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2017 HRS/EHRA/ECAS/APHRS/SOLAECE expert consensus statement on catheter and surgical ablation of atrial fibrillation
research-article
Hugh Calkins , MD
1 ,
Gerhard Hindricks , MD
2 ,
Riccardo Cappato , MD
3 ,
Young-Hoon Kim , MD, PhD
4 ,
Eduardo B Saad , MD, PhD
5 ,
Luis Aguinaga , MD, PhD
6 ,
Joseph G Akar , MD, PhD
7 ,
Vinay Badhwar , MD
8 ,
Josep Brugada , MD, PhD
9 ,
John Camm , MD
10 ,
Peng-Sheng Chen , MD
11 ,
Shih-Ann Chen , MD
12 ,
Mina K Chung , MD
13 ,
Jens Cosedis Nielsen , DMSc, PhD
14 ,
Anne B Curtis , MD
15 ,
D Wyn Davies , MD
16 ,
John D Day , MD
17 ,
André d’Avila , MD, PhD
18 ,
N M S (Natasja) de Groot , MD, PhD
19 ,
Luigi Di Biase , MD, PhD
20 ,
Mattias Duytschaever , MD, PhD
21 ,
James R Edgerton , MD
22 ,
Kenneth A Ellenbogen , MD
23 ,
Patrick T Ellinor , MD, PhD
24 ,
Sabine Ernst , MD, PhD
25 ,
Guilherme Fenelon , MD, PhD
26 ,
Edward P Gerstenfeld , MS, MD
27 ,
David E Haines , MD
28 ,
Michel Haissaguerre , MD
29 ,
Robert H Helm , MD
30 ,
Elaine Hylek , MD, MPH
31 ,
Warren M Jackman , MD
32 ,
Jose Jalife , MD
33 ,
Jonathan M Kalman , MBBS, PhD
34 ,
Josef Kautzner , MD, PhD
35 ,
Hans Kottkamp , MD
36 ,
Karl Heinz Kuck , MD, PhD
37 ,
Koichiro Kumagai , MD, PhD
38 ,
Richard Lee , MD, MBA
39 ,
Thorsten Lewalter , MD, PhD
40 ,
Bruce D Lindsay , MD
41 ,
Laurent Macle , MD
42 ,
Moussa Mansour , MD
43 ,
Francis E Marchlinski , MD
44 ,
Gregory F Michaud , MD
45 ,
Hiroshi Nakagawa , MD, PhD
46 ,
Andrea Natale , MD
47 ,
Stanley Nattel , MD
48 ,
Ken Okumura , MD, PhD
49 ,
Douglas Packer , MD
50 ,
Evgeny Pokushalov , MD, PhD
51 ,
Matthew R Reynolds , MD, MSc
52 ,
Prashanthan Sanders , MBBS, PhD
53 ,
Mauricio Scanavacca , MD, PhD
54 ,
Richard Schilling , MD
55 ,
Claudio Tondo , MD, PhD
56 ,
Hsuan-Ming Tsao , MD
57 ,
Atul Verma , MD
58 ,
David J Wilber , MD
59 ,
Teiichi Yamane , MD, PhD
60
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15 September 2017
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Abstract
Table of Contents
Abbreviationse5
Section 1: Introductione6
Section 2: Definitions, Mechanisms, and Rationale for AF Ablatione7
Definitione7
Demographic Profile of Patients with AF and Risk Factors for Development of AFe8
Natural History of AFe9
Genetic Contribution to AFe9
Genetic Determinants of Ablation Outcomee9
Significance of AFe10
Relationship Between Presence and Type of AF and Symptomse10
Anatomic and Electrophysiological Features of the Atria, Coronary Sinus, and Pulmonary
Veinse10
Autonomic Nervous System and How It Relates to AF and AF Ablatione13
Cardiac Fibrosis: Etiology and How It Relates to AFe13
Atrial Electrical and Structural Remodelinge14
AF-Related Extracellular Matrix Remodelinge14
Atrial Amyloidosise14
Role of Intracellular Ca
2+
Dysregulatione14
Ion Channels and Electrical Remodelinge15
Mechanisms of AF: Multiple Wavelet Hypothesis, Reentry, Spiral Waves, Rotational
Activity, and Focal Triggers from the Pulmonary Veins and Other Sitese15
Mechanisms of Atrial Tachycardia and Atrial Fluttere18
Potential Benefits and Rationale for Eliminating AF with Ablatione19
Electrophysiological Basis of AF Ablatione20
The Mechanisms of AF Recurrence After Catheter Ablation or Surgical AF Ablatione20
Section 3: Modifiable Risk Factors for AF and Impact on Ablatione21
AF Risk Factors and Their Interaction with AF Management and Ablatione21
Obesitye21
Sleep Apneae22
Types, Assessment, and Treatment of Apneae22
AF Mechanisms in Sleep Apneae22
Sleep Apnea Treatment and AF Ablation Outcomese23
Hypertensione23
Diabetese23
Alcohole23
Exercisee24
Section 4: Indicationse24
Recommendations and General Considerationse24
Catheter Ablation of AF as First-Line Therapye30
Catheter Ablation of AF in Patients with Heart Failure and Reduced Cardiac Functione30
Catheter Ablation in Older Peoplee30
Catheter Ablation in Other Populations of Patients Not Well Represented in Clinical
Trialse31
Catheter Ablation to Reduce Stroke Riske31
Catheter Ablation in Patients with Asymptomatic AFe31
Indications for Surgical Ablation of AFe33
Section 5: Strategies, Techniques, and Endpointse33
Historical Considerationse33
Ablation Approaches Targeting the PVs and Techniques to Obtain Permanent PVI Using
RF Energye34
Optimal Initial Lesion Creation and Waiting Phasee34
Adenosine Testinge35
Isoproterenol Infusione35
Loss of Pace Capture on the Ablation Linee35
Exit Blocke35
Techniques for Obtaining Permanent PVI with Balloon Technologiese36
Obtaining Permanent PVI with the Cryoballoone36
Endoscopic Laser Balloon PVIe36
Adjunctive Ablation Strategies to Be Performed in Addition to PVI During AF Ablatione37
Cavotricuspid Isthmus Ablatione37
Linear Lesions Not Involving the Cavotricuspid Isthmuse37
Posterior Wall Isolatione37
Nonpulmonary Vein Triggerse38
LAA Focal Ablation, Isolation, and Ligation or Resectione39
Complex Fractionated Atrial Electrogram Ablatione39
Ablation of Fibrosis Identified by Voltage Mapping and/or MRI Mappinge40
Mapping and Ablation of Rotational Activitye41
Localization and Ablation of Left Atrial Ganglionated Plexie42
Dominant Frequency Mappinge43
Renal Denervatione43
Epicardial Ablation of AFe43
Nonablative Strategies to Improve Outcomes of AF Ablatione44
AAD Therapye44
Risk Factor Modificatione44
Mechanisms of Nonisthmus-Dependent Atrial Flutter and Approaches to Mapping and Ablatione44
Anesthesia During AF Ablatione45
Recurrent AF with or without PV Reconnectione46
Endpoints for Ablation of Paroxysmal, Persistent, and Long-Standing Persistent AFe46
Section 6: Technology and Toolse46
Radiofrequency Energye47
Biophysics and Irrigatione47
Contact Force-Sensing Catheters and Systemse48
Contact Forcee48
Cryoablatione49
Laser and Ultrasound Ablation Systemse50
Other Balloon Technologiese50
Multielectrode Circumferential Ablation Catheterse50
Electroanatomical Mapping Systemse51
Robotic and Magnetic Catheter Navigatione52
Ultrasounde52
PV Venographye52
CT and/or MRI Scans and Rotational Angiography to Define the Anatomy of the Atrium,
PVs, and Antrume52
MRI of Atrial Fibrosis and Ablation Lesions and MRI-Guided AF Ablatione53
Section 7: Technical Aspects of Ablation to Maximize Safety and Anticoagulatione53
Prevention of Thromboembolism During and Following AF Ablatione53
Screening for LAA Thrombi Prior to Ablatione53
Transesophageal Echocardiographye53
Computer Tomographic Angiographye54
Intracardiac Echocardiographye54
Anticoagulatione54
Systemic Anticoagulation Prior to AF Ablatione54
Intraprocedural Anticoagulatione55
Early Postprocedural Anticoagulatione56
Anticoagulation Considerations Two or More Months Postablatione56
Anesthesia or Sedation During Ablatione58
General Anesthesiae58
Conscious and Deep Sedatione59
Jet Ventilatione59
Summarye59
Approaches to Minimize Risk of an AEFe59
Reduced Power Delivery on the Posterior Walle59
Esophageal Temperature Monitoringe59
Pharmacological Prophylaxise60
Role and Indications for Endoscopic Screening for Ulceration Following AF Ablatione60
Role and Indications for CT Imaging for Diagnosis of Atrioesophageal Fistulae60
Management of Atrial Esophageal Fistulae60
Summarye61
Section 8: Follow-up Considerationse61
Monitoring for Complications in the First Months After AF Ablatione61
Signs and Symptoms of Complications Within 1 Month Postablatione61
Signs and Symptoms of Complications More Than a Month Postablatione63
ECG Monitoring Pre- and Postablatione63
Available Methods for Arrhythmia Monitoringe64
Follow-up and Monitoring Guidelines for Routine Clinical Caree65
Early Recurrence After Ablatione66
Definition and Incidencee66
Causes of Recurrencese66
Early Recurrence as a Predictor of Failuree66
Antiarrhythmic Drugse66
Corticosteroidse66
Colchicinee67
Cardioversione67
Early Reablatione68
Conclusionse68
Atrial Tachycardias After AF Ablatione68
Antiarrhythmic and Other Pharmacological Therapy Postablatione68
Later-Term Repeat Ablation Procedurese69
Autonomic Alterationse69
Very Late Recurrence (More Than 1 Year) After AF Ablatione69
Section 9: Outcomes and Efficacye70
Overviewe70
Published Literature Review: Clinical Trials Performed for FDA Approvale70
AF Ablation as Second-Line Rhythm Control Therapye74
Outcomes and Efficacy of Catheter Ablation of AF as First-Line Rhythm Control Therapye74
Published Literature Review: Survey Resultse75
Outcomes of AF Ablation in Populations Not Well Represented in Clinical Trialse75
Outcomes of Catheter Ablation of Persistent and Long-Standing Persistent AFe75
Outcomes of AF Ablation in Elderly Patientse76
Outcomes of AF Ablation in Patients with Congestive Heart Failure and the Impact
of Ablation on Left Ventricular Functione76
Outcomes of AF Ablation in Patients with Hypertrophic Cardiomyopathye77
Outcomes of AF Ablation in Young Patientse77
Outcomes of AF Ablation in Womene78
Outcomes of Cryoballoon Ablatione78
Outcome of Rotational Activity Ablation for AFe79
Outcomes of Laser Balloon Ablatione79
Long-Term Ablation Efficacye79
Impact of Catheter Ablation of AF on QOLe79
Impact of Catheter Ablation of AF on LA Size and Functione80
Impact of Catheter Ablation on Stroke Riske80
Predictors of Success Following AF Ablatione81
Cost Effectiveness of AF Ablatione81
Section 10: Complicationse82
Overviewe82
Cardiac Tamponadee82
PV Stenosise87
Atrial Esophageal Fistula, Atrial Pericardial Fistula, and Esophageal Hematomae88
Esophageal Hematomae88
AEF and Atrial Pericardial Fistulae88
Gastric Hypomotility and Periesophageal Vagal Nerve Injurye89
Phrenic Nerve Palsye90
Stroke, TIA, and Silent Microembolie91
Stroke and TIAe91
Asymptomatic Cerebral Embolie91
Air Embolisme92
Vascular Complicationse92
Acute Coronary Artery Occlusion and Stenosise93
Radiation Exposure During Catheter Ablation of AFe94
Pericarditise94
Mitral Valve Trauma and Curvilinear Catheter Entrapmente94
Mortality Risk with AF Ablatione95
Stiff Left Atrial Syndromee95
Coughe96
Increase in Heart Rate and/or Sinus Tachycardiae96
Section 11: Training Requirementse96
Overviewe96
Appropriate Selection of Patientse96
Anatomy of the Atria and Adjacent Structurese97
Conceptual Knowledge of Strategies to Ablate AFe97
Technical Competencee97
Procedural Experiencee97
Recognition, Prevention, and Management of Complicationse98
Appropriate Follow-up and Long-Term Managemente98
Section 12: Surgical and Hybrid AF Ablatione98
Historical Considerations and Development of the Cox-Maze Proceduree98
Surgical Ablation Technologye99
Surgical Technology for Appendage Ligation or Removal and Outcomes of These Procedurese100
Concomitant Surgical Ablatione101
Historical Considerationse101
Concomitant Surgical Ablatione101
Surgical Ablation at the Time of Concomitant Open Atrial Operationse101
Surgical Ablation at the Time of Concomitant Closed Atrial Operatione102
Stand-Alone Surgical Ablation of AFe102
Stand-Alone Operations for AF and Their Outcomese102
Catheter Ablation After AF Surgerye104
Hybrid Epicardial and Endocardial AF Ablation Procedurese105
Backgrounde105
The Futuree106
Section 13: Clinical Trial Designe106
Overviewe106
Types of Clinical Trials, Strengths, and Weaknessese106
Mortality Trialse106
Stroke and Thromboembolism Trialse107
Multicenter Outcome Studiese107
Industry-Sponsored Device Approval Studiese108
Registry Studiese108
Clinical Endpoint Considerationse108
Blanking Periode108
AF Recurrence Endpointse115
AF Burden Endpointse115
Endpoint Differences for Paroxysmal vs Nonparoxysmal AF Ablation Studiese118
Symptomatic vs Asymptomatic Recurrencee118
AF Monitoring Postablatione118
QOL Measuremente119
Other Endpoint Reportinge119
Unanswered Questions in AF Ablatione119
Section 14: Conclusione120
Acknowledgmentse120
Appendix Ae121
Appendix Be133
Referencese135
Abbreviations
3D
three-dimensional
AADs
antiarrhythmic drugs
AATAC
Ablation vs Amiodarone for Treatment of Atrial Fibrillation in Patients With Congestive
Heart Failure and an Implanted ICD/CRTD
ACE
asymptomatic cerebral emboli
ACT
activated clotting time
ADVICE
Adenosine Following Pulmonary Vein Isolation to Target Dormant Conduction Elimination
study
AEF
atrial esophageal fistula
AF
atrial fibrillation
AFACART
Non-Invasive Mapping of Atrial Fibrillation study
AFACT
Atrial Fibrillation Ablation and Autonomic Modulation via Thoracoscopic Surgery study
AFCL
atrial fibrillation cycle length
AFEQT
Atrial Fibrillation Effect on QualiTy-of-Life questionnaire
AFL
atrial flutter
AH
arterial hypertension
ANS
autonomic nervous system
APD
action potential duration
ARREST-AF
Aggressive Risk Factor Reduction Study for Atrial Fibrillation and Implications for
the Outcome of Ablation study
ASD
atrial septal defect
ASTA
Arrhythmia-Specific questionnaire in Tachycardia and Arrhythmia
AT
atrial tachycardia
ATA
atrial tachyarrhythmia
ATP
adenosine triphosphate
AV
atrioventricular
AVR
aortic valve replacement
BIFA
box isolation of fibrotic areas
BMI
body mass index
BP
blood pressure
bpm
beats per minute
BSM
body surface mapping
CABANA
Catheter Ablation vs Anti-arrhythmic Drug Therapy for Atrial Fibrillation Trial
CABG
coronary artery bypass grafting
CaMKII
Ca2+/calmodulin-dependent protein kinase II
CB
cryoballoon
CBA
cryoballoon ablation
CF
contact force
CFAE
complex fractionated atrial electrogram
CFS
contact force sensing
CGCI
Catheter Guidance = Control = and Imaging
CHASE-AF
Catheter Ablation of Persistent Atrial Fibrillation study
CI
confidence interval
CMAP
compound motor action potentials
CPAP
continuous positive airway pressure
CPVA
circumferential PV ablation
Cryo-FIRST
Catheter Cryoablation vs Antiarrhythmic Drug as First-Line Therapy of Paroxysmal AF
trial
CS
coronary sinus
CSA
central sleep apnea
CT
computed tomography
CV
conduction velocity
DAD
delayed afterdepolarization
DE
delayed enhancement
DECAAF
Delayed Enhancement MRI and Atrial Fibrillation Catheter Ablation study
DF
dominant excitation frequency
DM
diabetes mellitus
DW-MRI
diffusion-weighted magnetic resonance imaging
EAM
electroanatomical mapping
EAST
Early Treatment of Atrial Fibrillation for Stroke Prevention Trial
EAVM
electroanatomical voltage mapping
ECG
electrocardiogram
ECGI
noninvasive electrocardiographic imaging
EF
ejection fraction
ERAF
early recurrence of AF
ERP
effective refractory period
FACM
fibrotic atrial cardiomyopathy
FAP
fractionated atrial potential
FAST
AF Catheter Ablation Versus Surgical Ablation Treatment trial
FDA
U.S. Food and Drug Administration
FIRM
focal impulse and rotor modulation
FLAIR
fluid-attenuated inversion recovery
FTI
force-time integral
GP
ganglionated plexi
HCM
hypertrophic cardiomyopathy
HDF
highest dominant excitation frequency
HF
heart failure
HFS
high-frequency stimulation
HR
hazard ratio
ICE
intracardiac echocardiography
IRGP
inferior right ganglionated plexi
ILR
implantable loop recorder
INR
international normalized ratio
LA
left atrial
LAA
left atrial appendage
LAD
left atrial dimension
LALA
left atrial linear ablation
LEGACY
Long-Term Effect of Goal Directed Weight Management on an Atrial Fibrillation Cohort
study
LGE
late gadolinium-enhanced
LI
left inferior
LICU
low-intensity collimated ultrasound
LIPV
left inferior pulmonary vein
LOE
Level of Evidence
Look AHEAD
Action for Health in Diabetes
LS
left superior
LSPV
left superior pulmonary vein
LVEF
left ventricular ejection fraction
MANTRA-PAF
Medical ANtiarrhythmic Treatment or Radiofrequency Ablation in Paroxysmal Atrial Fibrillation
MAP
mean arterial pressure
MLWHF
Minnesota Living with Heart Failure questionnaire
MRI
magnetic resonance imaging
MVRR
mitral valve repair or replacement
NCDR
National Cardiovascular Data Registry
NCX
Na+-Ca2+ exchanger
NOAC
novel oral anticoagulant
NSAID
nonsteroidal anti-inflammatory drug
OAC
oral anticoagulation
OCEAN
Optimal Anticoagulation for Higher Risk Patients Post-Catheter Ablation for Atrial
Fibrillation
ODIn-AF
Prevention of Silent Cerebral Thromboembolism by Oral Anticoagulation With Dabigatran
After PVI for Atrial Fibrillation trial
OPC
objective performance criteria
OR
odds ratio
OSA
obstructive sleep apnea
PA
peripheral artery
PABA-CHF
Pulmonary Vein Antrum Isolation versus AV Node Ablation with Bi-Ventricular Pacing
for Treatment of AF in Patients with Congestive Heart Failure
PAF
paroxysmal AF
PCC
prothrombin complex concentrates
PCWP
pulmonary capillary wedge pressure
PKA
protein kinase A
PN
phrenic nerve
PPIs
proton pump inhibitors
PROTECT AF
WATCHMAN Left Atrial Appendage System for Embolic Protection in Patients With Atrial
Fibrillation
PS
phase singularity
PSD
peak skin dose
PV
pulmonary vein
PVAC
pulmonary vein ablation catheter
PVI
pulmonary vein isolation
QALY
quality-adjusted life year
QOL
quality of life
RA
right atrium
RAAFT
First Line Radiofrequency Ablation Versus Antiarrhythmic Drugs for Atrial Fibrillation
Treatment
RAAFT-2
Radiofrequency Ablation versus Antiarrhythmic drugs as First-line Treatment of Paroxysmal
AF
RCA
right coronary artery
RCT
randomized controlled trial
RD
risk difference
RE-CIRCUIT
Randomized Evaluation of Dabigatran Etexilate Compared to Warfarin in Pulmonary Vein
Ablation: Assessment of an Uninterrupted Periprocedural Anticoagulation Strategy
RF
radiofrequency
RFA
radiofrequency energy ablation
RFC
radiofrequency catheter
RFCA
radiofrequency catheter ablation
RI
right inferior
RIPV
right inferior pulmonary vein
RP
refractory period
RR
relative risk
RS
right superior
RSPV
right superior pulmonary vein
RVSP
right ventricular systolic pressure
SARA
Study of Ablation Versus antiaRrhythmic Drugs in Persistent Atrial Fibrillation
SMART-AF
ThermoCool SmartTouch Catheter for the Treatment of Symptomatic Paroxysmal Atrial
Fibrillation
SNP
single nucleotide polymorphism
SPECULATE
Effect of Amiodarone on the Procedure Outcome in Long-standing persistent AF Undergoing
PV Antral Isolation
SR
sarcoplasmic reticulum
STAR AF II
Substrate and Trigger Ablation for Reduction of AF Trial Part II
STOP-AF
Sustained Treatment of Paroxysmal Atrial Fibrillation
SVC
superior vena cava
TEE
transesophageal echocardiogram
TIA
transient ischemic attack
VATS
video-assisted thoracoscopic surgery
VKA
vitamin K antagonist
WACA
wide-area circumferential ablation
WL
wavelength
Section 1: Introduction
During the past three decades, catheter and surgical ablation of atrial fibrillation
(AF) have evolved from investigational procedures to their current role as effective
treatment options for patients with AF. Surgical ablation of AF, using either standard,
minimally invasive, or hybrid techniques, is available in most major hospitals throughout
the world. Catheter ablation of AF is even more widely available, and is now the most
commonly performed catheter ablation procedure.
In 2007, an initial Consensus Statement on Catheter and Surgical AF Ablation was developed
as a joint effort of the Heart Rhythm Society (HRS), the European Heart Rhythm Association
(EHRA), and the European Cardiac Arrhythmia Society (ECAS).
1
The 2007 document was also developed in collaboration with the Society of Thoracic
Surgeons (STS) and the American College of Cardiology (ACC). This Consensus Statement
on Catheter and Surgical AF Ablation was rewritten in 2012 to reflect the many advances
in AF ablation that had occurred in the interim.
2
The rate of advancement in the tools, techniques, and outcomes of AF ablation continue
to increase as enormous research efforts are focused on the mechanisms, outcomes,
and treatment of AF. For this reason, the HRS initiated an effort to rewrite and update
this Consensus Statement. Reflecting both the worldwide importance of AF, as well
as the worldwide performance of AF ablation, this document is the result of a joint
partnership between the HRS, EHRA, ECAS, the Asia Pacific Heart Rhythm Society (APHRS),
and the Latin American Society of Cardiac Stimulation and Electrophysiology (Sociedad
Latinoamericana de Estimulación Cardíaca y Electrofisiología [SOLAECE]). The purpose
of this 2017 Consensus Statement is to provide a state-of-the-art review of the field
of catheter and surgical ablation of AF and to report the findings of a writing group,
convened by these five international societies. The writing group is charged with
defining the indications, techniques, and outcomes of AF ablation procedures. Included
within this document are recommendations pertinent to the design of clinical trials
in the field of AF ablation and the reporting of outcomes, including definitions relevant
to this topic.
The writing group is composed of 60 experts representing 11 organizations: HRS, EHRA,
ECAS, APHRS, SOLAECE, STS, ACC, American Heart Association (AHA), Canadian Heart Rhythm
Society (CHRS), Japanese Heart Rhythm Society (JHRS), and Brazilian Society of Cardiac
Arrhythmias (Sociedade Brasileira de Arritmias Cardíacas [SOBRAC]). All the members
of the writing group, as well as peer reviewers of the document, have provided disclosure
statements for all relationships that might be perceived as real or potential conflicts
of interest. All author and peer reviewer disclosure information is provided in Appendix
A and Appendix B.
In writing a consensus document, it is recognized that consensus does not mean that
there was complete agreement among all the writing group members. Surveys of the entire
writing group were used to identify areas of consensus concerning performance of AF
ablation procedures and to develop recommendations concerning the indications for
catheter and surgical AF ablation. These recommendations were systematically balloted
by the 60 writing group members and were approved by a minimum of 80% of these members.
The recommendations were also subject to a 1-month public comment period. Each partnering
and collaborating organization then officially reviewed, commented on, edited, and
endorsed the final document and recommendations.
The grading system for indication of class of evidence level was adapted based on
that used by the ACC and the AHA.
3
,
4
It is important to state, however, that this document is not a guideline. The indications
for catheter and surgical ablation of AF, as well as recommendations for procedure
performance, are presented with a Class and Level of Evidence (LOE) to be consistent
with what the reader is familiar with seeing in guideline statements. A Class I recommendation
means that the benefits of the AF ablation procedure markedly exceed the risks, and
that AF ablation should be performed; a Class IIa recommendation means that the benefits
of an AF ablation procedure exceed the risks, and that it is reasonable to perform
AF ablation; a Class IIb recommendation means that the benefit of AF ablation is greater
or equal to the risks, and that AF ablation may be considered; and a Class III recommendation
means that AF ablation is of no proven benefit and is not recommended.
The writing group reviewed and ranked evidence supporting current recommendations
with the weight of evidence ranked as Level A if the data were derived from high-quality
evidence from more than one randomized clinical trial, meta-analyses of high-quality
randomized clinical trials, or one or more randomized clinical trials corroborated
by high-quality registry studies. The writing group ranked available evidence as Level
B-R when there was moderate-quality evidence from one or more randomized clinical
trials, or meta-analyses of moderate-quality randomized clinical trials. Level B-NR
was used to denote moderate-quality evidence from one or more well-designed, well-executed
nonrandomized studies, observational studies, or registry studies. This designation
was also used to denote moderate-quality evidence from meta-analyses of such studies.
Evidence was ranked as Level C-LD when the primary source of the recommendation was
randomized or nonrandomized observational or registry studies with limitations of
design or execution, meta-analyses of such studies, or physiological or mechanistic
studies of human subjects. Level C-EO was defined as expert opinion based on the clinical
experience of the writing group.
Despite a large number of authors, the participation of several societies and professional
organizations, and the attempts of the group to reflect the current knowledge in the
field adequately, this document is not intended as a guideline. Rather, the group
would like to refer to the current guidelines on AF management for the purpose of
guiding overall AF management strategies.
5
,
6
This consensus document is specifically focused on catheter and surgical ablation
of AF, and summarizes the opinion of the writing group members based on an extensive
literature review as well as their own experience. It is directed to all health care
professionals who are involved in the care of patients with AF, particularly those
who are caring for patients who are undergoing, or are being considered for, catheter
or surgical ablation procedures for AF, and those involved in research in the field
of AF ablation. This statement is not intended to recommend or promote catheter or
surgical ablation of AF. Rather, the ultimate judgment regarding care of a particular
patient must be made by the health care provider and the patient in light of all the
circumstances presented by that patient.
The main objective of this document is to improve patient care by providing a foundation
of knowledge for those involved with catheter ablation of AF. A second major objective
is to provide recommendations for designing clinical trials and reporting outcomes
of clinical trials of AF ablation. It is recognized that this field continues to evolve
rapidly. As this document was being prepared, further clinical trials of catheter
and surgical ablation of AF were under way.
Section 2: Definitions, Mechanisms, and Rationale for AF Ablation
Definition
AF is a common supraventricular arrhythmia that is characterized by rapid and irregular
activation in the atria without discrete P waves on the surface electrocardiogram
(ECG). AF can be diagnosed with a surface ECG, an intracardiac atrial electrogram,
or both. An arrhythmia that has the ECG characteristics of AF and lasts sufficiently
long for a 12-lead ECG to be recorded, or is otherwise documented to last for at least
30 seconds, should be considered to be an AF episode. The 30-second duration was selected
based on previous published consensus statements and is used as the minimal duration
to define recurrence of AF after catheter ablation.
1
,
7
This duration of AF has not been linked to a specific outcome of AF. In addition to
the duration requirements listed above, the diagnosis of AF requires an ECG or rhythm
strip demonstrating: (1) “absolutely” irregular R-R intervals (in the absence of complete
atrioventricular [AV] block); (2) no distinct P waves on the surface ECG; and (3)
an atrial cycle length (when visible) that is usually less than 200 ms.
2
,
7
Although there are several classification systems for AF, for this consensus document,
we have adopted in large part the classification system that was presented in the
2014 AHA/ACC/HRS Guideline for the Management of Patients with Atrial Fibrillation.
5
We recommend that this classification system be used for future studies of catheter
and surgical ablation of AF. Paroxysmal AF (PAF) is defined as AF that terminates
spontaneously or with intervention within 7 days of onset (Table 1
); persistent AF is defined as continuous AF that is sustained beyond 7 days; and
long-standing persistent AF is defined as continuous AF of greater than 12 months'
duration. Early persistent AF is a new term we have defined as continuous AF of more
than 7 days' duration but less than 3 months' duration. Within the context of AF ablation
and clinical trials of AF ablation, early persistent AF defines a population of patients
in whom better outcomes of AF ablation are anticipated as compared with persistent
AF of more than 3 months' duration. The term permanent AF is defined as AF in which
the presence of the AF is accepted by the patient and physician, and no further attempts
will be made to either restore or maintain sinus rhythm. It is important, therefore,
to recognize that the term permanent AF represents a therapeutic attitude on the part
of a patient and their physician rather than on any inherent pathophysiological attribute
of the AF. Such decisions can change as symptoms, the efficacy of therapeutic interventions,
and patient and physician preferences evolve. If a rhythm control strategy is recommended
after reevaluation, the AF should be redesignated as paroxysmal, persistent, or long-standing
persistent AF. Within the context of any rhythm control strategy, including catheter
and surgical AF ablation, the term permanent AF is not meaningful and should not be
used. Silent AF is defined as asymptomatic AF diagnosed by an opportune ECG or rhythm
strip. Paroxysmal, persistent, and long-standing persistent AF can be silent. We recognize
that a particular patient might have AF episodes that fall into one or more of these
categories; therefore, we recommended that patients be categorized by their most frequent
pattern of AF during the 6 months prior to performance of an ablation procedure. Lone
AF is a descriptor that has been applied to younger patients without clinical or echocardiographic
evidence of cardiac disease. Because the definitions are variable, the term lone AF
is potentially confusing, and should not be used to describe populations of patients
with AF nor to guide therapeutic decisions.
5
The term chronic AF also has variable definitions and should not be used to describe
populations of patients with AF.
Table 1
Atrial fibrillation definitions
AF episode
An AF episode is defined as AF that is documented by ECG monitoring or intracardiac
electrogram monitoring and has a duration of at least 30 seconds, or if less than
30 seconds, is present throughout the ECG monitoring tracing. The presence of subsequent
episodes of AF requires that sinus rhythm be documented by ECG monitoring between
AF episodes.
Chronic AF
Chronic AF has variable definitions and should not be used to describe populations
of AF patients undergoing AF ablation.
Early persistent AF
Early persistent AF is defined as AF that is sustained beyond 7 days but is less than
3 months in duration.
Lone AF
Lone AF is a historical descriptor that is potentially confusing and should not be
used to describe populations of patients with AF undergoing AF ablation.
Long-standing persistent AF
Long-standing persistent AF is defined as continuous AF of greater than 12 months’
duration.
Paroxysmal AF
Paroxysmal AF is defined as AF that terminates spontaneously or with intervention
within 7 days of onset.
Permanent AF
Permanent AF is defined as the presence of AF that is accepted by the patient and
physician, and for which no further attempts to restore or maintain sinus rhythm will
be undertaken. The term permanent AF represents a therapeutic attitude on the part
of the patient and physician rather than an inherent pathophysiological attribute
of AF. The term permanent AF should not be used within the context of a rhythm control
strategy with antiarrhythmic drug therapy or AF ablation.
Persistent AF
Persistent AF is defined as continuous AF that is sustained beyond 7 days.
Silent AF
Silent AF is defined as asymptomatic AF diagnosed with an opportune ECG or rhythm
strip.
AF, atrial fibrillation; ECG, electrocardiogram.
The writing group recognizes that these definitions of AF are very broad, and that
additional details should be provided when describing a population of patients undergoing
AF ablation. With the increased use of implantable loop recorders (ILRs), pacemakers,
and implantable cardioverter-defibrillators for rhythm diagnosis, we urge the investigators
to specify the duration of time patients have spent in continuous AF prior to an ablation
procedure, including the 24-hour AF burden, when data are available. The investigators
should also specify whether patients undergoing AF ablation have previously failed
pharmacological therapy, electrical cardioversion, catheter and/or surgical ablation.
Shown in Table 1
are a series of definitions of AF types that can be used for future trials of AF ablation
and in the literature to help standardize reporting of patient populations and outcomes.
Demographic Profile of Patients with AF and Risk Factors for Development of AF
AF is an exceedingly common age-related arrhythmia. Among people of European descent,
the lifetime risk of developing AF after age 40 is 26% for men and 23% for women.
8
There are multiple risk factors for development of AF.
5
,
7
Some of these risk factors are modifiable, including hypertension, obesity, endurance
exercise, obstructive sleep apnea (OSA), thyroid disease, and alcohol consumption,
whereas many others are not.
5
,
7
,
9
,
10
,
11
Nonmodifiable risk factors include age, sex, family history, race, tall stature, and
other types of heart and valvular disease.
5
,
7
Among the many risk factors for development of AF, age is perhaps the most powerful.
8
,
9
The relative risks (RRs) of AF development associated with a number of risk factors
are provided in a recent systematic review.
12
It is rare to develop AF prior to age 50; and by age 80, approximately 10% of individuals
are diagnosed with AF. The precise pathophysiological basis of this link between AF
and age is not completely understood; however, age-related fibrosis likely plays a
key role.
9
AF risk factors have also been shown to be of value in predicting progression of paroxysmal
to persistent AF.
13
It is notable that many of the risk factors that have been associated with development
of AF also contribute to AF progression, recurrences of AF following ablation, and
complications associated with AF (e.g., stroke).
Natural History of AF
The concept of “AF begets AF” remains a cornerstone in the understanding of the natural
history of AF progression.
14
Increasing AF burden is associated with progressive atrial remodeling and the development
of atrial fibrosis, which can contribute to the long-term persistence of AF.
15
A wealth of experimental data exist regarding structural and functional atrial changes
that contribute to the development, maintenance, and progression of AF. In contrast,
considerably less data exist regarding the natural history of AF.
16
,
17
This is in large part related to the difficulty in accurately assessing the underlying
burden of AF in individuals and large populations. Thus, estimates of the prevalence
of clinical AF subtypes and their progression have evolved with the changes in population
characteristics, associated comorbidities, and development of modern arrhythmia monitoring
technology. For example, the rate of progression appears to be very low in individuals
with an initial diagnosis of AF who are younger than 60 years of age and who have
no concomitant heart disease. Among 97 individuals followed over three decades, 21%
had an isolated AF event without further recurrence, 58% had recurrent AF, and 22%
developed persistent AF.
18
Other longitudinal studies have demonstrated a much higher rate of AF progression.
One recent study examined the rate of progression to persistent AF among 1219 paroxysmal
patients with AF.
13
Progression to persistent AF was observed in 15% of the patients over 12 months of
follow-up. Predictors of progression included age, hypertension, prior transient ischemic
attack (TIA) or stroke, and chronic obstructive pulmonary disease. Similar results
were reported in another recent study that examined AF progression while waiting for
an AF ablation procedure.
19
Among 564 patients with PAF, 11% progressed to persistent AF during a 10-month follow-up
period. In this study, heart failure (HF) and a left atrial (LA) diameter >45 mm were
predictive of progression. These findings raise the possibility that the clinical
progression of AF could be driven by the development of associated comorbidities as
opposed to the arrhythmia itself. Moreover, recent studies using pacemaker-documented
AF burden have demonstrated a more complex natural history of the arrhythmia, with
persistent AF reverting to paroxysmal forms, without intervention.
20
This highlights our incomplete understanding of the natural history of clinical AF
and the need for larger studies focusing on the accurate assessment of AF progression
and regression.
Genetic Contribution to AF
It is now well recognized that AF is heritable.
21
,
22
,
23
Individuals having a first-degree relative with AF have approximately a 40% increased
risk for development of AF after accounting for established clinical AF risk factors.
23
In the last decade, great progress has been made in identifying the genetic determinants
of AF. Although studies of families with AF have led to the identification of mutations
in a series of ion channels and molecules, these mutations are typically family-specific,
rare, and do not explain a significant portion of the heritability of AF.
24
Therefore, population-based or genome-wide studies have been used to identify many
AF risk loci.
25
,
26
,
27
,
28
,
29
,
30
The genes at these loci encode transcription factors and ion channels, and many are
without a clear relation to AF at the present time.
There is interest in trying to use genetics to predict the onset of AF, to stratify
the risk of AF outcomes such as stroke and HF, and to identify the response to treatments
including antiarrhythmic medications or catheter ablation procedures. Interestingly,
a genetic risk score consisting of the top 12 loci for AF can be used to identify
as much as a 5-fold gradient in the risk of AF or those at greatest risk for a stroke.
31
,
32
However, similar to other common diseases, the genetic risk for AF provides minimal
additional predictive value after considering basic clinical risk factors such as
age and sex.
33
,
34
Future studies will be directed at using a comprehensive panel of genetic variants
to identify those at greatest risk for AF, and also to predict stroke risk and outcomes
to AF therapy, including AF ablation.
35
Whether genetic testing will ultimately prove to be an important clinical marker of
AF risk will become clear over time. An alternative and/or complementary strategy,
which might be easier for clinicians to employ, will be the use of a clinical risk
score.
Genetic Determinants of Ablation Outcome
Because many genetic determinants of AF have been identified, a logical question would
be to ask whether genetics can help predict the outcome of an ablation procedure.
35
At the present time, however, whether genetics will help predict outcomes remains
an unanswered question. Although there have been a number of studies exploring the
relation between a genetic variant or single nucleotide polymorphism (SNP) and AF
ablation outcome, these studies have been challenged by small sample sizes, testing
of a limited number of SNPs, and variable endpoints.
One recent study pooled ablation data from three different sites consisting of 991
individuals of European ancestry.
36
They tested representative SNPs at the top three loci (PITX2, ZFHX3, and KCNN3) identified
for AF in genome-wide association studies and related these SNPs to ablation outcome.
The primary finding was that an SNP, rs2200733, at the chromosome 4q25 or the PITX2
locus for AF was associated with a 1.4-fold increased risk of late AF recurrence.
In contrast, another recent study found differing results in a large Korean population
of 1068 individuals undergoing catheter ablation for AF.
37
This second study tested a similar set of SNPs, representing the PITX2, ZFHX3, and
KCNN3 loci, yet they did not observe any long-term difference in AF recurrence after
an ablation.
It is possible that the different outcomes noted in these two studies are due to a
racial difference in the genetic influence on ablation outcome, although future studies
will be necessary to resolve this issue. Larger, prospective, multiethnic studies
that test a comprehensive number of SNPs will be necessary before genetic data can
be considered clinically useful when considering AF ablation procedures.
Significance of AF
AF is an important arrhythmia for many reasons. First, it is common: current estimates
reveal that more than 33 million individuals worldwide have AF.
38
In the United States alone, it is estimated that between 3 and 5 million people have
AF, and that by 2050 this number will exceed 8 million.
39
Second, AF increases risk of stroke by an average of 5-fold.
40
AF-related strokes are more severe than those not related to AF.
41
Third, AF increases mortality, and has been linked to an increased risk of sudden
death.
42
,
43
Consistent with these prior studies, a recent Framingham study reported that those
with recurrent or sustained AF had a higher multivariable-adjusted mortality compared
with those with an isolated AF episode.
44
Fourth, AF increases the risk of HF.
45
Fifth, recent studies have linked AF with the development of dementia.
46
Finally, AF causes a wide variety of symptoms, including fatigue and reduced exercise
tolerance, and significantly impairs quality of life (QOL).
47
It is notable that asymptomatic status is associated with similar (or worse) prognosis
compared with symptomatic status.
48
AF is also important when considered in terms of use of health care resources and
cost. In the United States, AF accounts for more than 450,000 hospitalizations yearly
and has contributed to more than 99,000 deaths.
49
,
50
AF has been reported to increase annual health care costs by $8700 per patient, resulting
in a $26 billion annual increase in U.S. health care costs. Although studies have
not been performed to address the question of whether AF control with catheter ablation
impacts the morbidity and mortality associated with AF, it is notable that emerging
data have revealed that persistent forms of AF are associated with a significant increase
in thromboembolism and death compared with PAF.
51
The morbidity and mortality associated with AF provide a rationale to maintain sinus
rhythm. Given the anticipated enormous public health impact of AF, proven interventions
to reduce the risk of stroke, HF, cognitive impairment, and mortality are direly needed.
Large, prospective, multicenter, randomized clinical trials will help address whether
sinus rhythm achieved with ablation techniques lowers morbidity and mortality compared
with rate control alone or treatment with antiarrhythmic therapy. These studies will
also best define the patient population that will derive the most benefit. Until the
results of these types of clinical trials are available, it must be recognized that
the only proven benefit of AF ablation remains the reduction of symptoms and an improvement
in QOL.
Relationship Between Presence and Type of AF and Symptoms
During the past 15 years, multiple studies have investigated the impact of rate vs
rhythm control on stroke risk and mortality.
52
,
53
,
54
,
55
These studies have demonstrated no difference in these endpoints. When interpreting
the results of these studies, it is important to keep in mind the population of patients
who were enrolled, the approach used for rhythm control, and the duration of follow-up.
These studies enrolled predominantly elderly, minimally symptomatic patients with
AF in whom either a rate or rhythm control strategy would be acceptable; the mean
duration of follow-up was less than 4 years. The primary indication for catheter ablation
is to reduce patient symptoms and improve QOL. Therefore, prior to undergoing catheter
ablation, it is important to confirm that the patient's symptoms (palpitations, fatigue,
or effort intolerance) result from AF and to assess their severity. In some patients
with PAF, arrhythmia-monitoring tools (e.g., transtelephonic monitoring, Holter) are
useful to establish the correlation between symptoms and rhythm. In patients with
persistent AF who initially appear to be asymptomatic, a reassessment of symptoms
after restoration of sinus rhythm with cardioversion often reveals that the patient
does in fact feel better when in sinus rhythm. Because of this observation, many experienced
clinicians routinely recommend cardioversion with a reassessment of symptoms in apparently
asymptomatic patients with persistent AF. If the patient is ultimately demonstrated
to be symptomatic, a rhythm control strategy becomes an attractive therapeutic approach.
Conversely, if there is no change in symptoms postrestoration of sinus rhythm, a rate
control strategy could be preferable.
Several AF ablation studies evaluated the relationship between patient characteristics
and the presence of AF symptoms.
56
,
57
,
58
It is well recognized that patients' perception of AF varies widely. One of the first
studies to examine AF symptoms prior to and following ablation found that among 114
patients who underwent 7-day Holters prior to and following ablation, 38% of the patients
had only symptomatic AF episodes, 57% had both symptomatic and asymptomatic episodes,
and 5% of the patients had only asymptomatic episodes. Following the ablation, the
percentage of patients with only asymptomatic episodes of AF increased to 37%.
56
Asymptomatic AF is more frequent in men than in women.
48
,
59
,
60
In two prospective registries and in one recent retrospective study, older age was
associated with asymptomatic AF.
48
,
60
,
61
Inconsistent results have been reported for the association between asymptomatic AF
and cardiac and noncardiac comorbidities.
48
,
59
,
60
Although any type of AF can be asymptomatic, asymptomatic AF is more common in patients
with continuous persistent AF.
48
In approximately half of the patients with highly symptomatic AF referred for catheter
ablation, asymptomatic episodes are also present.
45
,
50
,
57
,
62
Arrhythmia episodes are more likely to be asymptomatic following, as compared with
prior to, AF ablation. Therefore, assessment of freedom from AF postablation cannot
be based on freedom from symptoms alone.
63
Anatomic and Electrophysiological Features of the Atria, Coronary Sinus, and Pulmonary
Veins
In recent decades, the development of catheter ablation of AF and other atrial arrhythmias
has made it necessary to have a sound understanding of cardiac anatomy (Figure 1
). Figure 1
shows the cardiac anatomy relevant for AF ablation when viewed from the anterior (Figure
1A), right lateral (Figure 1B), left lateral (Figure 1C), and posterior projections
(Figure 1D, 1E).
64
Viewed from the front, the right atrium (RA) is right and anterior, while the LA is
situated to the left and mainly posteriorly, with the right pulmonary veins (PVs)
adjacent to the intercaval area of the RA.
65
,
66
Consequently, the plane of the atrial septum lies at an angle to the sagittal plane
of the body. The front of the LA and the medial wall of the RA lie just behind the
aortic root, separated only by the transverse pericardial sinus. The posterior wall
of the LA is just in front of the tracheal bifurcation and the esophagus, with the
fibrous pericardium separating the heart from these structures.
Figure 1
Anatomical drawings of the heart relevant to AF ablation. This series of drawings
shows the heart and associated relevant structures from four different perspectives
relevant to AF ablation. This drawing includes the phrenic nerves and the esophagus.
(A) The heart viewed from the anterior perspective. (B) The heart viewed from the
right lateral perspective. (C) The heart viewed from the left lateral perspective.
(D) The heart viewed from the posterior perspective. (E) The left atrium viewed from
the posterior perspective. Illustration: Tim Phelps © 2017 Johns Hopkins University,
AAM.
PV anatomy is highly variable between patients (Figure 2
). Four distinct PV ostia are present in approximately 60% of patients, whereas variant
anatomy is observed in 40% of patients undergoing ablation.
67
In approximately 80% of cases, the anterior part of the ostium of the left PVs is
common, separated from the appendage by a ridge.
68
,
69
The most frequent type of variant anatomy is a left common PV, and the second most
frequent variant anatomy is a right middle PV. Anomalous PVs can also be observed
arising from the roof of the atrium. The orifices of the left PVs are located more
superior than those of the right PVs. The right superior (RS) PV and the left superior
(LS) PV project forward and upward, whereas the right inferior (RI) PV and the left
inferior (LI) PV project backward and downward. The RSPV lies just behind the superior
vena cava (SVC) or RA, and the left PVs are positioned between the left atrial appendage
(LAA) and the descending aorta.
Figure 2
This figure includes six CT or MR images of the left atrium and pulmonary veins viewed
from the posterior perspective. Common and uncommon variations in PV anatomy are shown.
(A) Standard PV anatomy with 4 distinct PV ostia. (B) Variant PV anatomy with a right
common and a left common PV. (C) Variant PV anatomy with a left common PV with a short
trunk and an anomolous PV arising from the right posterior left atrial wall. (D) and
(E) Variant PV anatomy with a common left PV with a long trunk. (F) Variant PV anatomy
with a massive left common PV.
Nathan and Eliakim first drew attention to the presence of sleeves of cardiac tissue
that extend onto the PVs (Figure 1E).
70
Myocardial muscle fibers extend from the LA into all the PVs for 1–3 cm; the thickness
of the muscular sleeve is highest at the proximal ends (1–1.5 mm), and then gradually
decreases distally.
16
,
64
,
71
The orientation of the major atrial muscular bundles (e.g., Bachmann's bundle or Crista
terminalis) has been recognized from anatomical dissections, with mostly circular
bundles around the ostia of the PVs, AV valves, and LAA.
72
Studies have described how premature firing from the PVs can initiate AF by interacting
with tissue mechanisms, using diffusion tensor imaging (at present, in vitro).
73
,
74
These findings have been reproduced by cardiac magnetic resonance imaging (MRI), highlighting
the very variable individual pattern of fiber orientation.
75
Future in vivo implementation (in addition to identification of fibrosis), combined
with simultaneous mapping techniques, could allow individual tailoring of interruption
of potential reentrant “pathways.”
76
,
77
The greater coronary venous system drains approximately 85% of the venous flow into
the RA, with the most proximal part being called the coronary sinus (CS). The great
cardiac vein ascends into the left AV groove, where it passes close to the circumflex
artery and under the cover of the LAA. The juncture between the great cardiac vein
and the CS is marked by the entrance of the vein of Marshall (which is typically obliterated
in adults and is referred to as the ligament of Marshall), which descends along the
epicardium between the LAA and the LSPV and can contain sympathetic nerves and ganglia.
78
Especially around the CS itself, muscular bundles are present that interconnect to
the LA, thereby serving as additional interatrial electrical “conductors.”
79
,
80
PV focal firing can trigger AF or act as a rapid driver to maintain the arrhythmia.
During embryological development of the heart, the location of the precursors of the
conduction system is defined by the looping process of the heart tube.
81
,
82
Cell markers common to precursors of specialized conduction tissue derived from the
heart tube have been found within myocardial sleeves.
83
The presence of P cells, transitional cells, and Purkinje cells has been demonstrated
in human PVs.
84
,
85
PV-sleeve cardiomyocytes have discrete ion channel and action potential properties
that predispose them to arrhythmogenesis.
84
,
85
They have small background IK1, which could favor spontaneous automaticity,
84
as could their reduced coupling to atrial tissue, a property common to pacemaking
structures.
86
Other studies show susceptibility to Ca2+-dependent arrhythmia mechanisms,
87
possibly due to cells of melanocyte origin.
88
Some, but not all, studies have reported that isolated cardiomyocytes from rabbit
and canine PVs show abnormal automaticity and triggered activity during manipulations
that enhance Ca2+ loading.
87
,
88
,
89
These properties might explain the electrical activity within the PVs that is commonly
observed after electrical disconnection of the PVs from the atrium.
90
Other studies have provided evidence to suggest that the PVs and the posterior LA
are also preferred sites for reentrant arrhythmias.
90
,
91
One important factor could be the shorter action potential duration (APD) of the PVs
vs the atrium
84
due to larger delayed-rectifier K+ currents and smaller inward Ca2+ currents in the
PV.
89
,
92
,
93
In addition, PVs demonstrate conduction abnormalities that promote reentry due to
abrupt changes in fiber orientation as well as Na+ channel inactivation by reduced
resting potentials due to small IK1.
84
Yet another study examined the impact of increasing atrial pressure on PV activation,
finding that as LA pressure was increased above 10 cm H2O, the PV–LA junction became
the source of dominant rotors.
94
These observations help explain the clinical link between AF and increased atrial
pressure. Several clinical studies have reported shorter refractory periods (RPs)
inside PVs compared to the LA, decremental conduction inside PVs, and easy induction
of PV reentry with premature stimulation from the PVs. Accordingly, rapid reentrant
activity with entrainment phenomena have been described inside PVs after successful
PV isolation (PVI).
95
,
96
Electrophysiological evaluation of the PVs using multielectrode basket catheters has
revealed effective refractory period (ERP) heterogeneity and anisotropic conduction
properties within the PV and at the PV–LA junction, which can provide a substrate
for reentry.
97
The response of PV activity to adenosine administration in patients with PAF is more
consistent with a reentrant than a focal-ectopic type of mechanism.
98
,
99
In addition, dominant frequency analysis points to an evolution of mechanisms in patients
with AF, with PV sources becoming less predominant as AF becomes more persistent and
atrial remodeling progresses.
95
Autonomic Nervous System and How It Relates to AF and AF Ablation
The cardiac autonomic nervous system (ANS) can be divided into the extrinsic and intrinsic
ANS.
100
The extrinsic cardiac ANS consists of sympathetic and parasympathetic components,
101
,
102
and includes neurons in the brain and spinal cord and nerves directed to the heart.
The intrinsic ANS primarily includes thousands of autonomic neurons and nerves located
in ganglionated plexi (GP), which are transitioned to the epicardial fat pads outside
the heart and along the great vessels in the thorax.
100
,
103
,
104
There are 7 major GP, including 4 located in the LA around the PVs.
103
,
105
The ligament of Marshall, which also contains GP, plays a coordination role between
the extrinsic and intrinsic ANS.
106
The GP predominantly contain parasympathetic neurons, but also sympathetic neurons.
In humans, numerous autonomic nerves are located at the PV–LA junction. The nerve
densities are much more pronounced within 5 mm of the PV–LA junction and are higher
in the epicardial surface than in the endocardium.
107
,
108
These data reveal that the areas of LA endocardial surface most suitable for ANS modification
are located in the immediate vicinity of the PV–LA junction. Due to close relationship
of the sympathetic and parasympathetic ANS components, it is difficult to perform
selective radiofrequency (RF) ablation of a particular part of the ANS,
109
and ablation of these sites can destroy both adrenergic and cholinergic nerves.
In an animal model of PAF, injection of parasympathomimetics into the fat pad adjacent
to the PV-atrial junctions resulted in spontaneous or easily induced sustained AF,
suggesting that a hyperactive ANS can play an important role in patients with focal
AF arising from the PV.
110
,
111
Stimulation of GP by pacing at the base of the PV can also provide a substrate of
AF initiation from PV firing.
112
,
113
Studies have shown that the intrinsic ANS has a potential impact on acute atrial electrical
remodeling induced by rapid atrial pacing.
113
Other studies have shown that synergic actions of both the sympathetic and parasympathetic
neurotransmitters promote rapid PV firing in an experimental system.
114
Another study demonstrated that stimulation of the right anterior GP converts isolated
premature depolarization from the RSPV into AF-inducing premature depolarizations,
115
indicating a link between GP activity and AF inducibility. The authors proposed a
model of a highly integrated atrial neural network in which a GP hyperactive state
could release a gradient of locally excessive concentrations of neurotransmitters
that initiate AF, whereas activation of the axons can “retrogradely” excite the GP
at a distance to cause the release of neurotransmitters to induce AF. Several studies
have identified a link between the intrinsic cardiac nervous system and complex fractionated
atrial electrograms (CFAEs) and AF triggers.
113
,
116
The effectiveness of catheter ablation of GP in patients with AF remains controversial.
One of the major challenges has been the lack of a sensitive and specific means to
localize the GP in patients.
117
,
118
,
119
,
120
Whereas several small studies have reported improved outcomes using an anatomically
based approach to localize autonomic ganglia, these findings have not been replicated
by other investigators.
121
,
122
A recent prospective randomized surgical AF ablation study reported no improvement
of outcomes by ablation of autonomic ganglia.
123
The most commonly used approach to localize the major atrial GP is to apply high-frequency
stimulation (HFS) to the presumed GP areas to elicit AV block. This method has low
specificity and sensitivity because endocardial GP can be embedded in epicardial fat
pads.
106
,
124
Some investigators have suggested that HFS mainly reveals the afferent link of the
ANS, suggesting that sites eliciting vagal responses do not coincide with sites where
GP clusters and efferent autonomic nerves are located.
125
Another issue is reinnervation of the ANS during follow-up.
108
,
114
Whether reinnervation causes recurrent AF postablation remains uncertain. One study
has reported that reinnervation of the ANS in patients after RF ablation is not directly
related to AF recurrence.
126
In summary, there is considerable evidence that the ANS contributes to the initiation
and maintenance of AF. Whether ablation of the ANS impacts the outcomes of AF ablation
remains uncertain. In the future, novel approaches for ANS modulation could increase
the efficacy of AF ablation treatment.
127
,
128
,
129
Cardiac Fibrosis: Etiology and How It Relates to AF
Atrial fibrosis is a common finding in patients with AF. The question of whether atrial
fibrosis stems from AF itself, from AF-related risk factors, or from a specific fibrotic
atrial cardiomyopathy (FACM) is under debate.
130
,
131
,
132
,
133
,
134
Recently, a subgroup of patients with recent onset persistent AF have been described
with a diffuse abnormal substrate and with poor outcome after ablation.
135
There is great variability in the amount of fibrosis in patients with AF, in which
some patients with PAF have massive fibrosis and some patients with persistent AF
show mild fibrosis.
134
,
136
Some morphological studies have shown that fibrosis in humans is related to the underlying
disease rather than being caused by AF.
73
,
137
,
138
The specific role of age and AF risk factors in atrial fibrosis was questioned by
an autopsy study, in which only small amounts of fibrofatty tissue were described
in atrial specimens from patients with a high mean CHA2DS2-VASc score of 4.3 but no
AF.
139
In addition, a low correlation between risk factors and the fibrotic substrate as
estimated from electroanatomic voltage mapping in patients with non-PAF has been described.
140
Similarly, cardiovascular risk factors were found to be equally distributed in various
classes of LA fibrosis as described by MRI studies, and structural atrial remodeling
was the same in patients with and without cardiovascular risk factors.
130
On the other hand, there is extensive evidence that many AF risk factors do substantially
increase atrial fibrosis content, and that AF itself might have a profibrotic effect.
141
,
142
,
143
One study reported that elevated serum markers of collagen synthesis were associated
with postsurgical AF, compared with those who stayed in sinus rhythm.
144
It is possible that the fibrotic atrial substrate could be a result of a specific
FACM.
131
,
133
,
140
FACM has been described as a specific disease with various expressions, from mild,
to moderate, to severe atrial fibrosis, and with a potentially progressive disease
process. Consequently, AF—and other arrhythmias such as reentrant atrial tachycardia
(AT) and sinus node disease—can be understood as a manifestation of the preexisting
FACM.
131
,
133
,
145
,
146
Atrial Electrical and Structural Remodeling
The pathophysiology of AF is complex, involving interaction among multiple factors,
including triggers, which are responsible for AF initiation; substrate, which is necessary
for AF maintenance; and perpetuators, which underlie the progression of the arrhythmia
from paroxysmal to the persistent forms.
146
,
147
The recently published EHRA/HRS/APHRS/SOLAECE expert consensus document on atrial
cardiomyopathies provides a detailed review of the important topic of atrial cardiomyopathies
and their interrelationship with AF.
148
It is generally believed that some degree of structural remodeling must predate electrical
remodeling. The trigger mechanisms can include focal enhanced automaticity or triggered
activity. Initiation of AF can be favored by both parasympathetic and sympathetic
activation, which also appear to play a role in maintaining AF.
149
However, the central mechanisms governing AF initiation and perpetuation are poorly
understood, which explains in part why treatment of patients with all forms of AF,
and particularly long-standing persistent AF, remains suboptimal. Although AF usually
starts with paroxysmal episodes, it can evolve to a persistent form in a significant
number of patients.
150
A few clinical factors have been associated with transition from paroxysmal to persistent
AF.
20
,
151
,
152
The transition likely reflects progressive structural and electrophysiological remodeling
in both atria, making the sources of the arrhythmia more stable by fundamental mechanisms
that have been incompletely explored.
153
,
154
,
155
,
156
AF-Related Extracellular Matrix Remodeling
Persistent AF itself leads to electrical remodeling and fibrosis of the atria.
157
,
158
Experimental and clinical data point to a complex pathophysiology involving diverse
factors, including oxidative stress, calcium overload, atrial dilatation, microRNAs,
inflammation, and myofibroblast activation.
141
,
159
,
160
,
161
,
162
In a recent study of transcriptional changes associated with AF, susceptibility to
the arrhythmia was associated with decreased expression of targets of several transcription
factors related to inflammation, oxidation, and cellular stress responses.
163
However, it is unknown to what extent and at which time points such alterations influence
the remodeling process that perpetuates AF. Moreover, rapid atrial rates activate
fibroblasts to increase collagen-gene activity, and AF in isolation might promote
cardiac fibrosis.
131
,
133
,
134
Cardiac fibrosis is part of the maladaptive cardiac remodeling in response to cardiac
injury
164
,
165
and has been implicated in initiation and maintenance of AF.
166
The mechanisms that are responsible for fibrosis and its consequences comprise many
phenomena occurring at various scales, including molecular, organelle, cellular, and
tissue scales.
167
At the molecular scale are dynamics changes in the genome, the transcriptome, and
the signaling pathways underlying the generation of profibrotic molecules
168
; cellular changes involve interactions among the various cardiac cells, including
myocytes, fibroblasts or myofibroblasts, and inflammatory cells such as macrophages
and neutrophils
169
; and tissue changes relate to the dynamics of scar, angiogenesis, electrical conduction,
and contractility.
153
Fibrosis can certainly act as an electrically insulating obstacle. Profibrotic stimuli
promote differentiation of fibroblasts into activated myofibroblasts, which electronically
couple to myocytes in vitro
20
,
150
,
151
,
152
; whether this occurs to a significant extent in AF atria in vivo remains uncertain.
Fibrosis affects electrical propagation through slow, discontinuous conduction with
“zigzag” propagation,
170
,
171
reduced regional coupling,
172
abrupt changes in fibrotic bundle size,
173
interruption of bundle continuity, and micro-anatomical reentry.
174
Another potentially important factor in AF-related atrial remodeling is fatty infiltration,
which is known to increase in a number of myocardial pathophysiological conditions
and is regarded as arrhythmogenic.
175
,
176
,
177
Obesity is a known AF risk factor, and the increasing incidence of AF could be related
to increasing rates of obesity.
177
,
178
Obesity frequently coexists with other AF risk factors that improve in response to
weight loss, emphasizing the importance of weight loss in AF risk factor management.
179
Epicardial fatty infiltration occurs with obesity
180
and has been associated with AF.
177
Biofactors released from fat might promote fibrosis and myocardial remodeling.
Atrial Amyloidosis
Over the past decade, a number of studies have called attention to a link between
atrial amyloidosis and AF.
74
,
181
,
182
Amyloidosis is characterized by the presence of extracellular proteinaceous deposits
showing characteristic structural and tinctorial properties. The various types of
amyloidosis are distinguished based on the fibril protein deposited and the clinical
presentation. Amyloidosis can affect the heart as part of a systemic process, as in
immunoglobulin-derived light-chain amyloidosis. Amyloid can also be deposited in the
heart as a manifestation of aging (senile amyloidosis), with amyloid observed in cardiac
vessels, in the ventricular interstitium, and in the atria. The heart can also be
affected by an organ-limited variant called isolated atrial amyloidosis. The incidence
of isolated atrial amyloidosis exceeds 90% in the ninth decade. Studies have shown
that isolated atrial amyloidosis affects atrial conduction and increases the risk
of AF. Notably, there is an inverse correlation between isolated atrial amyloidosis
and atrial fibrosis.
Role of Intracellular Ca
2+
Dysregulation
Spontaneous Ca2+ release promoting triggered activity is likely to be an important
mechanism of AF initiation.
183
During AF, the exceedingly high frequency of atrial excitation is expected to lead
to RyR2 refractoriness
184
and downregulation of Ca2+ handling proteins,
158
acting to prevent triggered activity in the presence of persistent AF. RyR2 leakiness
is therefore unlikely to contribute to persistent AF.
185
However, such considerations do not apply in PAF, in which ectopic activity likely
related to Ca2+-dependent ectopy could play an important role. There is evidence that
Ca2+ released from the leaky RyR2 receptors in the sarcoplasmic reticulum (SR) is
exchanged by the Na+-Ca2+ exchanger (NCX), which produces an arrhythmogenic depolarizing
current that induces atrial ectopic activity.
186
,
187
In a mouse model characterized by progressive AF, SR Ca2+ leak is enhanced in association
with Ca2+/calmodulin-dependent protein kinase II (CaMKII)-dependent hyperphosphorylation
of the ryanodine receptor.
188
Genetic inhibition of the Ca2+ leak reduced structural remodeling and prevented the
development of persistent AF.
188
However, in isolated remodeled rabbit and human atrial myocytes, Ca2+ signaling was
silenced through a variety of mechanisms.
185
The authors suggested that Ca2+ silencing might be a protective mechanism against
the Ca2+ overload that occurs during chronic AF, and challenged the notion that aberrant
Ca2+ release contributes to the pathophysiology of persistent AF. However, during
AF, the exceedingly high frequency of atrial excitation is expected to lead to RyR2
refractoriness and downregulation of Ca2+-handling proteins, acting to prevent triggered
activity. Therefore, whether RyR2 leakiness contributes to persistent AF is now being
disputed.
158
,
184
,
185
A popular concept that had been promoted by some investigators over the last several
years was that both initiation and maintenance of AF could be related to increased
activity of protein kinase A (PKA) and/or Ca2+/CaMKII, with subsequent uncontrolled
diastolic Ca2+ release from the SR.
186
The idea is that Ca2+ released from the “leaky” RyR2 receptors in the SR would overactivate
the NCX to extrude Ca2+ and produce an arrhythmogenic depolarizing current, thereby
explaining both the contractile dysfunction and the high recurrence rate of the arrhythmia.
186
,
187
In a recent study in mice with a mutation causing progressive AF, SR Ca2+ leak was
reported to be enhanced in association with Ca2+/CaMKII–dependent hyperphosphorylation
of the ryanodine receptor.
188
Genetic inhibition of Ca2+/CaMKII-mediated RyR2-S2814 suppressed the Ca2+ leak, reduced
structural remodeling, and prevented the development of persistent AF.
188
However, recent studies in large animals and in humans have challenged the idea that
Ca2+ dysfunction underlies AF maintenance and perpetuation. In isolated rabbit atrial
myocytes, remodeling in response to sustained tachycardia for up to 5 days was shown
to silence Ca2+ signaling through a failure of subcellular propagated Ca2+ release.
185
The authors suggested that Ca2+ silencing might be a protective mechanism against
the massive Ca2+ overload that occurs during chronic AF. In another study in human
atrial myocytes, although CaMKII appeared to facilitate catecholamine-evoked arrhythmias
in the atrial myocardium of patients with sinus rhythm, the same agonists failed to
elicit arrhythmias in the atrial myocardium of patients with chronic AF, likely related
to atrial remodeling, which included decreases in CaMKII-mediated processes.
189
The above results in patients are consistent with data derived from western blot analyses
in sheep, designed to test whether remodeling was related to altered intracellular
calcium dysfunction.
158
Although the Na+-Ca2+ exchange was increased in the LAA of animals with persistent
AF, both total RyR2 and phosphorylated RyR2 proteins were decreased, and the ratio
of phosphorylated RyR2 to total RyR2 phosphorylation was unaffected. Thus, the transition
from paroxysmal to persistent AF in the sheep model of atrial tachypacing did not
appear to depend on Ca2+ leak or delayed afterdepolarizations (DADs).
Ion Channels and Electrical Remodeling
Electrical remodeling, manifested as shortening of atrial refractoriness, develops
within the first few days of AF.
13
,
153
,
154
,
190
A number of ion channel modifications underlying such electrical changes have been
described in animal models and humans.
17
,
190
,
191
,
192
A recent study
158
used a clinically relevant ovine model of intermittent RA tachypacing and demonstrated
that, after the first AF episode, the dominant excitation frequency (DF) increased
gradually during a 2-week period in both LA and RA until it stabilized at a time that
coincided with the onset of persistent AF. The DF changes were associated with downregulation
of ICaL and INa and upregulation of IK1, along with corresponding mRNA or protein
changes, as described in extensive previous studies of atrial remodeling.
17
Interstitial fibrosis developed at 6–12 months and coincided with persistent AF. This
study highlighted progressive forms of atrial remodeling in the increasing tendency
of AF to persist over time. Consistent with these findings, another study recently
demonstrated that AF persistence was associated with numerous transcriptional changes
in ion channel expression.
163
Such changes included upregulation of KCNJ2 and KCNJ4 (encoding Kir2.1 and Kir2.3
subunits, respectively, which contribute to IK1) and downregulation of CACNA1C (encoding
the ICaL α-subunit) and CACNAB2 (an ICaL β-subunit).
163
,
193
Therefore, the progressive DF increase during PAF is also consistent with the fact
that AF frequency is usually higher in patients with persistent than with PAF,
98
a difference that is now clearly due to sustained AF-related electrical remodeling.
Sustained AF shortens APD and the ERP, decreasing the wavelength and facilitating
the acceleration and stabilization of sustained reentry. The primary determinants
of APD shortening are the decrease in ICaL and increase in IK1.
158
Mechanisms of AF: Multiple Wavelet Hypothesis, Reentry, Spiral Waves, Rotational Activity,
and Focal Triggers from the Pulmonary Veins and Other Sites
For many years, three concepts competed to explain the mechanism of AF: multiple reentrant
wavelets (Figure 3A), rapidly discharging automatic foci (Figure 3B), and a single
reentrant circuit with fibrillatory conduction (Figure 3C).
194
,
195
,
196
Considerable progress has been made in defining the mechanisms underlying initiation,
perpetuation, and progression of AF (Figures 3, 4
).
16
,
17
A key breakthrough was the recognition that in some patients, AF is triggered and/or
maintained by rapidly firing foci and can be “cured” by local catheter ablation.
197
This crucial observation focused attention on the PV cardiomyocyte sleeves. Subsequent
work confirmed the key role of the PVs in AF, particularly paroxysmal forms, and showed
that the PVs have features that make them favored zones to harbor both focal automatic
and microreentrant activity.
157
Figure 3
Schematic drawing showing various hypotheses and proposals concerning the mechanisms
of atrial fibrillation. (A) Multiple wavelets hypothesis. (B) Rapidly discharging
automatic foci. (C) Single reentrant circuit with fibrillatory conduction. (D) Functional
reentry resulting from rotors or spiral waves. (E) AF maintenance resulting from dissociation
between epicardial and endocardial layers, with mutual interaction producing multiplying
activity that maintains the arrhythmia.
Figure 4
Structure and mechanisms of atrial fibrillation. (A) Schematic drawing of the left
and right atria as viewed from the posterior perspective. The extension of muscular
fibers onto the PVs can be appreciated. Shown in yellow are the five major left atrial
autonomic ganglionic plexi (GP) and axons (superior left GP, inferior left GP, anterior
right GP, inferior right GP, and ligament of Marshall). Shown in blue is the coronary
sinus, which is enveloped by muscular fibers that have connections to the atria. Also
shown in blue is the vein and ligament of Marshall, which travels from the coronary
sinus to the region between the left superior PV and the left atrial appendage. (B)
The large and small reentrant wavelets that play a role in initiating and sustaining
AF. (C) The common locations of PV (red) and also the common sites of origin of non-PV
triggers (shown in green). (D) Composite of the anatomic and arrhythmic mechanisms
of AF. Adapted with permission from Calkins et al. Heart Rhythm 2012; 9:632–696.e21.
2
The multiple wavelet concept was initially proposed by Garrey (Figure 3A), was later
refined by Moe, and for at least 50 years became the dominant mechanistic framework
for AF. Engelmann had earlier suggested that AF was maintained by rapidly discharging
atrial ectopic foci,
198
,
199
,
200
a notion that was subsequently rejected only to periodically resurface.
201
Finally, Thomas Lewis suggested that a single rapidly rotating primary reentrant circuit
(a “mother wave”) was the most likely mechanism underlying AF.
202
For AF due to a single ectopic focus or a rapidly rotating single circuit, fibrillatory
conduction is required to account for the irregular activation typical of AF.
203
All three of these classical mechanisms were proposed in the early 20th century and
continue to underlie much of the contemporary thinking about AF mechanisms.
195
As mentioned above, the observations of early investigators who recognized the importance
of the PVs in AF were critical. Their initial observations pointed to a critical role
for very rapidly discharging PV foci in maintaining AF. Subsequent experimental studies
indicated that the PVs could indeed represent sites of very rapid automatic activity,
which is enhanced by the rapid activation caused by AF.
204
Subsequent detailed studies of PV cardiomyocyte ion-current function
84
and structure
91
indicated that the PVs also have properties favoring local microreentry, which likely
contribute to their participation in AF. Recent studies have implicated abnormal Ca2+
handling and DAD related to spontaneous ectopic activity of patients with paroxysmal
or long-standing persistent AF.
186
,
205
However, more recent studies strongly suggest that during long-term sustained AF,
one should not expect an increase in the spontaneous release of Ca2+ from the SR,
nor that DADs or triggered activity is involved in AF maintenance or in the progression
to stable forms of the arrhythmia.
158
,
206
,
207
Subsequent to recognition of the importance of the PVs, a variety of sites other than
the PVs have been shown to potentially harbor AF-maintaining sources,
208
but the critical importance of the PVs has withstood the test of time.
Allessie et al induced and mapped electrically induced tachycardia in isolated rabbit
atria and documented the circular movement reentry in that model.
209
Using a limited number of electrodes, the authors detected an activation sequence
that suggested centripetal direction of wavelet propagation. The authors proposed
that these centripetal wavelets activated tissue at the center of the circuit, resulting
in double responses (double potentials) of subnormal amplitude. Because the centripetal
wavelets were unable to propagate beyond the center, they prevented the impulse from
shortcutting the circuit, resulting in the maintenance of reentry. This mechanism
of reentry was named leading circle reentry by Allessie et al.
209
Building on ideas put forward initially by Mines and later quantified by Wiener and
Rosenblueth, Allessie et al suggested that functional reentry naturally establishes
itself in the shortest circuit that can maintain reentry, defined by the distance
a cardiac impulse travels during the RP.
210
,
211
,
212
This distance determines the length of the shortest reentrant cardiac excitation wave
(wavelength, WL) and is equal to the product of conduction velocity (CV) and RP (e.g.,
WL = CV × RP). If AF is maintained by multiple simultaneous reentrant waves, the likelihood
of spontaneous termination is greatest when the atria are only large enough to maintain
one reentrant wave; if the wavelength is shortened so that multiple waves can be maintained
simultaneously, the chances of spontaneous termination will be greatly reduced and
AF is likely to be sustained. Evidence to support this notion was obtained in a dog
model by varying autonomic tone and administering antiarrhythmic drugs (AADs).
211
However, some clinical observations were incompatible with the leading circle mechanism,
notably the effectiveness of Na+ channel blockers in AF. According to the leading
circle notion, Na+ channel blockers should decrease the wavelength by reducing CV
and thereby promote, rather than terminate, AF. Furthermore, for many years, multiple
numerical studies and high-density mapping studies in cardiac tissues have failed
to confirm the idea of the leading circle or the presence of centripetal wavelets
in the maintenance of reentrant excitation.
Computer simulations and experiments in multiple mammalian species suggest that functional
reentry is better explained by rotors or spiral waves (Figure 3D). This idea was first
conceptualized by Russian scientists in the 1960s, and later popularized by Arthur
Winfree to explain the reentry in all excitable media.
213
,
214
,
215
The rotor is the organizing center of the reentrant excitation
215
; it spins at exceedingly high frequencies, radiating spiral wavefronts with outwardly
decreasing curvature, forming an Archimedean spiral, and resulting in wave fragmentation
in its periphery.
216
,
217
Because CV decreases as the wavefront curvature becomes steeper toward the center
tip, it follows that at that site (sometimes called the phase singularity [PS]) the
curvature reaches a critical value, the velocity becomes zero, and the PS follows
a circular trajectory.
215
,
218
At each point the direction of propagation is perpendicular to the wavefront and the
velocity increases toward the periphery. The PS is a unique point where the wavefront
and the wavetail converge and velocity is zero, preventing the impulse from extending
toward the center of the rotation. Instead, the PS becomes the rotor, circling around
a small center of unexcited but excitable tissue.
218
The concept of rotor can also be applicable to anatomical reentry in the atria; a
pectinate muscle or the orifice of a PV can stabilize a reentrant rotor.
156
,
219
Unlike leading-circle reentry, spiral-wave reentry is not determined by the wavelength,
but rather by the source-sink relationship between the activation wavefront and the
tissue that must be excited in front of it to maintain activity. The rotor concept
has been applied to AF, and subsequent studies have confirmed its ability to account
for the AF-suppressing actions of Na+ channel blockers.
119
Recent advances in electrophysiological recording and analysis have led to important
advances in appreciating AF-maintaining mechanisms in patients. Interestingly, they
have also led to new controversies. The application of advanced computing technology
to the definition of detailed intracardiac electrical activity based on highly sophisticated
body surface mapping (BSM), a technique called electrocardiographic imaging (ECGI),
has led to the noninvasive analysis of underlying mechanisms in patients with AF.
220
,
221
Both focal and reentrant rotor sources were visualized and tended to become more numerous
as AF was maintained for longer periods.
221
Detailed analysis of patients undergoing AF ablation indicates that rotors are localized
to specific atrial regions and tend to be short-lasting, with rotor cores tending
to occur at the interface between fibrotic tissue and more normal atria.
222
Investigators have also applied intra-atrial basket catheters and complex mathematical
analysis to define AF mechanisms and target them in the electrophysiology laboratory
with a technique called focal impulse and rotor modulation (FIRM).
77
FIRM procedures have identified rotational activity in patients with AF. A number
of studies have shown the superiority of FIRM-based ablation over conventional ablation
strategies.
223
However, the success of targeted rotational activity ablation, as well as the meaning
of rotors detected by FIRM technology, have been disputed in recent clinical studies.
A prospective randomized clinical trial is now underway. It is notable that conventional
mapping techniques using isochronal mapping have not been able to identify continuous
rotational activation.
224
,
225
It is also notable that detailed human atrial mapping studies have not observed discrete
rotors, but rather suggest that AF is maintained by dissociation between epicardial
and endocardial layers, with mutual interaction producing multiplying activity that
maintains the arrhythmia (Figure 3E).
226
,
227
,
228
,
229
Investigators have recorded more than 500 epicardial electrograms from both atria
during cardiac surgery in patients with persistent AF and were unable to identify
reentrant activity.
229
They interpreted their results as suggesting predominance of focal activity and breakthroughs.
Potential unifying findings were recently presented by investigators, who performed
high-resolution endocardial and epicardial optical mapping in explanted diseased human
hearts.
227
They noted that AF was driven by stable transmural reentrant sources anchored to anatomical
complexities and fibrotic regions. One limitation of their studies was a need for
an action potential abbreviating drug (pinacidil) to observe AF, limiting the applicability
of their findings to spontaneous AF.
In summary, although the presently available data leave a number of questions open,
they do indicate that both ectopic activity and reentry play important roles in AF.
The specific mechanisms and determinants remain to be elucidated, along with their
implications for therapy.
Mechanisms of Atrial Tachycardia and Atrial Flutter
Atrial arrhythmias can be broadly classified as focal, small circuit, or macroreentry
(Figure 5A–F). Focal ATs can originate from anywhere within the atria or venous structures
but do have a classical anatomic distribution (Figures 4, 5C). In the absence of a
prior LA catheter or surgical ablation procedure, approximately two-thirds of focal
tachycardias have an RA origin and one-third occur from the LA. In the RA, the most
common anatomic locations are the crista terminalis, tricuspid annulus, CS ostium,
and perinodal regions. In the LA, the pulmonary venous ostia and mitral annulus are
most common. Focal tachycardias also can arise from the LA and RA appendages, but
these sites of origin are rare.
Figure 5
Schematic drawing showing mechanisms of atrial flutter and atrial tachycardia. (A)
Isthmus-dependent reverse common (clockwise) atrial flutter. (B) Isthmus-dependent
common (counter clockwise) atrial flutter. (C) Focal atrial tachycardia with circumferential
spread of activation of the atria (can arise from multiple sites within the left and
right atrium). (D) Microreentrant atrial tachycardia with circumferential spread of
activation of the atria. (E) Perimitral atrial flutter. (F) Roof-dependent atrial
flutter.
Macroreentry is a broad term that encompasses what have been considered to be typical
and atypical atrial flutters (AFLs). The hallmark of macroreentry is that two sites
≥2 cm apart demonstrate entrainment with a postpacing interval–tachycardia cycle length
of ≤ 20 ms (i.e., within the circuit). The most common forms of atrial macroreentry
are variants of classical common and reverse common cavotricuspid isthmus-dependent
flutter (Figure 5A,B). These include both counterclockwise (common) and clockwise
(reverse common) variants, with the circuit originally described as a broad active
wavefront rotating around the tricuspid annulus. However, it is now recognized that
many variants exist, such as lower loop reentry and forms in which the active wavefront
crosses immediately anterior or posterior to the inferior vena cava. Rarely, intraisthmus
reentry can occur. Classical AFL almost invariably coexists with AF. Studies of AFL
onset and termination have demonstrated that both invariably require transitional
AF, indicating that flutter is largely a downstream arrhythmia. Attempts to modify
the natural history of AF by ablation of AFL have thus far largely been unsuccessful.
Nevertheless, cavotricuspid isthmus ablation is a simple procedure with high efficacy
and low risk that can provide good arrhythmia palliation in the appropriately selected
patient. However, long-term follow-up studies following flutter ablation have demonstrated
increasing prevalence of AF during long-term follow-up.
230
Atypical forms of macroreentry can occur in both the LA and RA and are most common
in the setting of prior atrial surgery or prior ablation for AF. They can also occur
spontaneously. In the RA, these can occur in the free wall, where a surgical or spontaneous
scar creates the central obstacle; or in the form of upper loop reentry in which the
SVC is the central obstacle, often with some anchoring scar. Circuits have also been
described around segments of the crista terminalis, which acts as a central barrier
and creates regions of slow conduction. Reentrant circuits on the right septum, even
in the context of surgical scars or prosthetic material, are uncommon. In the LA,
macroreentry is most common in the context of prior ablation. The type of circuit
varies according to the nature of prior ablation and to the underlying structural
heart disease. Patients with more advanced atrial remodeling, such as those with persistent
AF, will be more likely to have regions of slow conduction. Linear ablation particularly
induces macroreentry due to the propensity for gaps in lines to develop. At the gap
site, conduction can also be slowed due to the presence of damaged tissue. Common
reentrant circuits are perimitral- or mitral isthmus-dependent or, alternately, roof-dependent
circuits (Figure 5E,F), which occur around either the left- or right-sided PVs. Ablation
of these circuits can be accomplished by creation of a linear ablation lesion in the
form of a mitral or an anterior line for perimitral flutter or a roof line for roof-dependent
flutters. Microreentrant AFL can be ablated with a focal lesion (Figure 5D). When
flutter occurs through a gap in a preexisting line, focal ablation at that gap can
often be sufficient to create complete conduction block. With the diminished use of
linear ablation for persistent AF treatment, the prevalence of these circuits is expected
to diminish. Whenever linear ablation is required for ablation of a macroreentrant
circuit it is important to check for bidirectional conduction block. Macroreentrant
circuits can also occur in the LA around large regions of scar. These can either occur
spontaneously, particularly in the setting of structural heart disease and atrial
enlargement, or be due to prior ablation. Simultaneous dual-loop reentry can also
be observed in this situation. Left septal flutter has been described, but is an uncommon
arrhythmia. When patients present with macroreentrant arrhythmias following AF ablation,
it is important to also identify and ablate the trigger causing onset. Common sources
of triggers include the PVs, reflecting PV reconnection, or non-PV triggers.
Small circuit reentry has been described more recently, and most classically occurs
in the context of a prior catheter or surgical ablation procedure due to islands of
scar that form a central obstacle and regions of slow conduction (Figure 5D). The
definition of a small circuit as being less than 2 cm in diameter creates a rather
arbitrary distinction from macroreentry, but it does have clinical relevance. In the
majority of small circuits, a single focal isthmus of slow conduction can be found
in which focal ablation eliminates the circuit.
Potential Benefits and Rationale for Eliminating AF with Ablation
As described earlier in this document, AF is associated with many adverse outcomes,
including stroke, dementia, HF, impaired QOL, increased medical costs, and mortality.
Understanding the effect of catheter ablation of AF on these outcomes is important
in the overall assessment of the role of ablation in the long-term management of patients
with AF. There have been a number of studies that have examined long-term outcomes
with AF ablation. To date, however, none have prospectively randomized patients to
ablation vs medical management and followed them longitudinally for more than 1 to
2 years. There are some long-term prospective registries of patients who have undergone
AF ablation, with patients matched to those treated medically. Despite rigorous propensity
matching, there could still be unrecognized differences in the populations treated
with ablation compared with those receiving medical management. Thus, most of the
evidence we have, while suggestive of benefit from ablation, cannot be taken as definitive
with respect to major health outcomes. This lack is the rationale behind the Catheter
Ablation vs Anti-arrhythmic Drug Therapy for Atrial Fibrillation Trial (CABANA) (ClinicalTrials.gov
identifier NCT00911508), which is a prospective, randomized trial of ablation vs medical
management of AF. The trial has completed enrollment, but it will be some time before
the results are known.
It is widely recognized that AF ablation is effective in controlling AF and its associated
symptoms. Multiple studies have demonstrated that AF ablation improves QOL in a patient
with symptomatic AF, including those with HF.
231
,
232
Many patients with AF have HF with reduced ejection fraction (EF). Multiple studies
have examined the effect of ablation on EF.
63
,
76
,
233
,
234
,
235
,
236
In a meta-analysis of nine studies of AF ablation in patients with HF, mean EF improved
11% (95% confidence interval [CI] 6.9–15.3, P <.001).
237
The effect of ablation on the future risk of stroke is of great interest, partly because
of the morbidity and mortality associated with stroke, but also because of the need
to inform decisions regarding continuing anticoagulation in patients with apparently
successful ablations. A number of studies, but not all, have reported a low stroke
rate in patients who have undergone AF ablation when followed long term.
238
,
239
,
240
,
241
,
242
Although the results of these studies taken as a whole report a lower than expected
stroke rate, these results can be considered preliminary data because many of these
trials enrolled patients with a CHA2DS2-VASc score of < 2, in whom stroke rates will
be anticipated to be low. This reflects the fact that very few patients with a high
stroke risk profile were followed long term after suspension of anticoagulation. Notably,
it has recently been shown that patients with PAF have a lower stroke rate than those
with persistent AF.
51
These observations, while preliminary, are supportive of the emerging belief that
AF ablation could in fact reduce stroke risk. The ultimate proof that elimination
of AF by ablation lowers stroke risk will require a large, prospective, randomized
clinical trial such as CABANA. Limited studies have evaluated the effect of ablation
on the risk of dementia. Prior studies have reported that Alzheimer's dementia occurred
in 0.2% of AF ablation patients compared with 0.9% of patients with AF who did not
have ablation and 0.5% of patients without AF (P <.0001). Other types of dementia
were also reduced significantly in patients who had undergone ablation.
239
Although these findings are of interest, they must be considered preliminary because
this was not a prospective randomized trial. The impact of AF ablation on mortality
is also uncertain. Although a number of preliminary studies have reported encouraging
results, not all studies have reported a reduction in mortality. These results must
also be considered preliminary due to their study design.
232
,
239
,
241
In summary, there is strong evidence that AF ablation improves QOL, and reasonable
evidence that AF ablation improves ventricular function in those patients with AF
who have HF. The impact of AF control with ablation on other endpoints, including
stroke risk, dementia, and mortality, will require further study.
Electrophysiological Basis of AF Ablation
It is generally accepted that development of AF requires both a trigger and a susceptible
substrate. Figures 3
and
4
summarize the many mechanisms of AF. Over time, AF progresses from a trigger-driven
to a more substrate-mediated arrhythmia due to structural remodeling of the atria.
153
,
243
Ablative therapy is therefore aimed at either eliminating the trigger initiating AF
or modifying the arrhythmogenic substrate. The most commonly employed ablation strategy
consists of electrical isolation of the PVs by creation of circumferential lesions
around the right and the left PV.
197
,
244
,
245
A schematic overview of common lesion sets created during an AF ablation procedure
is shown in Figure 6
. The effects of these lesions have been attributed to isolation of AF triggering
PV foci, elimination of non-PV triggering foci, and/or as the result of modification
of the arrhythmogenic substrate.
246
The latter might include interruption of crucial pathways of conduction between pulmonary-atrial
junctions, which play a role in sustenance of AF, reduction of the amount of mass
available for the number of simultaneously circulating wavelets (atrial debulking),
or partial vagal denervation by interruption of vagal stimulation from the autonomic
ganglia.
109
,
247
,
248
,
249
Adjuvant substrate modification is targeted at patient-specific AF sources in the
RA and LA.
250
AF recurrences after an initially successful AF ablation procedure are typically associated
with PVI reconnection. A more recent strategy for AF ablation involves mapping and
ablation of rotational activity.
222
,
223
Figure 6
Schematic of common lesion sets employed in AF ablation. (A) The circumferential ablation
lesions that are created in a circumferential fashion around the right and the left
PVs. The primary endpoint of this ablation strategy is the electrical isolation of
the PV musculature. (B) Some of the most common sites of linear ablation lesions.
These include a “roof line” connecting the lesions encircling the left and/or right
PVs, a “mitral isthmus” line connecting the mitral valve and the lesion encircling
the left PVs at the end of the left inferior PV, and an anterior linear lesion connecting
either the “roof line” or the left or right circumferential lesion to the mitral annulus
anteriorly. A linear lesion created at the cavotricuspid isthmus is also shown. This
lesion is generally placed in patients who have experienced cavotricuspid isthmus-dependent
atrial flutter clinically or have it induced during EP testing. (C) Similar to 6B,
but also shows additional linear ablation lesions between the superior and inferior
PVs resulting in a figure of eight lesion sets as well as a posterior inferior line
allowing for electrical isolation of the posterior left atrial wall. An encircling
lesion of the superior vena cava (SVC) directed at electrical isolation of the SVC
is also shown. SVC isolation is performed if focal firing from the SVC can be demonstrated.
A subset of operators empirically isolates the SVC. (D) Representative sites for ablation
when targeting rotational activity or CFAEs are targeted. Modified with permission
from Calkins et al. Heart Rhythm 2012; 9:632–696.e21.
2
The Mechanisms of AF Recurrence After Catheter Ablation or Surgical AF Ablation
Although its efficacy has been established, both catheter and surgical ablation of
AF are associated with a substantial risk of AF recurrence.
251
,
252
It is important to recognize that late recurrences are often asymptomatic.
56
Recurrences of AF after ablation are generally classified into three types according
to the phase after ablation in which they appear: (1) early recurrence (within 3 months);
(2) late recurrence (from 3 months to 1 year); and (3) very late recurrence (more
than 1 year). The characteristics and optimal managements differ according to the
type of recurrence.
Early recurrence, which is defined as recurrence within the first 3 months after the
procedure, is observed in 50% or more of patients.
253
,
254
,
255
Although its precise mechanisms have not been fully elucidated, the possible causes
include (1) a transient stimulatory effect of the tissue inflammatory response to
the application of RF
256
; (2) a transient imbalance of the ANS257; and (3) a delayed effect of the application
of RF, likely due to the maturation of the ablation lesion soon after the procedure.
258
A “blanking period” of 3 months after the procedure, during which reintervention should
be avoided, is recommended because up to half of the patients with early recurrence
remain AF-free during long-term follow-up.
254
,
255
,
259
It has recently been shown that patients who experience multiple early recurrences,
especially more than a month postablation, are more likely to have an unsuccessful
response to AF ablation at 1-year follow-up. It is for this reason that some electrophysiologists
recommend early reablation in this subset of patients.
260
Late recurrence, during the first 9 months after the blanking period, occurs in 25%–40%
of cases
261
,
262
; however, the incidence differs depending on the patient population (ratio of paroxysmal
to persistent form) and the manner in which recurrence is screened for and detected.
Studies have shown that the mechanism for late-term recurrence is predominantly linked
to the recovery of electrical conduction between the PVs and the LA, irrespective
of the type of AF.
261
,
263
Accordingly, ongoing efforts are focused on identifying techniques to achieve permanent
PVI during an initial AF ablation procedure.
264
,
265
The incidence of very late recurrence (after more than 12 months postablation) has
been shown to be higher than previously expected. Multiple studies of long-term follow-up
data (more than 5 years) have demonstrated that the longer the follow-up postablation,
the higher the recurrence rate.
266
,
267
,
268
The predominant mechanism of very late recurrence includes PV reconnection, the development
of non-PV triggers, and development and maturation of substrate.
267
,
269
,
270
The predictors of the very late recurrence of AF appear to be the nonparoxysmal form
of AF at baseline, organic heart disease (valvular heart disease and cardiomyopathy),
advanced age, and obesity.
268
,
271
One study investigated the relationship between time to recurrence of AF following
AF ablation, response to therapy, and outcome.
272
This study found that time to recurrence is a major determinant of outcome. Patients
with later recurrences were more likely to have sporadic episodes and respond better
to AADs and repeat ablation. This observation suggests pathophysiological differences
based on time to recurrence, and have implications for clinical management.
Section 3: Modifiable Risk Factors for AF and Impact on Ablation
AF Risk Factors and Their Interaction with AF Management and Ablation
Management of patients with AF has traditionally consisted of three main components:
(1) anticoagulation for stroke prevention; (2) rate control; and (3) rhythm control.
With the emergence of large amounts of data, which have both defined and called attention
to the interaction between modifiable risk factors and the development of AF and outcomes
of AF management, we believe it is time to include risk factor modification as the
fourth pillar of AF management.
7
,
10
,
273
,
274
,
275
In this section of the document, we will review the link between modifiable risk factors
and both the development of AF and their impacts on the outcomes of AF ablation.
Obesity
Data from population studies have demonstrated a significant dose relationship between
increasing risk of developing AF and increasing severity of obesity.
8
This relationship holds true even after multivariate adjustment for other known risk
factors, with 3%–7% increased AF risk per unit increment of body mass index (BMI).
8
,
276
,
277
,
278
Obesity is an important contributor to the burden of AF, explaining one-fifth of all
AF cases.
279
Obesity results in significant atrial remodeling, which predisposes an individual
to the development of AF. Progressive weight gain has been associated with increasing
atrial size, interstitial fibrosis, pericardial fat, heterogeneous and slowed conduction,
and infiltration of the atrial myocardium by the adjacent pericardial fat.
180
,
280
,
281
As a consequence of these changes, AF is more frequently induced and sustained.
There is increasing recognition that obesity can influence the risk of AF recurrence
after catheter ablation procedures.
268
,
282
,
283
,
284
,
285
,
286
,
287
,
288
,
289
,
290
,
291
,
292
,
293
,
294
,
295
,
296
,
297
,
298
A recent meta-analysis identified 16 studies involving 5864 individuals reporting
on the link between obesity and recurrence of AF after catheter ablation, identifying
that there was a 3.1% greater risk of recurrent AF postablation for every one unit
increase in BMI (RR 1.03; 95% CI 1.00–1.07).
299
Much less information is available on the effect of weight management on reducing
the risk of developing AF and on the impact of weight management on AF burden and
the outcomes of ablation in those with AF. In light of the above discussion, it was
somewhat surprising that the 5067-patient Action for Health in Diabetes (Look AHEAD)
randomized trial of an intensive lifestyle intervention failed to reduce the risk
of developing AF in individuals with type 2 diabetes.
300
In a recent, randomized, controlled clinical study, patients with highly symptomatic
AF were randomized to either physician-directed weight and cardiometabolic risk factor
management or standard of care. Weight and risk factor management were associated
with a reduction in AF symptom burden and reduced number and duration of AFs on ambulatory
monitoring. Indeed, a dose-dependent improvement in arrhythmia-free survival has been
observed in obese individuals with AF who underwent weight loss in the Long-Term Effect
of Goal Directed Weight Management on an Atrial Fibrillation Cohort (LEGACY) study,
with the best outcomes being observed in those having a linear loss of weight ≥10%
and without weight fluctuation. The Aggressive Risk Factor Reduction Study for Atrial
Fibrillation and Implications for the Outcome of Ablation (ARREST-AF) cohort study
evaluated the impact of weight and risk factor management in the context of patients
undergoing AF ablation. In this observational study, adjunctive weight and risk factor
management resulted in improvement in AF symptoms and a 5-fold greater likelihood
of maintaining sinus rhythm after ablation; at a 42-month follow-up, 87% in the intervention
group, compared with 18% in the control group, were in sinus rhythm (P <.001).
301
Although there are randomized data demonstrating the impact of weight and cardiometabolic
risk factor management, data after catheter ablation remain observational and require
confirmation. A survey of the writing group shows that 96% recommend weight loss as
part of a comprehensive risk factor management strategy for patients with AF, including
those who are being evaluated for an AF ablation procedure. Eighty-eight percent of
the writing group consider a patient's BMI when discussing the risks, benefits, and
outcomes of AF ablation with a patient being evaluated for an AF ablation procedure.
One limitation to enacting a weight loss program is that only 34% of the writing group
members currently have ready access to a weight loss clinic at their center.
Sleep Apnea
Types, Assessment, and Treatment of Apnea
Sleep-disordered breathing includes OSA, central sleep apnea (CSA), periodic breathing
(including Cheyne-Stokes breathing), and sleep-related hypoventilation. OSA affects
approximately 24% of men and 9% of women between 30 and 60 years of age. Several studies
revealed that the prevalence of OSA is substantially higher among patients with AF
(ranging from 32% to 39%), indicating that OSA could be contributing to the initiation
and progression of AF.
OSA is caused by repeated upper airway collapse leading to oxygen desaturation and
disrupted sleep. Pathogenesis varies; predisposing factors include small upper airway
lumen, unstable respiratory control, low arousal threshold, and dysfunctional upper
airway dilator muscles. Risk factors include obesity, male sex, age, menopause, fluid
retention, adenotonsillar hypertrophy, and smoking. Continuous positive airway pressure
(CPAP) is the treatment of choice for OSA, with adherence of 60%–70%. The positive
pressure keeps the pharyngeal area from collapsing, and thus helps alleviate the airway
obstruction.
Bi-level positive airway pressure or adaptive servoventilation can be used for patients
who are intolerant of CPAP. Other treatments include mandibular advancement devices,
upper airway surgery, and lifestyle modification (weight loss, avoidance of alcohol
and sedatives).
AF Mechanisms in Sleep Apnea
A variety of mechanisms have been implicated in the pathogenesis of OSA-associated
AF.
302
Exposure of rats over 35 days to episodic hypoxia of the type caused by OSA causes
a sustained increase in blood pressure (BP) due to activation of sympathetic nerves
and the renin-angiotensin-aldosterone system.
303
Although intrinsic endothelial sensitivity appears unaltered in OSA, the vasoconstrictor
response to angiotensin is enhanced.
304
A variety of lines of evidence point to an important role of the ANS. Prolonged apneic
episodes in dogs (2 min) enhance ganglionated plexus neural activity and increase
AF inducibility.
305
Strong negative intrathoracic pressure applied to pigs during 2-minute apneic episodes
reduces the atrial ERP and enhances AF inducibility, effects reversed by atropine
or vagotomy.
306
Renal denervation suppresses postapneic BP increases, AF inducibility and neurohumoral
activation in pigs.
307
,
308
That altered autonomic nerve activity is not the entire explanation for the influence
of sleep apnea in AF occurrence was shown in a study of sleep apnea in a rat model
of obesity.
309
Obstructive apnea promoted AF induction in obese rats much more than in lean rats,
with only partial protection (<50%) by autonomic blockade. On the other hand, obstructive
episodes caused LA dilation that was enhanced in obese rats by obesity-associated
left-ventricular diastolic dysfunction. Prevention of LA dilation fully prevented
apnea-associated AF. In this model, neither obstructive apnea nor obesity was enough
to cause significant AF vulnerability; the interaction appeared necessary to cause
the degree of LA dilation needed to allow for AF induction.
Subsequent studies evaluated the effects of repeated obstructive apnea, as occurs
in patients with OSA, on cardiac structure, function, and electrophysiology.
310
In a rat model of repeated OSA for 4 weeks, atrial conduction slowed considerably
in association with connexin downregulation and atrial fibrosis. Left ventricular
dilation, hypertrophy, and diastolic dysfunction also occurred. In addition to the
remodeling-induced AF substrate caused by repeated apneic episodes, AF inducibility
was further enhanced by superimposed episodes of acute obstructive apnea in over 80%
of the rats.
310
The role of atrial remodeling by repeated OSA is supported by electroanatomical studies
in the clinical electrophysiology lab, with OSA associated with prolonged atrial conduction
times, slower conduction, reduced electrogram amplitudes, and widespread complex atrial
electrograms.
311
Finally, experiments in sheep demonstrated that hypercapnia per se causes profound
atrial conduction slowing and increased AF inducibility, which persists following
the return of CO2 levels to normal.
312
This effect was independent of oxygen levels. Taken together, the results suggest
that acute OSA episodes enhance AF vulnerability via a combination of LA dilation
and autonomic and electrophysiological changes; however, these abnormalities alone
are not enough to significantly enhance AF risk in normal hearts. Repeated nocturnal
OSA activates neurohormonal systems that over time produce sustained hypertension
and cardiac structural and electrophysiological remodeling. These render the atria
susceptible to AF, particularly during an acute OSA episode.
Sleep Apnea Treatment and AF Ablation Outcomes
Several studies have observed associations between AF and OSA. Epidemiological data
suggest AF prevalence and progression are linked with OSA severity,
313
,
314
whereas observational data have linked OSA with a more severely remodeled atrial substrate.
311
Treatment of OSA with CPAP, however, appears to favorably impact AF management, regardless
of the rhythm control strategy adopted.
315
,
316
Several studies have examined the impact of CPAP intervention on arrhythmia-free survival
following catheter ablation of AF.
283
,
289
,
290
,
291
,
316
,
317
,
318
,
319
Although OSA has been associated with poorer outcomes, CPAP appears to attenuate the
deleterious impact of OSA. Pooled analysis suggests that although OSA increases the
risk of AF recurrence following ablation (RR 1.31; 95% CI 1.16–1.48; P <.001), CPAP
therapy improves ablation success to rates comparable with non-OSA populations (RR
1.25; 95% CI 0.77–2.03; P = .37).
320
Nonuse of CPAP increases the risk of recurrent AF after ablation by 57% (RR 1.57;
95% CI 1.36–1.81; P <.001).
320
One study demonstrated an increased prevalence of non-PV triggers in patients with
OSA.
290
The observational nature of the literature that evaluates CPAP use in OSA, however,
limits its generalizability and precision. In most studies, formal sleep studies were
not used to systematically screen all patients for sleep apnea. Clinical history or
diagnostic questionnaires (e.g., Berlin questionnaire) formed the basis of OSA diagnosis
in some, whereas the diagnosis was rarely excluded by sleep study in non-OSA groups.
283
,
289
,
290
,
291
,
316
Similarly, treatment efficacy was assessed by self-reported CPAP use.
289
,
290
,
291
,
316
These study deficiencies lead to a poorly defined treatment effect of CPAP on AF recurrence
after ablation.
A survey of the writing group shows that 80% of the writing group members screen for
signs and symptoms of sleep apnea when evaluating patients for an AF ablation procedure.
This survey also revealed that 94% refer patients being evaluated for an AF ablation
procedure, in whom signs and symptoms of sleep apnea are detected, to a sleep center
for evaluation and management of sleep apnea. Eighty-six percent of the writing group
members currently have ready access to a sleep program at their center.
Hypertension
Hypertension is a well-established, independent risk factor for AF,
9
,
279
,
321
,
322
and this risk increases in patients with uncontrolled systolic BP,
323
particularly in those with EF less than 40%.
324
Even BPs that are near the upper limit of normal (systolic 130–139 mm Hg, diastolic
85–89 mm Hg) predict risk for AF in healthy middle-aged men
325
and women.
326
Hypertensive animal models have shown that elevated systolic and diastolic BP promote
the development of the atrial substrate for AF by increasing LA pressure, promoting
interstitial fibrosis and inflammatory infiltrates.
327
Following AF ablation, hypertension has been shown to be an independent predictor
of recurrence.
268
,
328
,
329
,
330
Conversely, patients with pharmacologically controlled hypertension could have similar
risk of AF recurrence postablation as those without hypertension.
279
Pooled analysis of two small studies demonstrated that renal artery denervation resulted
in both sustained lowering of BP and reduction in AF recurrence postablation.
127
,
331
However, the antiarrhythmic effect of renal denervation is not well established, and
whether it is mediated by remodeling of the hypertension-associated atrial substrate
or decrease in neurohormonal activation remains uncertain.
129
Whereas upstream therapy with angiotensin-converting enzyme inhibitors and angiotensin
receptor blockers might be effective for primary prevention of AF in patients with
systolic LV dysfunction or left ventricular hypertrophy,
332
their effect on secondary prevention postablation of AF is uncertain. Numerous, mostly
retrospective, studies have shown that modulation of the renin-angiotensin-aldosterone
system does not improve ablation outcome.
289
,
290
,
291
,
333
,
334
In summary, studies have shown that hypertension predicts AF recurrence after AF ablation;
however, it is not well established whether aggressive BP reduction with antihypertensive
therapy, modulation of the autonomic system, or inhibition of the renin-angiotensin-aldosterone
system is required for reducing AF reoccurrence in patients with hypertension undergoing
AF ablation. Despite this, aggressive treatment of hypertension is warranted in all
patients with AF due to the well-established link between hypertension and stroke
risk.
Diabetes
Diabetes promotes atrial remodeling characterized by diffuse interstitial fibrosis
and conduction slowing,
335
and has been shown to be an independent risk factor for development of AF.
9
,
336
,
337
At least 10 studies have evaluated whether diabetes or impaired glucose metabolism
predicts AF recurrence following ablation, with varying results. A systematic review
and meta-analysis reported that the risk of AF postablation was not elevated in patients
with diabetes.
338
Overall, studies have not consistently demonstrated differences in AF ablation outcomes
in patients with diabetes, and whether aggressive glucose control is effective for
secondary AF prevention following ablation is uncertain.
Alcohol
Alcohol consumption at varying degrees could increase the likelihood of incident AF
and might also elevate the risk of thromboembolic events and postablation recurrence
in patients with AF.
339
,
340
,
341
,
342
Fibrotic changes in the myocardium caused by alcohol toxicity potentially facilitate
development of LA scar and origin of non-PV triggers.
301
,
343
A recent observational study demonstrated a lower AF ablation success rate in moderate
and heavy drinkers.
342
Furthermore, binge drinking has been reported to be associated with increase in the
risk of postablation AF recurrence. Finally, the ARREST-AF study demonstrated significant
reduction in symptom severity, burden, and recurrence rate in patients with risk factor
management that included lowering alcohol intake to ≤ 30 g per week.
344
Thus, limiting alcohol intake is a potential target to increase the success rate in
AF ablation, but definitive evidence is required before stronger conclusions can be
made.
Exercise
Recent studies have observed a U-shaped risk relationship of physical activity to
AF. At one end of the spectrum, a large observational study of 64,561 people showed
that those at the lowest levels of physical fitness had a 5-fold increased risk of
AF.
345
Increasing the physical activity of sedentary patients could help reduce the risk
or burden of AF. For example, one randomized study demonstrated that just 12 weeks
of moderate-intensity physical activity decreased the AF burden by 41%.
346
Of the physically inactive with AF, the obese might benefit the most from moderate
levels of physical activity.
345
In contrast, a meta-analysis of 655 endurance athletes also demonstrated a 5-fold
increased risk of AF.
347
Of these studies, increased AF risk was generally only observed with the highest levels
of physical activity over a prolonged period of time.
348
,
349
One explanation for the exercise paradox is that both long-term endurance training
and a sedentary lifestyle increase chronic systemic inflammation.
The risk of AF from sustained high levels of physical activity is likely modulated
by age, given studies of young athletes have failed to show an increased risk.
350
,
351
Indeed, AF is the primary arrhythmia observed in middle-aged athletes.
352
AF in athletes tends to be paroxysmal, vagally mediated, and highly symptomatic.
353
Risk is augmented in athletes who are better conditioned, participate more often,
and have faster performance times.
354
The mechanism of increased AF risk at either end of the physical activity spectrum
likely includes autonomic, structural, inflammatory, and fibrotic changes to the heart.
For example, increased vagal tone, which is often observed in the endurance athlete,
has been shown to result in a short atrial RP, and thus initiates AF.
355
Most studies have shown structural changes in endurance athletes, which have resulted
in the term athlete's heart. These changes include dilatation of all four heart chambers,
increase in left ventricular mass, and mild right ventricular hypertrophy.
356
Initially, these adaptive changes were felt to be benign; however, emerging evidence
suggests otherwise, with endurance athletes experiencing higher-than-expected rates
of coronary artery calcium scores, myocardial fibrosis, AF, and sinus node dysfunction.
357
Long-term endurance training, as well as a sedentary lifestyle,
358
increase chronic systemic inflammation,
359
which in turn could also facilitate AF.
360
Studies show that moderate physical activity might reduce inflammatory markers.
361
,
362
,
363
Extreme levels of exercise are a known cause of cardiac fibrosis, particularly in
hinge point locations of the heart, such as the right ventricle; however, the significance
of MRI-detected fibrosis remains controversial.
349
Athletes who experience higher levels of fibrosis also have higher levels of coronary
calcium.
364
In turn, fibrosis is a well-established risk factor of AF.
365
In one study, the fibrotic changes caused by vigorous exercise were reversed after
an 8-week period of physical activity cessation.
366
One study showed an increase in collagen and other fibrosis biomarkers in athletes.
367
Murine models have found that losartan reduces all fibrosis biomarkers and the histologic
findings of fibrosis induced by long-term intensive exercise.
368
Although increasing physical activity might reduce AF in sedentary patients, decreasing
physical activity levels in elite endurance athletes could also reduce AF.
350
Professional athletes represent a unique treatment dilemma because medical therapy
for AF might not only reduce athletic performance but it could also be prohibited
in some sports.
369
Furthermore, many athletes have marked resting bradycardia, limiting use of AAD therapy.
Because most high-level endurance athletes are unwilling to give up or reduce their
level of their sports participation, AF ablation might be the only viable treatment
option for these patients. Although there are limited data on the efficacy of AF ablation
in athletes, two small studies involving a total of 276 patients suggested equal benefit
of ablation compared with AAD therapy for the endurance athlete.
370
,
371
However, caution should be exercised when interpreting these data because a third
small study reported that, although ablation can result in a durable arrhythmia-free
benefit, athletes typically require multiple procedures—an average of 2.3—to achieve
a long-term benefit.
372
Although moderate levels of physical activity have not been independently shown to
improve AF ablation outcomes in the sedentary patient, one observational study of
308 patients showed that increased physical fitness was associated with a dose-dependent
reduction in AF burden. Moreover, the AF benefit of physical fitness provided a 12%
incremental gain over weight loss, resulting in an improved AF risk factor profile,
inflammatory state, and cardiac remodeling.
373
These observed beneficial changes of moderate physical activity would predict a better
AF ablation outcome in the sedentary patient. Given that interventions aimed at increasing
physical activity could be more successful than those targeting weight loss,
374
increasing physical activity could be an attractive option to prevent or treat AF.
To date, however, definitive evidence of the impact of physical activity on ablation
outcomes is lacking.
Section 4: Indications
Recommendations and General Considerations
Shown in Table 2
, and summarized in Figures 7
and
8
of this document, are the Consensus Indications for Catheter and Surgical Ablation
of AF. As outlined in the introduction section of this document, these indications
are stratified as Class I, Class IIa, Class IIb, and Class III indications. The evidence
supporting these indications is provided, as well as a selection of the key references
supporting these levels of evidence. In making these recommendations, the writing
group considered the body of published literature that has defined the safety and
efficacy of catheter and surgical ablation of AF. Also considered in these recommendations
is the personal lifetime experience in the field of each of the writing group members.
Both the number of clinical trials and the quality of these trials were considered.
In considering the class of indications recommended by this writing group, it is important
to keep several points in mind. First, these classes of indications only define the
indications for catheter and surgical ablation of AF when performed by an electrophysiologist
or a surgeon who has received appropriate training and/or who has a certain level
of experience and is performing the procedure in an experienced center (Section 11).
Catheter and surgical ablation of AF are highly complex procedures, and a careful
assessment of the benefit and risk must be considered for each patient. Second, these
indications stratify patients based only on the type of AF and whether the procedure
is being performed prior to or following a trial of one or more Class I or III antiarrhythmic
medications. This document for the first time includes indications for catheter ablation
of select asymptomatic patients. As detailed in Section 9, there are many other additional
clinical and imaging-based variables that can be used to further define the efficacy
and risk of ablation in a given patient. Some of the variables that can be used to
define patients in whom a lower success rate or a higher complication rate can be
expected include the presence of concomitant heart disease, obesity, sleep apnea,
LA size, patient age and frailty, as well as the duration of time the patient has
been in continuous AF. Each of these variables needs to be considered when discussing
the risks and benefits of AF ablation with a particular patient. In the presence of
substantial risk or anticipated difficulty of ablation, it could be more appropriate
to use additional AAD options, even if the patient on face value might present with
a Class I or IIa indication for ablation. Third, it is important to consider patient
preference and values. Some patients are reluctant to consider a major procedure or
surgery and have a strong preference for a pharmacological approach. In these patients,
trials of antiarrhythmic agents including amiodarone might be preferred to catheter
ablation. On the other hand, some patients prefer a nonpharmacological approach. Fourth,
it is important to recognize that some patients early in the course of their AF journey
might have only infrequent episodes for many years and/or could have AF that is responsive
to well-tolerated AAD therapy. And finally, it is important to bear in mind that a
decision to perform catheter or surgical AF ablation should only be made after a patient
carefully considers the risks, benefits, and alternatives to the procedure.
Table 2
Indications for catheter (A and B) and surgical (C, D, and E) ablation of atrial fibrillation
Recommendation
Class
LOE
References
Indications for catheter ablation of atrial fibrillation
A. Indications for catheter ablation of atrial fibrillation
Symptomatic AF refractory or intolerant to at least one Class I or III antiarrhythmic
medication
Paroxysmal: Catheter ablation is recommended.
I
A
261,262,462,489,503, 655,673,684,709, 1027–1029
Persistent: Catheter ablation is reasonable.
IIa
B-NR
245,262,515,527,733, 1015,1025–1030
Long-standing persistent: Catheter ablation may be considered.
IIb
C-LD
245,262,515,527,733,1015,1025–1030
Symptomatic AF prior to initiation of antiarrhythmic therapy with a Class I or III
antiarrhythmic medication
Paroxysmal: Catheter ablation is reasonable.
IIa
B-R
370
,
372
,
377–383
Persistent: Catheter ablation is reasonable.
IIa
C-EO
Long-standing persistent: Catheter ablation may be considered.
IIb
C-EO
B. Indications for catheter atrial fibrillation ablation in populations of patients
not well represented in clinical trials
Congestive heart failure
It is reasonable to use similar indications for AF ablation in selected patients with
heart failure as in patients without heart failure.
IIa
B-R
233–237,384,386–395,1042
Older patients (>75 years of age)
It is reasonable to use similar indications for AF ablation in selected older patients
with AF as in younger patients.
IIa
B-NR
396–398
,
401–404
Hypertrophic cardiomyopathy
It is reasonable to use similar indications for AF ablation in selected patients with
HCM as in patients without HCM.
IIa
B-NR
385,1043,1044
Young patients (<45 years of age)
It is reasonable to use similar indications for AF ablation in young patients with
AF (<45 years of age) as in older patients.
IIa
B-NR
405,1045
Tachy-brady syndrome
It is reasonable to offer AF ablation as an alternative to pacemaker implantation
in patients with tachy-brady syndrome.
IIa
B-NR
381–383
Athletes with AF
It is reasonable to offer high-level athletes AF as first-line therapy due to the
negative effects of medications on athletic performance.
IIa
C-LD
370–372
Asymptomatic AF∗∗
Paroxysmal: Catheter ablation may be considered in select patients.∗∗
IIb
C-EO
416
,
418
Persistent: Catheter ablation may be considered in select patients.
IIb
C-EO
417
Indications for surgical ablation of atrial fibrillation
C. Indications for concomitant open (such as mitral valve) surgical ablation of atrial
fibrillation
Symptomatic AF refractory or intolerant to at least one Class I or III antiarrhythmic
medication
Paroxysmal: Surgical ablation is recommended.
I
B-NR
1290,1326–1338
Persistent: Surgical ablation is recommended.
I
B-NR
1290,1326–1338
Long-standing persistent: Surgical ablation is recommended.
I
B-NR
1290,1326–1338
Symptomatic AF prior to initiation of antiarrhythmic therapy with a Class I or III
antiarrhythmic medication
Paroxysmal: Surgical ablation is recommended.
I
B-NR
1290,1326–1338
Persistent: Surgical ablation is recommended.
I
B-NR
1290,1326–1338
Long-standing persistent: Surgical ablation is recommended.
I
B-NR
1290,1326–1338
D. Indications for concomitant closed (such as CABG and AVR) surgical ablation of
atrial fibrillation
Symptomatic AF refractory or intolerant to at least one Class I or III antiarrhythmic
medication
Paroxysmal: Surgical ablation is recommended.
I
B-NR
1339–1344
Persistent: Surgical ablation is recommended.
I
B-NR
1339–1344
Long-standing persistent: Surgical ablation is recommended.
I
B-NR
1339–1344
Symptomatic AF prior to initiation of antiarrhythmic therapy with a Class I or III
antiarrhythmic medication
Paroxysmal: Surgical ablation is reasonable.
IIa
B-NR
1339–1344
Persistent: Surgical ablation is reasonable.
IIa
B-NR
1339–1344
Long-standing persistent: Surgical ablation is reasonable.
IIa
B-NR
1339–1344
E. Indications for stand-alone and hybrid surgical ablation of atrial fibrillation
Symptomatic AF refractory or intolerant to at least one Class I or III antiarrhythmic
medication
Paroxysmal: Stand-alone surgical ablation can be considered for patients who have
failed one or more attempts at catheter ablation and also for those who are intolerant
or refractory to antiarrhythmic drug therapy and prefer a surgical approach, after
review of the relative safety and efficacy of catheter ablation versus a stand-alone
surgical approach.
IIb
B-NR
123,601,1306,1339–1341,1349,1351–1361
Persistent: Stand-alone surgical ablation is reasonable for patients who have failed
one or more attempts at catheter ablation and also for those patients who prefer a
surgical approach after review of the relative safety and efficacy of catheter ablation
versus a stand-alone surgical approach.
IIa
B-NR
123,601,1306,1339–1341,1349,1351–1361
Long-standing persistent: Stand-alone surgical ablation is reasonable for patients
who have failed one or more attempts at catheter ablation and also for those patients
who prefer a surgical approach after review of the relative safety and efficacy of
catheter ablation versus a stand-alone surgical approach.
IIa
B-NR
123,601,1306,1339–1341,1349,1351–1361
It might be reasonable to apply the indications for stand-alone surgical ablation
described above to patients being considered for hybrid surgical AF ablation.
IIb
C-EO
1361–1366
AF, atrial fibrillation; LOE, Level of Evidence; HCM, hypertrophic cardiomyopathy.
∗∗
A decision to perform AF ablation in an asymptomatic patient requires additional discussion
with the patient because the potential benefits of the procedure for the patient without
symptoms are uncertain.
Figure 7
Indications for catheter ablation of symptomatic atrial fibrillation. Shown in this
figure are the indications for catheter ablation of symptomatic paroxysmal, persistent,
and long-standing persistent AF. The Class for each indication based on whether ablation
is performed after failure of antiarrhythmic drug therapy or as first-line therapy
is shown. Please refer to Table 2B and the text for the indications for catheter ablation
of asymptomatic AF.
Figure 8
Indications for surgical ablation of atrial fibrillation. Shown in this figure are
the indications for surgical ablation of paroxysmal, persistent, and long-standing
persistent AF. The Class for each indication based on whether ablation is performed
after failure of antiarrhythmic drug therapy or as first-line therapy is shown. The
indications for surgical AF ablation are divided into whether the AF ablation procedure
is performed concomitantly with an open surgical procedure (such as mitral valve replacement),
a closed surgical procedure (such as coronary artery bypass graft surgery), or as
a stand-alone surgical AF ablation procedure performed solely for treatment of atrial
fibrillation.
As demonstrated in a large number of published studies, the primary clinical benefit
from catheter ablation of AF is an improvement in QOL resulting from elimination of
arrhythmia-related symptoms, such as palpitations, fatigue, or effort intolerance
(see Section 9). Thus, the primary selection criterion for catheter ablation should
be the presence of symptomatic AF. The indications for catheter and surgical ablation
of symptomatic AF shown in Table 2
, and summarized in Figures 7
and
8
, are for the most part consistent with the indications for AF ablation recommended
in the recently published 2016 ESC Guidelines for the Management of AF, as well as
in the 2014 ACC/AHA/HRS Guidelines for AF management.
5
,
6
These recommendations for AF ablation present the indications for AF ablation as second-line
therapy, after failure of a Class I or III antiarrhythmic agent and also the indications
for AF ablation as first-line therapy. As shown in Table 2
, catheter ablation is recommended for patients with symptomatic PAF who have failed
AAD therapy (Class I, LOE A). For patients with symptomatic persistent AF who have
failed AAD therapy, catheter ablation has a Class IIa, LOE B-NR indication, and for
patients with symptomatic long-standing persistent AF who have failed drug therapy,
catheter ablation has a Class IIb, LOE C-LD indication.
In preparing this document, the writing group has chosen to address for the first
time the important issue of catheter ablation of AF in select asymptomatic patients.
We have also addressed the important issues of AF ablation as first-line therapy,
the role of AF ablation in patients with HF, and the role of AF ablation in subgroups
of patients not well represented in clinical trials. Each of these important considerations
is addressed in detail below.
Catheter Ablation of AF as First-Line Therapy
The role of catheter ablation as first-line therapy, prior to a trial of a Class I
or III antiarrhythmic agent, is an appropriate indication for catheter ablation of
AF in patients with symptomatic paroxysmal or persistent AF. These recommendations
are consistent with the indications for AF ablation recommended in the recently published
2016 ESC guidelines for the management of AF as well as in the 2014 ACC/AHA/HRS Guidelines
for AF management.
5
,
6
,
375
,
376
For patients with paroxysmal symptomatic AF who have not failed drug therapy, catheter
ablation has a Class IIa, LOE B-R indication; for patients with persistent symptomatic
AF who have not failed drug therapy, catheter ablation has a Class IIa, LOE C-EO indication;
and for patients with long-standing persistent AF who have not failed drug therapy,
catheter ablation has a Class IIb, LOE C-EO indication.
There have been three prospective randomized clinical trials that have examined the
relative efficacy and safety of first-line AF ablation vs pharmacological therapy.
377
,
378
,
379
The outcomes of these three trials have recently been summarized in a meta-analysis.
380
A total of 491 young, generally healthy patients with predominantly PAF were randomized
to AF ablation vs pharmacological therapy. Catheter ablation of AF was associated
with a significantly higher freedom from AF recurrence, as compared with drug therapy.
The difference in the rate of symptomatic AF recurrences was not significant. There
was one procedure-related death due to a stroke in the ablation arm. The main major
complication was cardiac tamponade which occurred in 1.7% of patients in the ablation
arm. Taken as a whole, these findings provide evidence to support the role of AF ablation
as first-line therapy.
It is important to recognize that there are certain situations in which first-line
AF ablation is a preferred treatment option. For example, first-line AF ablation is
often recommended in patients with PAF who have symptomatic pauses (tachy-brady syndrome).
For these patients, initiation of pharmacological therapy would be inappropriate in
the absence of a permanent pacemaker. Over the past 15 years, a body of literature
has been published demonstrating that catheter ablation is effective, without concomitant
need of a permanent pacemaker in the great majority of patients with tachy-brady syndrome.
381
,
382
,
383
Based on this body of literature and the cumulative experience of the writing group,
we believe that it is appropriate to consider AF ablation as first-line therapy in
this clinical situation. Another specific population of patients in whom first-line
AF ablation is often recommended as an initial approach are high-level competitive
athletes with paroxysmal or persistent AF. These individuals often are strongly against
taking a medication, which could potentially reduce their peak heart rate and/or impair
cardiac function; they often have a marked resting bradycardia. Several studies have
reported favorable outcomes of AF ablation in this subgroup of patients.
371
,
372
,
373
Catheter Ablation of AF in Patients with Heart Failure and Reduced Cardiac Function
AF and HF are closely related conditions. HF can predispose an individual to the occurrence
of AF through various mechanisms, such as the increase of the left ventricular filling
pressure or LA dilatation and fibrosis, each of which can lead to atrial structural
and electrical remodeling. Conversely, AF with the loss of atrial contraction and
potential uncontrolled heart rate secondary to arrhythmia can predispose an individual
to the development of HF, thus leading to impaired contractility and reduced cardiac
output. AF can increase mortality in patients with left ventricular dysfunction; therefore,
the treatment of AF in this subset of patients is of pivotal importance.
Much controversy still exists regarding how to maintain sinus rhythm in patients with
HF; undoubtedly, however, maintenance of sinus rhythm is beneficial in restoring atrial-ventricular
coordination, thus favoring an improved left ventricular performance and a better
QOL.
The published literature describing the safety and efficacy of AF ablation in patients
with HF and/or a reduced EF is considerable. When viewed cumulatively, these published
results describe the outcomes of AF ablation in more than 1000 patients with HF.
233
,
234
,
235
,
236
,
237
,
384
,
385
,
386
,
387
,
388
,
389
,
390
,
391
,
392
,
393
,
394
Included within this large body of literature are four prospective, randomized clinical
trials, the results of which were recently summarized in a meta-analysis.
235
,
236
,
237
,
390
,
392
A total of 224 patients were randomized, among whom 83% had persistent AF. AF ablation
resulted in an increase in left ventricular ejection fraction (LVEF) by a mean of
8.5% compared with rate control alone. AF ablation also was superior to rate control
in improving QOL. Peak oxygen consumption and 6-minute walk test distance increased
in ablation compared with rate control patients. Major adverse events were not different
in the two treatment arms. The meta-analysis of these four studies concluded that
catheter ablation is superior to rate control in improving LVEF, QOL, and functional
capacity. This conclusion is consistent with other data that reveal that adequate
rate control alone is insufficient to prevent AF-mediated cardiomyopathy in a subset
of AF patients.
395
Prior to accepting a rate control strategy, patients with HF and persistent AF or
drug-refractory AF should be advised to consider AF ablation.
Based on this growing body of data, the writing group believes that catheter ablation
of AF is a safe, effective, and clinically acceptable therapeutic option in patients
with AF and HF. This applies both to patients suspected of having a cardiomyopathy
that is strongly suspected to be due to AF, with a rapid ventricular response, as
well as to other populations of patients with AF. The writing group recommends that
it is reasonable to use similar indications for AF ablation in selected patients with
HF as for patients without HF (Class IIa, LOE B-R).
Catheter Ablation in Older People
AF is in large part a disease of the older person. During the past decade, there have
been a number of studies that have specifically focused on reporting the outcomes
of AF ablation in older individuals.
396
,
397
,
398
,
399
,
400
,
401
,
402
,
403
,
404
The age cutoff for defining elderly varied between age ≥70 years, age ≥75 years,
397
,
402
,
404
and age ≥80 years.
398
,
399
,
400
,
401
The number of older people in these studies was small, with five of the seven studies
enrolling fewer than 100 patients and the largest reporting outcomes on 261 older
people. Taken as a whole, the results of these studies provide evidence that catheter
ablation of AF has an acceptable safety and efficacy profile in selected older individual
over the age of 75 or 80 years. However, as shown in analysis of the relationship
between age and 5-year outcomes of AF ablation,
403
age significantly impacts long-term outcomes of AF ablation. This study reported that
for every 10-year increase in age there was a higher multivariate-adjusted risk of
AF recurrence, death, and major cardiac events.
The writing group recommends that it is reasonable to use similar indications for
AF ablation in selected older people with AF as in younger patients (Class IIa, LOE
B-NR). It is important to note that the complications of the procedure are somewhat
increased in older individuals, the need for concomitant antiarrhythmic therapy postablation
is greater, and the efficacy is somewhat reduced.
396
,
405
It is also important to recognize that amiodarone, although not a good long-term pharmacological
option in younger individuals, is an appropriate treatment strategy in older people.
Catheter Ablation in Other Populations of Patients Not Well Represented in Clinical
Trials
Shown in Table 2
are indications for AF ablation in several additional subgroups of patients not well
represented in clinical trials. These subgroups include patients with hypertrophic
dilated cardiomyopathy, young patients (<45 years of age), high-level athletes, and
patients with tachy-brady syndrome. The references supporting the recommendations
of the writing group are shown.
Catheter Ablation to Reduce Stroke Risk
Patients with AF might seek catheter ablation to avoid long-term oral anticoagulation
(OAC) therapy. Multiple studies reported a low thromboembolic risk in patients who
discontinued OAC after successful AF ablation.
238
,
406
,
407
,
408
,
409
,
410
,
411
However, an important limitation of these studies is the fact that only a small subset
of patients had a CHA2DS2-VASc score ≥2, and almost no patients were at extreme increased
stroke risk due to a prior stroke or TIA and/or age ≥75 years. Recent data from the
German Ablation Registry
412
showed a high thromboembolic risk after ablation in high-stroke-risk patients. Furthermore,
it is well recognized that both symptomatic and asymptomatic AF can recur after AF
ablation procedures,
56
,
58
,
413
and late recurrence of AF is observed in 50% or more patients by 5 years. Absence
of symptomatic AF after ablation does not necessarily indicate an absence of asymptomatic
AF or a low risk of stroke.
414
The writing group also recommends that systemic anticoagulation with warfarin or a
novel oral anticoagulant (NOAC) is recommended for at least 2 months post-catheter
ablation of AF (Class I, LOE C-EO). The writing group recommends that decisions regarding
continuation of systemic anticoagulation more than 2 months postablation should be
based on the patient's stroke risk profile and not on the perceived success or failure
of the ablation procedure (Class I, LOE C-EO, Table 4
). Anticoagulation is recommended for patients with a CHA2DS2-VASc score of 2 in men
or 3 in women. For patients with one stroke risk factor (e.g., CHA2DS2-VASc 1 in men
or 2 in women), the role of OAC is borderline, and can “be considered.” Anticoagulation
is generally not recommended 2 or more months post-AF ablation in patients with a
low stroke risk profile (e.g., CHA2DS2-VASc 0 in men or 1 in women) unless cardioversion
is anticipated or has recently been performed.
415
Table 4
Anticoagulation strategies: pre-, during, and postcatheter ablation of AF
Recommendation
Class
LOE
References
Preablation
For patients undergoing AF catheter ablation who have been therapeutically anticoagulated
with warfarin or dabigatran, performance of the ablation procedure without interruption
of warfarin or dabigatran is recommended.
I
A
400
,
532
,
829
,
830
,
833
,
834
,
837
,
841
For patients undergoing AF catheter ablation who have been therapeutically anticoagulated
with rivaroxaban, performance of the ablation procedure without interruption of rivaroxaban
is recommended.
I
B-R
842
For patients undergoing AF catheter ablation who have been therapeutically anticoagulated
with a NOAC other than dabigatran or rivaroxaban, performance of the ablation procedure
without withholding a NOAC dose is reasonable.
IIa
B-NR
1395
Anticoagulation guidelines that pertain to cardioversion of AF should be adhered to
in patients who present for an AF catheter ablation procedure.
I
B-NR
5
,
6
For patients anticoagulated with a NOAC prior to AF catheter ablation, it is reasonable
to hold one to two doses of the NOAC prior to AF ablation with reinitiation postablation.
IIa
B-NR
835–840
Performance of a TEE in patients who are in AF on presentation for AF catheter ablation
and who have been receiving anticoagulation therapeutically for 3 weeks or longer
is reasonable.
IIa
C-EO
5
,
6
Performance of a TEE in patients who present for ablation in sinus rhythm and who
have not been anticoagulated prior to catheter ablation is reasonable.
IIa
C-EO
5
,
6
Use of intracardiac echocardiography to screen for atrial thrombi in patients who
cannot undergo TEE may be considered.
IIb
C-EO
768
,
820–824
During ablation
Heparin should be administered prior to or immediately following transseptal puncture
during AF catheter ablation procedures and adjusted to achieve and maintain an ACT
of at least 300 seconds.
I
B-NR
768
,
802–804
,
820
,
830
,
840
,
846–849
Administration of protamine following AF catheter ablation to reverse heparin is reasonable.
IIa
B-NR
851
Postablation
In patients who are not therapeutically anticoagulated prior to catheter ablation
of AF and in whom warfarin will be used for anticoagulation postablation, low molecular
weight heparin or intravenous heparin should be used as a bridge for initiation of
systemic anticoagulation with warfarin following AF ablation.∗
I
C-EO
Systemic anticoagulation with warfarin∗ or a NOAC is recommended for at least 2 months
postcatheter ablation of AF.
I
C-EO
1
,
2
Adherence to AF anticoagulation guidelines is recommended for patients who have undergone
an AF ablation procedure, regardless of the apparent success or failure of the procedure.
I
C-EO
5
,
6
Decisions regarding continuation of systemic anticoagulation more than 2 months post
ablation should be based on the patient's stroke risk profile and not on the perceived
success or failure of the ablation procedure.
I
C-EO
5
,
6
In patients who have not been anticoagulated prior to catheter ablation of AF or in
whom anticoagulation with a NOAC or warfarin has been interrupted prior to ablation,
administration of a NOAC 3 to 5 hours after achievement of hemostasis is reasonable
postablation.
IIa
C-EO
835–840
Patients in whom discontinuation of anticoagulation is being considered based on patient
values and preferences should consider undergoing continuous or frequent ECG monitoring
to screen for AF recurrence.
IIb
C-EO
AF, atrial fibrillation; LOE, Level of Evidence; NOAC, novel oral anticoagulant; TEE,
transesophageal electrocardiogram; ACT, activated clotting time.
∗Time in therapeutic range (TTR) should be > 65% – 70% on warfarin.
The writing group also recommends that adherence to AF anticoagulation guidelines
is recommended for patients who have undergone an AF ablation procedure, regardless
of the apparent success or failure of the procedure (Class I, LOE C-EO, Table 4
). Patients in whom discontinuation of anticoagulation is being considered based on
patient values and preferences should consider undergoing continuous or frequent ECG
monitoring to screen for AF recurrence (Class IIb, LOE C-EO, Table 4
).
414
A patient's desire to eliminate the need for long-term anticoagulation by itself should
not be considered an appropriate selection criterion for AF ablation. In arriving
at this recommendation, the writing group recognizes that patients who have undergone
catheter ablation of AF represent a new and previously unstudied population in trials
of OAC therapy. Clinical trials are therefore needed to define the stroke risk of
this patient population and to determine whether the risk factors identified in the
CHA2DS2-VASc or other scoring systems apply to these patients. Please refer to Section
7 for a more detailed discussion of this topic and the writing group recommendations
for long-term anticoagulation.
Catheter Ablation in Patients with Asymptomatic AF
The writing group believes that AF ablation may be considered in select asymptomatic
patients with paroxysmal or persistent AF when performed by an experienced operator
and following a detailed discussion of the risks and benefits of undergoing the procedure
(Class IIb, LOE C-EO). It is recognized that a decision to perform AF ablation in
an asymptomatic patient requires additional discussion with the patient, given the
potential benefits of the procedure for the patient without symptoms are uncertain.
AF ablation is not recommended for patients with asymptomatic long-standing persistent
AF. The justification for making this recommendation is as follows. First, it is well
established that the duration of time a patient is in continuous AF directly impacts
the outcomes of AF ablation or other rhythm control strategies. Whereas AF ablation
in patients with symptomatic PAF is associated with high efficacy, the efficacy of
AF ablation in patients who have been in continuous AF for 2 or more years is dramatically
reduced. Second, it is well established that AF is associated with an increased risk
of stroke, HF, dementia, and mortality. It is also notable that asymptomatic status
is associated with similar (or worse) prognosis compared with symptomatic status.
48
Furthermore, the risk of stroke has been shown to be lower in patients with paroxysmal
rather than continuous AF. Although large-scale, prospective, randomized clinical
trials have not been performed to evaluate the impact of AF ablation on stroke risk,
dementia, HF, and mortality, it is plausible that maintenance of sinus rhythm will
ultimately be shown to reduce these risks. While awaiting the results of these trials,
it is important to recognize that if a physician makes a decision to leave a patient
with apparent asymptomatic continuous AF in AF rather than to pursue restoration of
sinus rhythm, it will be extremely difficult or impossible to restore and maintain
sinus rhythm later in this patient's life.
There have been three small studies that have described the safety and efficacy of
AF ablation in patients with asymptomatic AF.
416
,
417
,
418
The first compared the outcomes of 54 patients with asymptomatic subclinical AF with
486 patients with drug-refractory symptomatic AF.
416
No difference in safety or efficacy of the procedure was observed at the 24-month
follow-up. The second study reported the outcomes of 61 patients with asymptomatic
long-standing persistent AF.
417
At 50 ± 5 months' follow-up, 57% remained AF recurrence-free after removal from drugs.
QOL improved, with the physical component summary and the mental component summary
demonstrating substantial improvement. Improvement was also noted on metabolic stress
testing. A third study compared the outcomes of 61 patients with asymptomatic persistent
AF with 132 otherwise matched symptomatic patients with AF.
418
In this study, the outcomes of ablation were superior in the symptomatic patients
compared with the asymptomatic patients (71% vs 27% freedom from AF). Also of note
was the fact that 16 patients (37%) in the asymptomatic group developed symptomatic
AT. Perhaps not surprisingly, the asymptomatic patients showed less improvement in
QOL than the symptomatic patients. The study concludes that the outcomes of AF ablation
are worse in asymptomatic patients, predominantly due to the risk of developing a
symptomatic AT postablation of asymptomatic AF. There are no prospective randomized
clinical trials that determine the benefit and risk ratio of ablation in patients
with asymptomatic AF.
While considering the issues of rhythm control and AF ablation in apparently asymptomatic
AF patients, the writing group of this document feels it is important to note that
many patients with apparently asymptomatic AF are in fact symptomatic once an assessment
of how the patient feels in sinus rhythm has been carried out. It has become common
practice, when faced with a relatively young person with apparently asymptomatic persistent
AF, to cardiovert the patient, with or without concomitant use of antiarrhythmic medications,
and then reassess the patients' symptom status while in sinus rhythm. In our experience,
many patients subjected to this “trial of sinus rhythm” recognize that they feel better
in sinus rhythm. This finding is important because a rhythm control strategy and/or
catheter ablation then becomes a more acceptable therapeutic strategy.
At the end of the day, the writing group believes that in selected patients, after
a careful discussion of the risks, benefits, and alternatives, that AF ablation may
be considered in patients with asymptomatic paroxysmal or persistent AF (Class IIb,
LOE C-EO) (Table 2
). Patients in whom this management strategy should be entertained include patients
whose clinical profile would be associated with a high efficacy and safety of AF ablation.
Indications for Surgical Ablation of AF
Indications for surgical ablation of AF are also shown in Table 2
and are summarized in Figure 8
. Safety and efficacy of AF ablation have been well supported for a surgical approach,
either performed in conjunction with another cardiac surgical procedure or when carried
out as a stand-alone procedure. The rationale and detailed indications for surgical
ablation of AF are discussed in more detail in Section 12.
Section 5: Strategies, Techniques, and Endpoints
Historical Considerations
Cox and colleagues are credited with developing and demonstrating the efficacy of
surgical ablation of AF.
419
,
420
Subsequent surgeons evaluated the efficacy of surgical approaches that limit the lesion
set to PVI.
421
,
422
The final iteration of the procedure developed by Cox, which is referred to as the
MAZE-3 procedure, was based on a model of AF in which maintenance of the arrhythmia
was shown to require a critical number of circulating wavelets for reentry. The success
of the Maze-3 procedure in the early 1990s led some cardiac electrophysiologists to
attempt to reproduce the procedure with RF catheter ablation. Swartz and colleagues
reported replication of the MAZE-1 lesion set in a small series of patients using
specially designed sheaths and standard RF ablation catheters.
423
The efficacy was modest, the complication rate was high, and the procedure and fluoroscopy
times were long. As a result, this approach was quickly abandoned. This report demonstrated
a proof of concept that motivated others to try to improve catheter-based ablative
treatment of AF. Subsequently, a large number of investigators attempted to replicate
the surgical MAZE procedure through the use of either three-dimensional (3D) mapping
systems or the use of multipolar ablation catheters. These clinical trials had limited
success.
424
,
425
,
426
,
427
,
428
,
429
Based on these observations and the rapid advances in ablation of AF targeting focal
triggers that initiate AF in the PVs, electrophysiologists lost interest in linear
non-PV-based approaches to catheter ablation of AF that attempted to replicate various
aspects of the surgical MAZE procedure.
The identification by Haissaguerre and colleagues of triggers that initiate AF within
the PVs led to prevention of AF recurrence by catheter ablation at the site of the
origin of the trigger.
197
,
430
,
431
,
432
,
433
Direct catheter ablation of the triggers was limited by the infrequency with which
AF initiation could be reproducibly triggered. To overcome these limitations, an ablation
approach was introduced
433
that was designed to electrically isolate the PVs. This segmental PVI technique involved
the sequential identification and ablation of the PV ostium close to the earliest
sites of activation of the PV musculature. An ablation strategy of encircling the
PVs guided by 3D electroanatomical mapping (EAM) was subsequently developed by Pappone
et al.
244
,
432
The recognition of PV stenosis as a complication of RF delivery within a PV, as well
as the recognition that sites of AF initiation and/or maintenance were frequently
located within the PV antrum, resulted in a shift in ablation strategies to target
the atrial tissue located in the antrum rather than in the PV itself.
434
,
435
Ablation at these sites was either performed segmentally, guided by a circular mapping
catheter
433
,
436
positioned close to the PV ostium, the so-called segmental PV ablation, or by wider
continuous circumferential ablation lesions created to surround the right or left
PVs,
244
,
432
the so-called wide-area circumferential ablation (WACA). The circumferential ablation
or isolation line was either guided by 3D EAM,
244
,
437
,
438
by fluoroscopy,
439
or by intracardiac echocardiography (ICE).
435
,
440
Studies comparing these two procedures reported contradictory data.
441
,
442
A subsequent randomized study compared isolation of each individual PV vs isolation
of large areas around both ipsilateral PVs. This study reported that isolation of
a large circumferential area around both ipsilateral PVs with verification of conduction
block is a more effective treatment of AF than segmental isolation of each PV.
443
The endpoint for this procedure was either amplitude reduction within the ablated
area,
244
,
437
elimination (or dissociation) of the PV potentials recorded from either one or two
circular mapping catheters, or a basket catheter within the ipsilateral PVs
435
,
438
,
439
,
441
,
442
,
444
and/or exit block from the PV.
445
PVI is now widely accepted as the cornerstone of AF ablation procedures (Table 3
).
2
Electrical isolation of the PVs is recommended during all AF ablation procedures (Class
I, LOE A). Elimination (or dissociation) of the PV potentials recorded from a multipolar
electrode catheter is the primary endpoint for AF ablation procedures for 95% of the
writing group members. A single-catheter approach to AF ablation, without employing
a circular multipolar electrode catheter as an ablation endpoint, is used by 5% of
the writing group members, whereas 95% employ both an ablation catheter and a mapping
catheter in the LA when performing AF ablation using either RF energy or cryoballoon
(CB) ablation (CBA). Due to the high recurrence rate observed in patients with persistent
and long-standing persistent AF with PVI alone, efforts continued to identify additive
strategies to improve the outcomes of AF ablation. These strategies have included
linear RF lesions in the LA and RA, ablation of autonomic ganglia, ablation by CFAE,
ablation of non-PV foci, isolation of the LAA, ablation of scar identified by voltage
mapping or MRI, and most recently, ablation of rotational activity. Whether any or
all of these strategies will emerge as standard proven components to AF ablation procedures
will be determined over time. The results of the recent randomized Substrate and Trigger
Ablation for Reduction of AF Trial Part II (STAR AF II) trial failed to demonstrate
any reduction in AF recurrence by adding either linear or CFAE ablation to PVI in
patients with persistent AF.
245
This study represented a sobering landmark in the field of AF ablation, which has
served to remind those in the field that rigorous clinical trials are needed to define
the safety and efficacy of a particular ablation strategy before it is adopted widely
as part of routine clinical care. Other advancements in the field include the introduction
of the CBA system, as well as the introduction of force-sensing ablation catheters.
In the following sections of this document we will go through the data supporting
each of these approaches and technologies in detail. We will also provide input as
to the importance of these approaches as assessed by this large international writing
group.
Table 3
Atrial fibrillation ablation: strategies, techniques, and endpoints
Recommendation
Class
LOE
References
PV isolation by catheter ablation
Electrical isolation of the PVs is recommended during all AF ablation procedures.
I
A
245,261,262,456,462,489,503,515,527, 655,673,684,709,733,1015,1025,1026,1027,1030
Achievement of electrical isolation requires, at a minimum, assessment and demonstration
of entrance block into the PV.
I
B-R
245,261,262,456,462,489,503,515,527,655,673, 684,709,733,1015,1025,1026,1027,1030
Monitoring for PV reconnection for 20 minutes following initial PV isolation is reasonable.
IIa
B-R
263
,
265
,
448
,
450
,
451
,
452
,
457–461
,
462
Administration of adenosine 20 minutes following initial PV isolation using RF energy
with reablation if PV reconnection might be considered.
IIb
B-R
265
,
448
,
449–451
,
454
,
456
,
461
,
463–468
Use of a pace-capture (pacing along the ablation line) ablation strategy may be considered.
IIb
B-R
264
,
472–475
Demonstration of exit block may be considered.
IIb
B-NR
445
,
477–481
Ablation strategies to be considered for use in conjunction with PV isolation
If a patient has a history of typical atrial flutter or typical atrial flutter is
induced at the time of AF ablation, delivery of a cavotricuspid isthmus linear lesion
is recommended.
I
B-R
230
,
504
,
511
,
1397
If linear ablation lesions are applied, operators should use mapping and pacing maneuvers
to assess for line completeness.
I
C-LD
245,504,506–508,510–513,1397
If a reproducible focal trigger that initiates AF is identified outside the PV ostia
at the time of an AF ablation procedure, ablation of the focal trigger should be considered.
IIa
C-LD
96
,
197
,
208
,
257
,
530
,
531
,
533–535
,
537–539
When performing AF ablation with a force-sensing RF ablation catheter, a minimal targeted
contact force of 5 to 10 grams is reasonable.
IIa
C-LD
453
,
468
,
668
,
670–686
Posterior wall isolation might be considered for initial or repeat ablation of persistent
or long-standing persistent AF.
IIb
C-LD
522–529
Administration of high-dose isoproterenol to screen for and then ablate non-PV triggers
may be considered during initial or repeat AF ablation procedures in patients with
paroxysmal, persistent, or long-standing persistent AF.
IIb
C-LD
96
,
197
,
208
,
257
,
530
,
531
,
533–535
,
537–539
DF-based ablation strategy is of unknown usefulness for AF ablation.
IIb
C-LD
587–594
The usefulness of creating linear ablation lesions in the right or left atrium as
an initial or repeat ablation strategy for persistent or long-standing persistent
AF is not well established.
IIb
B-NR
245
,
507–521
The usefulness of linear ablation lesions in the absence of macroreentrant atrial
flutter is not well established.
IIb
C-LD
245
,
507–521
The usefulness of mapping and ablation of areas of abnormal myocardial tissue identified
with voltage mapping or MRI as an initial or repeat ablation strategy for persistent
or long-standing persistent AF is not well established.
IIb
B-R
140
,
522
,
553–561
The usefulness of ablation of complex fractionated atrial electrograms as an initial
or repeat ablation strategy for persistent and long-standing persistent AF is not
well established.
IIb
B-R
245
,
514–517
,
540
,
545–552
The usefulness of ablation of rotational activity as an initial or repeat ablation
strategy for persistent and long-standing persistent AF is not well established.
IIb
B-NR
76
,
221–226
,
562–575
The usefulness of ablation of autonomic ganglia as an initial or repeat ablation strategy
for paroxysmal, persistent, and long-standing persistent AF is not well established.
IIb
B-NR
103
,
105
,
114
,
116
,
122–124
,
245
,
355
,
576–586
Nonablation strategies to improve outcomes
Weight loss can be useful for patients with AF, including those who are being evaluated
to undergo an AF ablation procedure, as part of a comprehensive risk factor management
strategy.
IIa
B-R
8
,
180
,
268
,
276–301
It is reasonable to consider a patient's BMI when discussing the risks, benefits,
and outcomes of AF ablation with a patient being evaluated for an AF ablation procedure.
IIa
B-R
8
,
180
,
268
,
276–301
It is reasonable to screen for signs and symptoms of sleep apnea when evaluating a
patient for an AF ablation procedure and to recommend a sleep evaluation if sleep
apnea is suspected.
IIa
B-R
283
,
289–291
,
302–320
Treatment of sleep apnea can be useful for patients with AF, including those who are
being evaluated to undergo an AF ablation procedure.
IIa
B-R
283
,
289–291
,
302–320
The usefulness of discontinuation of antiarrhythmic drug therapy prior to AF ablation
in an effort to improve long-term outcomes is unclear.
IIb
C-LD
617–621
The usefulness of initiation or continuation of antiarrhythmic drug therapy during
the postablation healing phase in an effort to improve long-term outcomes is unclear.
IIb
C-LD
617–621
Strategies to reduce the risks of AF ablation
Careful identification of the PV ostia is mandatory to avoid ablation within the PVs.
I
B-NR
434,505,778,927,928,1143–1160
It is recommended that RF power be reduced when creating lesions along the posterior
wall near the esophagus.
I
C-LD
341,417,637,806,866,900,906–911,920,1162–1178,1398
It is reasonable to use an esophageal temperature probe during AF ablation procedures
to monitor esophageal temperature and help guide energy delivery.
IIa
C-EO
341,417,910,1398
AF, atrial fibrillation; LOE, Level of Evidence; PV, pulmonary vein; RF, radiofrequency;
MRI, magnetic resonance imaging; BMI, body mass index.
Ablation Approaches Targeting the PVs and Techniques to Obtain Permanent PVI Using
RF Energy
Permanent electrical isolation of the PVs is well established as the cornerstone of
AF ablation. Despite the importance of this ablation endpoint, permanent electrical
isolation of the PVs can rarely be achieved.
263
,
446
,
447
,
448
,
449
,
450
,
451
,
452
,
453
,
454
,
455
,
456
Among patients returning to the electrophysiology laboratory for a repeat ablation
procedure after failing an initial ablation procedure, most studies report that recurrence
of PV conduction is observed in one or more PVs in more than 80% of patients.
263
,
446
,
447
,
452
,
454
Studies have also been performed to define the rate of PV reconduction among patients
who are AF-free after an initial PVI procedure. Although several of these series reported
rates of PV reconduction less than 20%,
263
,
447
most studies have reported far higher reconduction rates, varying from 62% to 90%.
449
,
454
,
456
The time course of electrical reconduction appears to be rapid, with studies reporting
acute reconduction rates of 33% at 30 minutes
448
,
450
,
451
and 50% at 60 minutes.
457
In this section of the document, we will review techniques that have been developed
in attempt to improve the rate of permanent PVI. We will also provide input concerning
which approaches are most widely used by the writing group members of this document.
Optimal Initial Lesion Creation and Waiting Phase
It is widely recognized that the likelihood of obtaining permanent PVI is related
to the quality of ablation energy delivery and lesion formation. There are many factors
that play a role in determination of lesion size. With RF energy it is well recognized
that important variables that impact lesion size and transmurality include catheter
stability, contact force (CF), power output, temperature, and duration of RF output.
Please refer to Section 6 of this document for a more detailed discussion of these
topics. Each of these variables is of importance. The writing group recommends that
when performing AF ablation with a force-sensing RF catheter, that a minimum targeted
CF of 5 to 10 grams is reasonable (Class IIa, LOE C-LD) (Table 3
).
The writing group also recommends that it is reasonable to use an esophageal temperature
probe during RF ablation procedures to monitor esophageal temperature and help guide
energy delivery (Class IIa, LOE C-EO) (Table 3
). In contrast to these two topics on which consensus was achieved, there is much
less consensus regarding power output and the duration of energy delivery because
a wide variety of approaches are used by members of the writing group.
One of the approaches that has been proposed as a technique to increase the rate of
permanent PVI is to incorporate a 20- to 30-minute waiting period following initial
isolation of each PV. The prevalence of time-induced PV reconnection is most frequent
at 30 minutes, with a significant proportion of patients having further reconnection
at 60 minutes and very few between 60 and 90 minutes.
265
,
448
,
450
,
451
,
457
,
459
,
460
,
461
In a retrospective study including patients undergoing a repeat ablation procedure
for recurrent AF, receiver operating characteristic analysis revealed a strong negative
correlation between the observation time after complete PVI during the initial procedure
and chronic PV reconnection.
452
The optimal cutoff value was 35 minutes, although the diagnostic accuracy was not
high (sensitivity 66.9%, specificity 60.6%). A small, prospective randomized trial
comparing the outcomes of AF ablation in which no waiting period, a 30-minute, and
a 60-minute waiting period was incorporated into the ablation procedure revealed a
clear benefit of incorporating a 30-minute or longer waiting phase (60.7%, 84.3%,
and 86.7%, respectively).
457
It is notable that reevaluation of the need for a waiting phase has not been reassessed
since the widespread availability of contact force-sensing (CFS) ablation catheters.
The need for a waiting phase has been less completely assessed with CB AF ablation.
The Sustained Treatment of Paroxysmal Atrial Fibrillation (STOP-AF) Trial did require
a 30-minute waiting period before termination of the observation period. It is unclear
whether this contributed to the 69.9% success rate in elimination of AF, although
those outcomes are similar to equivalent studies during that time frame.
462
The above data would suggest that a 20- to 30-minute waiting phase is reasonable to
incorporate into an AF ablation procedure. A limitation of a longer observation period
is the impact on the total procedure duration and work flow in the electrophysiology
laboratory. A survey of the writing group members shows that 80% incorporate at least
a 20-minute waiting period following initial isolation of the PVs when performing
AF ablation with RF energy. Based on this information, the published literature, and
the experience of this writing group, the writing group recommends that monitoring
for PV reconnection for 20 minutes following initial PVI “is reasonable” (Class IIa,
LOE B-R) during AF ablation using RF energy (Table 3
).
Adenosine Testing
Intravenous adenosine (or adenosine triphosphate [ATP]) can transiently restore cellular
excitability and differentiate permanent conduction block from dormant conduction
(e.g., viable but latently nonconducting tissue) across circumferential PV ablation
(CPVA) lines.
463
,
464
,
465
,
466
,
467
The ability of adenosine to unmask dormant PV reconnection is impacted by the adenosine
dose as well as by the waiting time since initial documentation of PVI.
466
,
467
The results of one recent study suggest that the demonstration of a physiological
effect of adenosine (e.g., sinus tachycardia, hypotension) is inadequate, and that
sufficient adenosine needs to be administered to demonstrate transient AV block.
467
There have been more than a dozen studies that have investigated the role of adenosine
as an adjunct to achieving permanent PVI and improving the outcomes of AF ablation;
these are summarized in a recent review article.
466
Among these studies are two large, prospective, randomized clinical trials.
The first study was a prospective, randomized clinical trial involving 534 patients
with PAF. All the patients were administered adenosine 20 minutes following initial
PVI. The initial dose was 12 mg, which was titrated until at least one blocked P wave
or a 3-second pause was observed.
265
The presence of dormant PV conduction was associated with an increased risk of arrhythmia
recurrence. Patients with dormant PV conduction were randomly assigned to additional
adenosine-guided or to no further ablation. Elimination of dormant PV conduction by
additional targeted ablation significantly reduced recurrent atrial tachyarrhythmias
(ATAs) by 56% during follow-up (P <.0001).
265
The most recent study enrolled 2113 patients with paroxysmal, persistent, and long-standing
persistent AF.
461
In this study, 0.4 mg per kg of adenosine was administered after a variable waiting
time (median time 43 minutes). Early reconduction after the waiting time alone was
observed in 42% of the patients in both groups. Subsequent administration of adenosine
demonstrated further reconduction in an additional 27% of the patients. Further ablation
was then performed to eliminate dormant conduction. At the end of 1 year of follow-up,
no difference in outcome was observed, with a success rate of approximately 65% in
each group. Of note, given the lower observed 27.6% prevalence of dormant conduction
in the latter trial, a risk reduction of 72.4% in those patients with dormant conduction
would have been required to detect a significant overall difference.
466
It is also notable that the use of force-sensing ablation catheters is associated
with a significant reduction in the prevalence of dormant conduction, therefore limiting
the impact of an adenosine-guided ablation strategy on clinical outcome.
468
Although the above data would suggest that administration of adenosine 20 minutes
after initial PVI at a dose titrated to achieve AV block or a 3-second pause could
improve outcomes of AF ablation, the impact of such a strategy is limited. Furthermore,
the addition of an adenosine testing strategy prolongs procedure time and increases
costs. A survey of the writing group members shows that 61% routinely incorporate
use of adenosine into their ablation procedure when using RF energy and 25% incorporate
this approach into their ablation strategy when using CB. Based on this information,
the published literature, and the experience of this writing group, the writing group
recommends that administration of adenosine 20 minutes after initial PVI phase “may
be considered” (Class IIb, LOE B-R) during AF ablation (Table 3
).
Isoproterenol Infusion
Some studies reported the use of adenosine during isoproterenol infusion to unmask
dormant PV conduction.
460
,
469
,
470
A prospective clinical and experimental evaluation of various pharmacological strategies
found that adenosine was superior to an isoproterenol infusion, with no significant
additional value of combining the two.
471
Therefore, although isoproterenol infusion can be used to identify non-PV triggers
in paroxysmal and persistent AF, there is only a limited role of isoproterenol infusion
alone to reveal dormant PV conduction after PVI. A survey of writing group members
shows that less than one-third administer isoproterenol to search for PV reconnection.
Loss of Pace Capture on the Ablation Line
The use of a pace capture-guided ablation strategy as an additional endpoint in PVI
procedures has been proposed as another method to improve the durability of PVI.
264
,
472
,
473
,
474
,
475
Using this approach, after completion of PVI, high-output pacing (10 mA) from the
ablation catheter's distal bipole is performed during sinus rhythm while slowly moving
the catheter along the entire circumference of the ipsilateral PVI lines.
264
,
472
Where local LA capture is identified, additional ablation is performed until loss
of capture, with the goal of closure of the residual gaps. In a recent randomized
study involving 102 patients at two centers, this technique significantly improved
arrhythmia-free survival compared with conventional PVI.
474
Another study compared an ablation strategy of loss of pace capture vs adenosine administration
to identify dormant conduction. The outcomes were no different in the two groups.
473
Another study revealed that a strategy of pace-capture-guided PVI was found to be
associated with a significant reduction in dormant PV conduction revealed by adenosine.
475
It is also notable that reevaluation of value of pace capture has not been reassessed
since the widespread availability of CFS ablation catheters.
Although the above data would suggest that using pace capture might improve outcomes
of AF ablation, the data are somewhat limited and have been published from a very
small number of centers. Like other strategies to improve outcomes of AF ablation,
this strategy also prolongs procedure time. A survey of the writing group members
shows that 24% routinely incorporate the strategy of pace capture when using RF energy.
This strategy is not applicable for the CB approach. Based on this information, the
published literature, and the experience of this writing group, the writing group
recommends that pace-capture-guided ablation strategy may be considered following
PVI with RF energy (Class IIb, LOE B-R) (Table 3
).
Exit Block
Although the demonstration of entrance conduction block is the standard endpoint of
PVI procedures, permanent PV exit conduction block (or the “stable absence of PV-LA
conduction”) is the ultimate goal for prevention of PV-induced AF. Exit block can
be demonstrated either by spontaneous discharges recorded circumferentially around
the PV or by continuing arrhythmia within the PV, which are dissociated from sinus
rhythm or by pacing from within the PV.
476
In the case of PV pacing, it is imperative to demonstrate local PV capture without
conduction to the LA to prove exit block. It is also important to avoid inadvertent
capture of adjacent far-field structures, which would result in misinterpretation
of apparent exit conduction.
477
,
478
The presence of entrance block appears to be effective in predicting bidirectional
block across CPVA lines.
141
,
142
,
143
Mechanistically, the most likely explanation is source–sink mismatch, which is defined
as delay or block of conduction observed when the size of a given excited region supplying
depolarizing current (the current source) is insufficient for the amount of depolarizing
current necessary to excite the regions ahead (the current sink).
479
Although an initial report has observed unidirectional entrance block in more than
40% of PVs,
445
the incidence was much lower in more recent studies (1.5%–16%).
477
,
479
,
480
,
481
Interestingly, in one of these studies, the presence of PV discharges conducted to
the LA (exit conduction) was followed by recovery of entrance conduction during a
30-minute waiting period.
480
None of the reported studies compared success rates of PVI using only verification
of PV entrance block vs bidirectional PV conduction block.
The above data would suggest that demonstration of exit block is feasible, and is
a reasonable endpoint for AF ablation when combined with the presence of exit block.
A survey of the writing group members shows that 60% routinely pace in the PV and
employ exit block as an endpoint during AF ablation using RF energy, and 46% routinely
pace in the PV and employ exit block as an endpoint during CBA. Based on this information,
the published literature, and group experience, the writing group recommends that
demonstration of exit block may be considered following PVI with RF or CB energy (Class
IIb, LOE B-NR) (Table 3
).
Techniques for Obtaining Permanent PVI with Balloon Technologies
PVI is the cornerstone of all ablation strategies in AF. However, it is still challenging,
and there exists a considerable learning curve to develop the skills needed to safely
and effectively perform RF AF under 3D electroanatomical guidance. Therefore, novel
catheter designs with alternative energy sources have been developed. These catheter
technologies are balloon-based ablation systems using various energy modalities, such
as cryoenergy (Arctic Front, Medtronic, Inc., Minneapolis, MN, USA), laser (Heartlight,
CardioFocus, Marlborough, MA, USA), and radiofrequency catheter (RFC) (Hot Balloon
Catheter, Hayama Arrhythmia Institute, Kanagawa, Japan). These technologies will be
discussed in detail in the technologies section of this document. The present section
will focus on some of the strategies that have been developed to facilitate the endpoint
of achieving permanent PVI.
Obtaining Permanent PVI with the Cryoballoon
The first-generation CB was introduced approximately 10 years ago and consisted of
a noncompliant balloon with two different diameters (23 mm and 28 mm), using N2O as
the refrigerant. A stiff wire or a spiral mapping catheter (Achieve, Medtronic, Inc.)
is inserted via a central lumen of the catheter shaft. Applying the first-generation
CB and freeze cycle durations of 300 seconds, successful PVI was routinely followed
by a bonus freeze cycle of the same duration. The 1-year success rate was approximately
70%–73%.
462
,
482
More than 80% of the patients with AF recurrence after first-generation CB-based PVI
demonstrated recurrence of conduction at the time of a repeat ablation procedure.
483
The second-generation CB (Arctic Front Advance, Medtronic, Inc.) was introduced in
2012 and incorporates a modified refrigerant injection system characterized by 8 injection
jets in a more distal balloon position. Thus, a more homogeneous cooling of the complete
distal balloon hemisphere, including the distal tip, was achieved. Multiple studies
have demonstrated clinical success rates of 65% or greater.
484
,
485
,
486
,
487
,
488
,
489
,
490
,
491
,
492
,
493
The recently published FIRE AND ICE trial was the first to compare the acute and long-term
efficacy as well as the safety profile of the second-generation CB with conventional
RFC ablation in a prospective, randomized, multicenter fashion.
489
The study demonstrated the noninferiority of CBA compared with RF-based ablation with
respect to efficacy and safety of patients with drug-refractory PAF.
494
However, secondary endpoints, such as the rate of rehospitalization and reablations,
or the necessity of electrical cardioversion during follow-up were in favor of CB.
490
Among patients who fail AF ablation with the CB2 system, recurrent PV conduction is
observed in 27% to 65% of patients.
487
,
491
The role of adenosine in revealing dormant conduction has also been evaluated. One
study reported that administration of 12 mg or more of adenosine (titrated to AV block)
30 minutes postablation resulted in an 11% incidence of recurrent PV conduction.
495
A second study reported similar findings, with a 12% incidence of recurrent conduction
after a waiting phase plus adenosine administration. This small study of 90 patients
reported a higher success rate (84% vs 79%) when a strategy of reablation based on
adenosine-induced dormant conduction was targeted.
495
A survey of the writing group shows that only 51% of the writing group members employ
a 20-minute or longer waiting phase when using CBA. This survey also revealed that
46% of operators routinely pace in the PV and employ exit block as a secondary endpoint
during AF ablation using CB energy.
Endoscopic Laser Balloon PVI
The endoscopic laser balloon is a recently introduced balloon-based ablation system
incorporating a titratable laser source and a 2F endoscope. This ablation system received
U.S. Food and Drug Administration (FDA) approval in the United States for ablation
of PAF in 2016. It consists of a compliant balloon (9–35 mm) that can be adapted according
to the individual PV diameter. The laser arc covers 30° of a complete circle and allows
energy titration in five steps, from 5.5 W to a maximum of 12 W. The rate of acute
PVI when applying this system is 98%–100%.
496
,
497
,
498
,
499
A study in which 52 patients underwent chronic reassessment of PV conduction revealed
that 14% of PVs demonstrated reconnection, translating to 38% of patients with reconduction
of one or more veins.
497
The application of higher energy levels (8.5 W or 10 W) was associated with a significant
increase in the rate of acute PVI after a purely visually guided ablation circle.
500
,
501
,
502
At the same time, the application of higher energy settings did not compromise the
safety profile. One-year clinical follow-up data from two prospective, multicenter
studies in patients with PAF demonstrated a single-procedure clinical success rate
of 63% and 60% with no anti-arrhythmic medication.
498
,
499
A prospective comparison with RF ablation revealed equivalent 1-year outcomes, with
a success rate of 61%.
503
There have been no studies that have examined how often vein reconnection is observed
within the first 60 minutes post-PVI. There are also no data on the role of adenosine.
Adjunctive Ablation Strategies to Be Performed in Addition to PVI During AF Ablation
Cavotricuspid Isthmus Ablation
Catheter ablation of typical AFL involving the cavotricuspid isthmus is a safe, effective,
and well-established ablation procedure. For patients undergoing AF ablation, creation
of a cavotricuspid isthmus line can be performed safely, easily, and with only a slight
prolongation in procedure time. A survey of the writing group members shows that ablation
of the cavotricuspid isthmus is performed by 94% of the writing group members in patients
undergoing AF ablation who have previously been documented by ECG to have experienced
isthmus-dependent AFL, as well as those with inducible cavotricuspid isthmus-dependent
AFL at the time of the ablation procedure. This is based on decades of experience
demonstrating the safety and efficacy of catheter ablation of AFL as well as data
from clinical trials comparing ablation with AAD therapy.
230,504,511,1397
The writing group recommends that if a patient has a history of typical AFL or typical
AFL is induced at the time of AF ablation, delivery of a cavotricuspid isthmus linear
lesion is recommended (Class I, LOE B-R, Table 3
).
Linear Lesions Not Involving the Cavotricuspid Isthmus
Circumferential isolation of PVs has become the standard therapy for PAF. However,
due to the high recurrence rate observed in patients with persistent and long-standing
persistent AF with PVI alone, continued efforts are underway to identify additive
strategies to improve outcome. One of these strategies is to create additional linear
lesions in the LA similar to those that are a part of that advocated with the Cox-Maze
III lesion set (Figure 6
).
505
,
506
The most common sites for linear ablation are the LA “roof” connecting the superior
aspects of the left and right upper PVI lesions, the region of tissue between the
mitral valve and the LIPV (the mitral isthmus), and anteriorly between the roof line
near the left or right circumferential lesion and the mitral annulus. A prior randomized,
prospective trial of catheter ablation of PAF comparing segmental PVI vs CPVA plus
LA linear ablation (CPVA-LALA) at the LA roof and myocardial infarction showed that
significantly more patients had LA flutter in the CPVA-LALA group.
507
A survey of the writing group shows that only 2% perform linear ablation during an
initial AF ablation in patients with PAF. For redo ablation procedures in PAF, only
10% of the writing group members routinely employ linear ablation. Based on this information,
the published literature, and the experience of this writing group, we recommend that
creation of linear lesions not be performed during initial or redo AF ablation for
PAF unless a macroreentrant AT is induced. The role of additional lines in cases of
persistent AF remains controversial.
508
The recently completed STAR-AF study of ablation strategies for persistent AF showed
no improvement in ablation efficacy for linear lesions plus PVI vs PVI alone.
245
The Catheter Ablation of Persistent Atrial Fibrillation (CHASE-AF) study also revealed
that the addition of linear lesions and defragmentation of PVI did not improve outcomes
for ablation of persistent AF compared with PVI alone.
509
For patients with persistent or long-standing persistent AF, 25% of the writing group
members perform linear ablation at the time of an initial ablation procedure, increasing
to 45% when redo procedures are performed in patients with persistent and long-standing
persistent AF. The writing group recognizes that the usefulness of linear ablation
lesions in the absence of macroreentrant AFL is not well established (Class IIb, LOE
C-LD). For patients with PAF, linear ablation should not be performed. The usefulness
of creation of linear ablation lesions in the RA or LA as an initial or repeat ablation
strategy for persistent or long-standing persistent AF is not well established (Class
IIb, LOE B-NR) (Table 3
). It has been widely demonstrated that incomplete block across the ablation lines
can be responsible for AT recurrence.
510
,
511
,
512
,
513
Therefore, if linear ablation lesions are applied, operators should use mapping and
pacing maneuvers to assess for line completeness (Class I, LOE C-LD) (Table 3
). Well-designed, prospective, randomized clinical trials must be the ultimate test
of linear ablation techniques.
In patients with long-standing persistent AF, the stepwise approach has been proposed.
514
,
515
The strategy starts by pulmonary isolation, followed by ablation of CFAE, looking
for reversion to sinus rhythm or AT. If this endpoint is not achieved, additional
linear lesions are deployed.
514
,
516
,
517
Whether the endpoint of AF termination is associated with improved long-term results
remains controversial.
518
Despite encouraging acute outcomes, with termination of AF in 80% of patients, the
follow-up data were less impressive with a 1-year single procedure efficacy of 35%
and a 5-year efficacy of 17%. Arrhythmia-free survival rates after the last procedure
(mean 2.1 ± 1.0 procedures) were 89.7% ± 2.5%, 79.8% ± 3.4%, and 62.9% ± 4.5%, at
1, 2, and 5 years, respectively.
515
More recent data also suggest that linear ablation does not improve outcomes compared
with PVI alone.
245
,
515
,
519
,
520
,
521
The recently completed CHASE-AF study also reported no improvement in efficacy for
ablation of persistent AF with PVI plus linear lesions and defragmentation compared
with PVI alone.
509
The clinical significance of these data, which appear to be contrary to our understanding
of the mechanisms of AF, predicting that AF is less likely to be sustained in electrophysiologically
smaller, segmented atria, is of clinical importance. Potential explanations for this
discrepancy might be that the linear lesions are incomplete, are in the wrong place,
or that our understanding of the AF mechanism is incorrect.
Posterior Wall Isolation
Some patients with PAF can be undertreated with PVI alone, and PVI might not be enough
to control persistent and long-standing persistent AF. Further modification of the
atrial substrate might be required. One of the strategies that has been proposed is
electrical isolation of the posterior wall. This can be performed by creating a linear
ablation of the LA roof joining the superior PVs and the LA floor joining the inferior
PVs or by point-by-point ablation of the entire posterior wall (Figure 6
). Entrance block of the box lesion is confirmed by lack of potentials in the box.
Exit block of the box lesion is confirmed by pacing in the box and demonstrating exit
block during sinus rhythm. Gaps along the ablation lines, if present, are mapped and
ablated.
522
,
523
,
524
With lack of LA capture outside the box, the lines are considered complete. The endpoint
of box isolation is defined as bidirectional conduction block, i.e., both lack of
potentials in the box and lack of LA capture.
Although some studies have been published that report improved outcomes,
525
,
526
with posterior wall isolation, other clinical trials report no improvement on outcomes.
527
The recently published BELIEF trial reported at 28% efficacy of an extensive ablation
strategy, including ablation of the posterior wall, in patients with long-standing
persistent AF.
528
,
529
A survey of the writing group shows that 15% of the writing group members perform
posterior wall isolation in patients with PAF during an initial AF ablation procedure,
and 18% isolate the posterior wall during a repeat ablation procedure in a patient
with PAF. The role of posterior wall isolation in cases of persistent AF also remains
controversial.
508
For patients with persistent or long-standing persistent AF, 22% of the writing group
members perform posterior wall isolation at the time of an initial AF ablation procedure
and 38% of the writing group members perform posterior wall isolation for repeat AF
ablation procedures in patients with persistent and long-standing persistent AF. Based
on this information and a review of the literature, the writing group recommends that
posterior wall isolation might be considered during an initial or repeat AF ablation
for paroxysmal, persistent, or long-standing persistent AF (Class IIb, LOE C-LD, Table
3
).
Nonpulmonary Vein Triggers
Non-PV “triggers” can be identified in 10%–33% of unselected patients referred for
catheter ablation of AF.
96
,
197
,
208
,
257
,
530
,
531
,
532
,
533
,
534
The prevalence of non-PV triggers in different studies varies with the specific definition
adopted, which ranges from repetitive atrial premature depolarizations without definitive
AF initiation
532
,
533
to reproducible sustained AF triggering.
534
Supraventricular tachycardias, such as AV nodal reentry or accessory pathway-mediated
AV reciprocating tachycardia, can also be identified in up to 4% of unselected patients
referred for AF ablation and can serve as a triggering mechanism for AF.
458
Non-PV triggers can be provoked in patients with both paroxysmal and more persistent
forms of AF.
531
,
534
In selected patients with reproducible non-PV triggers and without provocable PV AF
triggers with high-dose isoproterenol, elimination of only the non-PV triggers has
resulted in elimination of AF.
96
,
458
,
535
The most common sites of origin for non-PV atrial triggers include the posterior wall
of the LA, the SVC, the crista terminalis, the fossa ovalis, the CS, the eustachian
ridge, the ligament of Marshall, and adjacent to the AV valve annuli (Figure 4
).
96
,
208
,
458
,
530
,
531
,
536
More recently, frequent and repetitive atrial premature depolarizations have been
identified in the LAA in patients with more persistent AF, which have been targeted
by LAA isolation techniques.
532
,
533
Isoproterenol is the most commonly used agent to provoke non-PV triggers. Withholding
of antiarrhythmic agents for five half-lives and withholding beta-blockers for at
least 24 hours is important when a strategy of searching for non-PV triggers is employed.
A typical protocol for initiating non-PV triggers includes:
Baseline infusion of a vasoconstrictor (e.g., phenylephrine) to maintain mean arterial
pressure (MAP) >70 mm Hg and increase the bolus vasoconstrictor throughout infusion
to maintain adequate perfusion. This is particularly important under general anesthesia.
Careful titration of a vasoconstrictor allows for higher doses of isoproterenol infusion.
Graded infusion of isoproterenol using up to 20–30 μg per minute for at least 10 minutes
is recommended. Most members of the non-PV trigger writing group felt that lower-dose
isoproterenol infusion was frequently ineffective.
If no effect with isoproterenol infusion, burst pacing into AF and then cardioversion
during low-dose isoproterenol infusion (2–6 μg per minute) may be considered.
Use of adenosine bolus or burst atrial pacing during lower-dose isoproterenol infusion
to attempt to identify repetitive triggers after the drive train is an adjunctive
technique employed by a subset of the non-PV trigger writing group. Localization of
non-PV AF triggers can be challenging, particularly when only the first triggering
beat is being targeted, and typically involves recognition of specific intra-atrial
activation patterns on multipolar catheters placed in the RA and CS, together with
information from the surface ECG to help regionalize an area of interest.
458
,
534
,
535
Moving the circular mapping or ablation catheters around the LA and reinitiating AF
can be useful to localize AF triggers, taking care to minimize ectopy with catheter
manipulation. Placement of a multipolar catheter inside the SVC is important for identifying
SVC triggers. The majority of the writing committee members perform SVC isolation
if an SVC trigger is identified. To isolate the SVC, a circular mapping catheter is
placed inside the SVC to identify SVC potentials. Ablation is performed proximally
at the SVC/RA junction. While isolating the SVC, high-voltage pacing (at least 20 mA)
is used before each RF application to check for phrenic nerve (PN) stimulation. Ablation
is avoided in areas of PN capture, even if incomplete isolation is the result. SVC
isolation should ideally be performed in sinus rhythm after isoproterenol infusion
has worn off to avoid sinus node injury. RF application is ceased if sinus node acceleration
or pauses are observed. The endpoint of SVC isolation is entry and exit block into
the SVC, as is typically seen with PVI. Dissociated firing of the SVC can also be
observed. In contrast to wide-area PVI and because of phrenic capture or risk of sinus
node injury, a segmental approach targeting the earliest breakthrough on the circular
mapping catheter is most commonly employed.
While ablating AF triggers on the LA posterior wall, the RF power is typically decreased
to ≤ 30 W. An esophageal temperature probe is frequently used. The writing group also
recommends that it is reasonable to use an esophageal temperature probe during RF
ablation procedures to monitor esophageal temperature and to help guide energy delivery
(Class IIa, LOE C-EO, Table 3
). Some committee members isolate the entire posterior wall if numerous or multifocal
posterior wall triggers are identified. This can be accomplished using a “box” lesion
set, including a roof line (RSPV to LSPV) and floor line (RIPV to LIPV) after PVI.
If triggers are observed to be originating from the CS or the LAA, some writing committee
members perform isolation of these structures, while most prefer focal ablation. LAA
triggers can be identified by observing far field LAA activity on a circular mapping
catheter placed in the LSPV; placing the ablation catheter into the LAA should be
avoided to minimize risk of perforation or catheter-induced ectopy. Isolation of the
LAA should be performed only after prior discussion with the patient and consideration
of the long-term need for thromboembolic prophylaxis, with consideration given to
LAA closure by one of the available methods. For other non-PV triggers, such as AT,
AV nodal reentry tachycardia or AV reentrant tachycardia, focal ablation is performed.
Inability to provoke the trigger with repeat isoproterenol infusion is considered
as the endpoint. Observational studies have shown improved arrhythmia-free survival
when non-PV triggers are targeted for ablation and effectively eliminated at the time
of PVI.
537
,
538
In some redo ablation cases, if non-PV triggers cannot be provoked, empiric ablation
of non-PV trigger sites may be attempted. The empiric targeting of frequently defined
non-PV trigger sites can have more value in persistent forms of AF when triggers are
not observed with provocative maneuvers.
539
The most common empiric non-PV trigger ablation is SVC isolation. Other common sites
for empiric non-PV trigger ablation include the mitral annulus, limbus of the crista
terminalis, mid to inferior crista terminalis, and eustachian ridge.
539
Some investigators also advocate empiric LAA and CS isolation.
Despite the suggested improved outcome with elimination of non-PV triggers, the minority
of operators according to a recent European survey routinely perform non-PV trigger
initiation and ablation.
540
Ablation of non-PV triggers might be more important for patients with persistent forms
of AF and for those patients who undergo repeat ablation procedures in whom all PVs
are found to be isolated.
Additional investigation is needed on the optimum method for initiating and mapping
infrequent non-PV triggers. Furthermore, the value of routine non-PV trigger identification
and ablation with the initial ablation procedure and at the time of repeat procedure
following recurrence warrants further study.
A survey of the writing group members shows that when ablating PAF with the CB system,
18% also search for non-PV triggers. Among those who use RF energy for AF ablation
in patients with PAF, 41% routinely employ a strategy including administration of
high-dose isoproterenol to screen for and then ablate non-PV triggers. When performing
a repeat procedure in a patient with PAF, 57% of the writing group members search
for non-PV triggers. When ablating persistent and long-standing persistent AF with
RF energy, the percentage of the writing group members who use a non-PV trigger protocol
are 35%, and 46% for first-time and redo AF ablation procedures, respectively. Based
on this information and a review of the literature, the writing groups recommends
that administration of high-dose isoproterenol to screen for and then ablate non-PV
triggers may be considered during initial or repeat AF ablation procedures in patients
with paroxysmal, persistent, or long-standing persistent AF (Class IIb, LOE C-LD).
LAA Focal Ablation, Isolation, and Ligation or Resection
A relatively new non-PV-based strategy for ablation of AF involves targeting non-PV
triggers and reentrant tachycardias that arise from the LAA.
541
Over the past 5 years, new information has been published showing promising outcomes
using a variety of non-PV-based ablation strategies that target the LAA. These strategies
include focal ablation of non-PV triggers arising in the appendage,
541
electrical isolation of the LAA,
541
,
542
,
543
,
544
and most recently, ligation of the LAA, although this approach is an off-label use
of LA tissue ligation.
532
,
533
,
535
,
536
LAA isolation has been described using a technique similar to that of PVI: with the
circular mapping catheter positioned at the level of the LAA ostium, addressing the
earliest LAA activation site (preferably during sinus rhythm). Care should be taken
not to ablate inside the LAA (risk of perforation and PN injury). After LAA isolation,
patients should be kept on long-term OAC or considered for LAA occlusion. This reflects
the results of a recent study that has reported an increased stroke risk following
LAA electrical isolation.
544
The recently published BELIEF trial randomized 173 patients to start AF ablation or
to start standard AF ablation with empirical electrical isolation of the LAA. After
an average of 1.3 procedures, the cumulative success at 24 months' follow-up was 76%
in the combined group vs 56% with standard AF ablation.
528
,
529
One approach to address this potential issue is to combine LAA electrical isolation
with placement of a Watchman Device.
542
,
543
Recent animal and human studies have also reported the feasibility of this combined
strategy.
542
,
543
Currently, a prospective randomized clinical trial is being performed to determine
if LAA ligation with the LARIAT device will improve the efficacy of PVI in patients
with persistent AF. The outcome of this trial will be required to provide a clear
indication for this approach. A survey of the writing group members shows LAA focal
ablation, isolation, or ligation as an initial ablation strategy in patients with
PAF is used by 2% of the writing group members, and 4% use the above for repeat AF
ablation procedures in patients with PAF. For patients with persistent and long-standing
persistent AF, LAA focal ablation, isolation, or ligation was used by 9% of the writing
group members as an initial ablation strategy in patients with PAF, and was used by
11% of the writing group members for repeat AF ablation procedures in patients with
persistent and long-standing persistent AF. There is need for additional well-performed,
prospective, multicenter randomized trials in order to determine the safety and efficacy
of this approach.
Complex Fractionated Atrial Electrogram Ablation
More than a decade ago, CFAEs were reported to potentially represent AF substrate
sites and became target sites for AF.
516
,
545
CFAEs are electrograms with highly fractionated potentials or with a very short cycle
length (<120 ms). CFAEs are typically low-voltage multiple potential signals between
0.06 and 0.25 mV. The primary endpoints using this approach during RF catheter ablation
strategies for AF are either complete elimination of the areas identified with CFAEs,
conversion of AF to sinus rhythm (either directly or first to an AT), and/or noninducibility
of AF. In patients with persistent AF, the endpoint of ablation with this approach
is AF termination. Although use of the AF termination endpoint has been reported to
be associated with improved short-term outcomes, the long-term results have been disappointing.
245
,
515
,
517
,
546
When the areas identified with CFAEs are completely eliminated, but the arrhythmias
continue as organized AFL or AT, the ATAs are mapped and ablated. In patients with
long-standing persistent AF, a step-wise approach to ablation has been reported to
successfully convert AF to either sinus rhythm or AT in greater than 80% of patients.
514
,
547
Despite these encouraging acute outcomes, the follow-up data were disappointing, with
a 1-year single procedure efficacy of 35% and a 5-year efficacy of 17%.
515
One of the limitations of ablation targeting with CFAEs has been the extensive amount
of ablation needed. As a result, some strategies for differentiating “active” from
“passive” sites have been described. These include pharmacological interventions,
the use of monophasic action potentials, limiting ablation to areas of continuous
electrical activity, and activation mapping of AF.
540
,
548
,
549
,
550
,
551
Unfortunately, improved outcomes with CFAE ablation in patients with persistent AF
have not been uniformly reported, and the scientific basis for CFAE ablation is not
universally accepted. Moreover, results from the STAR AF II trial have shown that
the addition of further ablation (lines or CFAEs) to PVI increased ablation time but
did not reduce the recurrence of AF in 589 patients with persistent AF.
245
At 18 months, the percentage of patients who were free from AF recurrence after one
procedure without antiarrhythmic medication did not significantly differ among groups.
Similar findings were reported in the CHASE-AF trial, which reported that the addition
of defragmentation and linear ablation to PVI did not improve ablation outcomes for
persistent AF compared with PVI alone.
509
This suggests that CFAE has clearly lost momentum, perhaps in favor of less extensive
approaches for AF ablation.
552
None of the writing group members routinely employ CFAE-based ablation as part of
an initial ablation strategy in patients with PAF, and only 4% of the writing group
members employ CFAE ablation during repeat procedures. Ten percent of the writing
group members routinely employ CFAE-based ablation as part of an initial ablation
strategy in patients with persistent and long-standing persistent AF, and 26% incorporate
CFAE-based ablation for redo procedures in this subset of patients. Based on this
information and a review of the literature, the writing group recognizes that the
usefulness of CFAE-based ablation as an initial or repeat ablation strategy for persistent
and long-standing persistent AF is not well established (Class IIb, LOE B-R). Focal
ablation of sites targeted by CFAE without anchoring the lesion to a nonconducting
neighboring area might simply lead to formation of a substrate prone to produce future
AFLs. CFAE ablation is not recommended for ablation of PAF.
Ablation of Fibrosis Identified by Voltage Mapping and/or MRI Mapping
Another new ablation strategy that has been developed to improve the outcomes of ablation
involves targeting detected areas of fibrosis, based either on voltage mapping or
on MRI. The regional and individual extent of the fibrotic LA substrate in patients
with AF can be visualized during ablation intervention in sinus rhythm by applying
electroanatomical voltage mapping (EAVM). This technique led to the use of a patient-tailored
ablation strategy called box isolation of fibrotic areas (BIFA), with circumferential
isolation of the severely affected fibrotic areas (e.g., <0.5 mV), and with complete
isolation confirmed by a circular mapping catheter.
140
,
553
Early pilot data using this approach combined with PVI was encouraging.
This approach involves first isolating the PVs. A voltage map is then recorded during
sinus rhythm, and the low voltage areas are identified and subsequently isolated according
to the individual localization and extent. Efforts are made to connect these BIFA
ablation lines to the initial PVI lines to prevent the production of small channels,
such as is possible with CFAE or GP ablation. Using this approach, approximately one-third
of the patients with persistent AF were identified as not having substantial LA fibrosis
and, accordingly, only PVI was performed. This limited approach led to freedom from
AF at 12 months with a single procedure in 69% of the patients and with only 1.2 procedures
per patient in 85%.
140
These results were comparable to patients with substantial fibrosis and subsequent
BIFA ablation. In addition, in a small portion of patients with massive fibrosis (the
strawberry), failure of the initial ablation was likely, and further ablation procedures
were discouraged.
140
Other investigators have also described a tailored substrate modification based on
low-voltage areas.
554
They used several strategies, including linear lines encircling of low-voltage areas,
with demonstration of a significant reduction in local electrograms, defractionation,
and/or loss of capture. Even earlier, isolation of the posterior wall at the level
of the PVs without prior EAVM was introduced
522
; however, this strategy did not address the individual localization of the fibrotic
disease at that time. Several other groups have recently reported on voltage-guided
substrate modification in patients with persistent AF.
555
,
556
,
557
The durability of RFC-induced isolating lesions is clearly still an issue. The same
holds true for BIFA lines for substrate modification guided by EAVM. Recent technology
improvements of point-by-point catheter approaches (e.g., CF measurement) could further
pave the way for improving these approaches. However, the realization of the proposed
strategies for BIFA substrate modification requires of the operator extensive manual
skills and experience.
The methods to describe the fibrotic substrate with EAVM are also under intensive
investigation, and several limitations yet remain. The voltage maps using point-by-point
mapping not only take time, but the measured voltage also depends on the rhythm (sinus
rhythm vs extrasystole or AF), the contact of the electrode to the tissue, the thickness
of the atrial myocardium, the size of the mapping electrodes, interelectrode distance,
and other variables. Investigators described preexistent LA scarring in patients undergoing
PVI as an independent predictor of procedural failure.
558
Low voltage for abnormal areas in their study was also defined as an amplitude ≤0.5 mV,
and scar ≤0.05 mV, indistinguishable from noise. Other investigators recently described
contact EAM-derived voltage criteria for characterizing LA scar in patients undergoing
ablation for AF.
559
In their study, a voltage range of 0.2 to 0.45 mV was found to delineate scar. Others
used 0.2 to 0.5 mV as diseased and >0.5 mV as healthy.
554
This differs from the experience of another investigator, in whose studies 0.5 to
1.5 mV presented an intermediate zone that did not denote substantial fibrosis but
that also did not provide clear evidence for a normal atrial myocardium.
140
,
553
The fragmented electrogram appearance of voltages in the range of 0.5 and 1.5 mV frequently
argue in favor of mild fibrosis. Certainly, there is no “yes or no” with respect to
atrial fibrosis, but various grades can be observed. In summary, atrial scar is proposed
for sites with no discrete electrograms (apart from potential far-field electrograms)
and no local capture during pacing, dense fibrosis for sites with voltages ≤0.5 mV,
an intermediate zone of mild fibrosis for sites with voltages >0.5 to 1.5 mV, and
normal for sites with voltages >1.5 mV. However, with some exceptions, mild fibrosis
is even assumed at sites with voltages between 1.5 and 2.5 mV. Furthermore, criteria
need to be developed when other diagnostic catheters are used for EAVM, e.g., the
circular mapping catheter or the Pentaray catheter. Overall, these initial single-center
observational studies on ablation or isolation of fibrotic areas need to be confirmed
and extended in multicenter randomized studies.
Recently, the utility of delayed enhancement (DE) MRI has been introduced for detecting,
quantifying, and localizing atrial fibrosis, including the definition of four categories
of structural changes (Utah stages I–IV).
130
,
560
,
561
The tissue characterization of the LA wall on DE MRI correlated with EAVM and with
histology from surgical biopsy specimens.
560
,
561
The association of atrial tissue fibrosis and AF catheter ablation outcomes, with
more extensive fibrosis associated with lower efficacy, was confirmed in the multicenter
Delayed Enhancement MRI and Atrial Fibrillation Catheter Ablation (DECAAF) study.
365
On the other hand, these MRI findings at this point in time require extensive MRI
experience, including specification of image contrast and continuity, required to
set boundaries for the various degrees of fibrosis. The reproducibility of this approach
is still under investigation. A major limitation of this approach is that the degree
of scar identified depends strongly on the above thresholds used to define scar. At
the present time, no uniform standard has been developed. This limitation hinders
the reader-to-reader and day-to-day reproducibility of MRI-determined measurements
of atrial scar. Once established, however, the DE MRI quantification and localization
of atrial fibrosis might be used effectively to guide individually tailored substrate
elimination comparable to EAVM-guided substrate modification. Finally, tissue visualization
before and also during and directly after RF catheter ablation is the target for introducing
real-time MRI into the clinical electrophysiological laboratory. Currently, the DECAAF-2
trial has been launched to test the hypothesis that ablation of scar detected on MRI
improves ablation outcomes for persistent AF compared with PVI alone.
A survey of the writing group members shows that for patients undergoing an initial
AF ablation for PAF, 7% of the writing group members employ an ablation strategy based
in part on MRI or voltage mapping-detected scar, and 9% of the writing group members
employ this strategy for repeat AF ablation procedures in patients with PAF. For an
initial ablation procedure in patients with persistent and long-standing persistent
AF, 15% of the writing group members employ an ablation strategy based in part on
MRI or voltage mapping-detected scar. The proportion increases to 22% for repeat ablation
in patients with persistent or long-standing persistent AF. Based on this information
and a review of the literature, the writing group recognizes that the usefulness of
mapping and ablation of areas of abnormal myocardial tissue identified with voltage
mapping or MRI as an initial or repeat ablation strategy for persistent and long-standing
persistent AF is not well established (Class IIb, LOE B-R, Table 3
).
Mapping and Ablation of Rotational Activity
Several approaches have been developed to identify areas of rotational activity in
the atria. The first identification and targeted ablation of rotational activity with
fibrillatory activities was reported in 2005, using the noncontact mapping technique
by Lin et al.
562
The next system that was developed for clinical use employed two 64-pole basket catheters
to obtain simultaneous unipolar endocardial electrograms from 128 locations in both
atria of patients undergoing AF ablation.
563
A computational mapping system (RhythmView, Topera, Inc.) was used to process the
electrograms and generate activation movies of the atrial electrical activity. After
considerable processing and interpolation, evidence was found for rotational activity
in patients with paroxysmal, persistent, and long-standing persistent AF.
564
MAPs established the minimum repolarization interval and provided physiologically
feasible sequential activation paths. Movies of activation patterns and isochronal
maps from individual cycles showed circulating activity around a center of rotation
that was identified as rotational activity.
564
Focal (centrifugal) activations were also identified. Both were considered drivers
only if they sustained for ≥50 rotations or focal discharges.
563
This approach has recently been validated by linking FIRM simultaneously with optically
mapped rotational activity in the same human hearts.
76
Although early reports documented findings showing that this approach to mapping and
ablating rotational activity improved outcomes of AF ablation,
223
,
226
,
563
,
565
,
566
,
567
more recent studies have failed to confirm these early findings.
568
Issues associated with the FIRM-guided protocol that have contributed to uncertainty
regarding its clinical value include difficulties with basket catheter placement and
appropriate electrode contact, and the inability to identify atrial electrogram characteristics
expected from rotational activity that differ quantitatively from surrounding tissue.
At the time this document is being written, the approach of FIRM-guided ablation has
not been universally adopted. Considerable debate continues concerning the efficacy
of this ablation strategy. Further research is clearly needed.
223
,
564
,
566
,
569
At the present time, several prospective, randomized clinical trials are underway
to evaluate the long-term safety and efficacy of this approach.
Several other approaches have recently been developed to identify rotational activity
as a potential target for ablation. One of these systems involves the use of high-density
multipolar recordings with nonlinear analysis of the similarity index and phase mapping
of rotational activity. This approach has resulted in improved ablation outcome for
patients with persistent AF.
224
,
225
Another system that has been developed to noninvasively map rotational activity is
the ECGI mapping system.
221
,
570
,
571
,
572
This system utilizes a multielectrode vest that records 224 body surface ECGs; electrical
potentials, electrograms, and isochrones are then reconstructed on the heart's surface
using geometrical information from computed tomography (CT). A mathematical algorithm
combines the body surface potentials recorded by the electrodes and the geometric
information provided by CT and solves the electrocardiographic inverse problem in
order to noninvasively obtain estimated epicardial electrograms.
221
,
570
An advantage of this approach is that it is noninvasive, and thus can be used to provide
detailed follow-up information on AF recurrence. Disadvantages of the system are that
it is limited to providing virtual electrograms of the atrial epicardium; activity
on the interatrial septum, the PV-LAA ridge, etc., is not recorded. Another limitation
has to do with workflow and the fact that CT imaging is required to obtain the torso
geometry. An additional limitation of this system is that it requires the assumption
that the torso has uniform electrical properties when, clearly, thoracic tissue conducts
electricity nonuniformly. A clinical trial used ECGI combined with phase mapping to
identify the drivers of persistent AF in 103 patients undergoing AF ablation. They
observed continuously changing wavefronts and a wide variety of rotational activity
behaviors.
222
Reentrant drivers were unsustained and meandered substantially, but recurred repetitively
within the same region. Computation of aggregated driver-density maps over a cumulative
registering period allowed identification of a median of four driver domains per patient
and helped to guide the ablation procedure. Of note, the longer the duration of sustained
AF, the larger the number of driver regions. Ablation of driver domains alone terminated
AF in 75% of patients with persistent AF and in 15% of patients with long-standing
persistent AF. The onset or extinction of drivers during ablation was not assessed;
thus, there is room for improving the ablation results if real-time data are used.
222
At the 12-month follow-up, 83% of the patients with PAF and 75% of the patients with
persistent or long-lasting AF were free from AF.
222
At the present time, this system is not widely available, and few members of the writing
group have clinical experience with this system.
Other investigators have also reported the ability of body surface potential mapping
to detect rotational activity and stable propagation patterns during AF.
573
Phase maps computed from the TQ intervals in 64 surface potentials showed complex
patterns in which rotational activity could be identified, but they were unstable
and lasted for a very short time. Noninvasive BSM methodology has recently started
to gain momentum for the analysis of activation patterns during AF.
574
,
575
These investigators used a custom-made 67-electrode vest that covered the whole torso
of the patient; intracardiac signals at several locations were simultaneously recorded.
574
They selected either segments without ventricular activity after adenosine infusion,
or applied complex subtraction of QRST if such intervals were not found. After computing
and performing comparisons between intracardiac and surface DF maps, the investigators
demonstrated that high-frequency sources could be reflected on a small area of the
body surface close to the atrium harboring the highest DF.
574
More recently, investigators have used phase mapping to filter the unipolar signals
with a narrow 2-Hz band-pass around the highest DF (HDF filtering) to significantly
improve the detection of stable rotational activity.
575
Prior to HDF band-pass filtering, phase maps displayed unstable reentries, likely
as a result of superposition of the disorganized electrical activity coming from the
rest of the atrial tissue. HDF filtering accentuated the organized activity of scroll
waves, after which rotational activity was the main pattern of activation during AF
(median of 2.8 rotations, present 73% of the time). Also, computer simulations showed
that epicardial propagation is spatially smoothened when projected on the torso. For
example, nearby epicardial rotational activity with opposing chirality might not be
detected on the torso. This fact and the possibility of temporal intervals in which
AF activity can be affected by ectopic foci, could explain the lack of detected rotational
activity during the remaining 27% of the time.
575
Improved understanding of underlying mechanisms improves therapy. High-frequency reentrant
sources are an important mechanism of AF maintenance in humans, even if other mechanisms
might also be involved in AF initiation and maintenance.
17
Experimental data and ablation outcomes are making it increasingly clear that multielectrode
approaches that provide simultaneous acquisition of tens or hundreds of recording
sites from the fibrillating atria provide substantial improvement for the identification
and eventual termination of AF sources. Although there is still substantial room for
improvement, mapping technology is evolving at an accelerating pace, which gives hope
that novel breakthroughs will enable panoramic assessment of the underlying mechanisms
that underlie electrical turbulence in AF. Simultaneous high-resolution panoramic
assessment of wave propagation from the body surface and the endocardium could help
in tracking drifting or more stationary rotational activity trajectories over wide
areas of the atria with better accuracy, and hopefully should advance ablation therapy.
An important issue with these mapping forms is that they are critically dependent
on electrogram acquisition, electrogram integration, and a variety of signal manipulations
with mathematical techniques, including inverse solution, Hilbert, and phase transformations
that produce an additional level of complexity in attempting to simplify mapping.
Registration of the maps to anatomic structures, or CT or MRI and subsequent navigation,
likewise add complexity to the process and underscore the need for additional translational
and clinical studies to validate and clarify their utility.
A survey of the writing group shows that none of the members routinely employ ablation
of rotational activity during initial or repeat ablation procedures in patients with
PAF; 7% do so during initial ablation of persistent and long-standing persistent AF,
and 9% do so during repeat ablation of persistent and long-standing persistent AF.
Based on this information and a review of the literature, the writing group recognizes
that the usefulness of ablation of rotational activity as an initial or repeat ablation
strategy for persistent and long-standing persistent AF is not well established (Class
IIb, LOE B-NR, Table 3
).
Localization and Ablation of Left Atrial Ganglionated Plexi
Recent experimental and clinical studies have shown that the intrinsic cardiac ANS,
which is formed by interconnected clusters of autonomic ganglia, known as GP, plays
an important role in the initiation and maintenance of AF.
103
,
105
,
114
,
116
,
124
,
355
,
576
,
577
,
578
,
579
,
580
,
581
,
582
Because the GP are consistently located within areas of highly fractionated atrial
potentials (FAPs), also referred to as CFAEs,
103
,
105
,
114
,
116
,
124
,
355
,
576
,
577
,
578
,
579
,
580
,
581
,
582
,
583
,
584
it is useful to begin with a fractionation map of the LA and PVs during AF. The LA
FAPs are usually located in four areas: (1) LAA ridge FAP area (between LAA and left
PVs); (2) superior left FAP area; (3) inferoposterior FAP area; and (4) anterior right
FAP area (Figure 4
). GP can be localized using HFS to identify sites exhibiting transient AV block during
AF. In one approach,
124
,
582
endocardial HFS (cycle length 50 ms, 12–15 V, 10 ms pulse width) is delivered through
the distal pair of the electrodes on a mapping or ablation catheter to sites within
FAPs in the LA. Sites exhibiting a positive HFS response (transient AV block, increase
in mean R-R interval >50% during AF) identify the 5 major GP (Marshall tract GP, superior
left GP, anterior right GP, inferior left GP, and inferior right GP) (Figure 4
). HFS of a GP generally increases the degree of fractionation in the adjacent PV
and frequently in distant PVs.
For endocardial catheter ablation of the GP, RF energy is applied to each site exhibiting
a positive HFS response (usually 25–35 W for 30–60 seconds, but the RF power and/or
time is reduced when close to the esophagus).
105
,
124
,
582
HFS is repeated after each RF application. If the positive HFS response is still present,
RF energy is reapplied until the response is eliminated (generally only one or two
RF applications are required). Ablation of each of the five GP areas usually requires
2–12 (median 6) RF applications.
124
,
582
A positive HFS response might not identify the entire GP area. HFS-induced transient
AV block is driven by activation of the inferior right ganglionated plexi (IRGP).
Therefore, activating the Marshall tract GP, superior left GP, inferior left GP, or
anterior right GP by HFS is followed by activation of other GP, including the inferior
right GP, which innervates the AV node. The positive response to HFS (transient AV
block) might not occur, due to ablation of one of the intermediate GP along the line
to the IRGP. To minimize the loss of a positive HFS response, ablation of the GP should
be performed in the following order: Marshall Tract GP, superior left GP, anterior
right GP, inferior left GP, and finally inferior right GP. Other signs of GP activation
(such as the onset of PV firing other than the PV adjacent to the stimulated GP) are
occasionally observed during HFS, which does not produce an AV block response, suggesting
lower sensitivity of HFS in identifying GP. Some reports targeted GP without HFS,
delivering RF applications to the presumed anatomical locations of the GP.
245
,
576
,
583
,
584
The GP (identified by HFS) are consistently located within an area of FAPs, which
is much larger than the GP area, suggesting that although GP ablation consistently
produces CFAE (or FAP) ablation, CFAE ablation is not equivalent to GP ablation. In
patients with either paroxysmal or persistent AF, GP ablation (before PVI) significantly
reduced the inducibility of sustained AF. If AF remains inducible after GP ablation,
GP ablation often eliminates the majority of CFAEs, despite ablating a much smaller
area than the overall CFAE area.
124
,
582
One clinical study randomized a total of 242 patients with PAF to conventional PVI,
PVI plus GP ablation, and GP ablation alone.
122
Freedom from ATAs (followed for at least 2 years) was achieved in a similar number
of patients in the conventional PVI and GP ablation alone groups (56% and 48%, respectively),
and in a significantly greater number of patients in the PVI plus GP ablation group
(74%; P = .004). In another randomized study including 264 patients with persistent
or long-standing persistent AF, GP ablation as an adjunct to PVI resulted in higher
rates of sinus rhythm maintenance at 3 years (49%) compared with PVI plus LA linear
lesions (34%).
585
,
586
In addition, LA tachycardias were less common with PVI plus GP ablation than with
PVI plus linear lesions. GP ablation alone was also tested in patients with drug-refractory
long-standing persistent AF, resulting in a lower success rate (38% sinus rhythm maintenance
at 2 years).
583
,
584
A recent, prospective, randomized, surgical AF ablation study reported no improvement
of outcomes by ablation of the autonomic ganglia.
123
Again, anchoring the focal ablation of a GP to other nonconducting tissue produced
by PVI or anatomic structures remains critical to prevent subsequent ATs.
A survey of the writing group showed that 7% of the writing group members routinely
employ ablation of autonomic ganglia during initial or repeat ablation procedures
in patients with PAF, and 7% do so during initial or repeat ablation of persistent
and long-standing persistent AF. Based on this information and a review of the literature,
the writing group recognizes that usefulness of ablation of autonomic ganglia as an
initial or repeat ablation strategy for paroxysmal, persistent, and long-standing
persistent AF is not well established (Class IIb, LOE B-NR, Table 3
).
Dominant Frequency Mapping
An emergent property of the complex spatiotemporal dynamics is that during AF, the
local cycle length (atrial fibrillation cycle length [AFCL]) varies depending on electrode
location, with the shortest AFCLs usually localized in the LA.
587
,
588
The combined use of phase mapping
589
and DF mapping demonstrated that the highest DF corresponded with the location of
rotational activity that was driving the arrhythmia.
590
,
591
A subsequent study in patients with paroxysmal or persistent AF showed that ablation
of PVs harboring high DF sites resulted in an increase in the AFCL (≥5 ms) within
the CS in 89% of cases.
98
Arrhythmia termination occurred during ablation in 15 of 17 patients (88%) with PAF,
but in none with permanent AF. In 87% of patients with PAF, ablation at a high DF
site terminated the arrhythmia. Subsequent studies supported the notion that the high
DF (DFmax) sites play a role in the maintenance of AF in a significant number of patients.
592
,
593
Based on these mechanistic studies, a small trial of 50 patients with paroxysmal and
persistent AF was performed, combining PVI with ablation of DFmax sites. At a mean
of 9.3 ± 5.4 months, freedom from AF after one or more ablation procedures was achieved
in 88% and 56% of paroxysmal and persistent AF patients, respectively.
593
A more recent prospective randomized clinical trial of 232 patients with paroxysmal
and persistent AF reported no improvement in ablation outcomes with a DF-based approach
compared with PVI alone.
594
None of the writing group members incorporate DF mapping as a routine AF ablation
strategy in initial or repeat ablation of PAF. One writing group member (2%) incorporates
a DF-based approach during initial and repeat ablation of persistent and long-standing
persistent AF. Based on this information and a review of the literature, the writing
group recognizes that a DF-based ablation strategy is of unknown usefulness for AF
ablation (Class IIb, LOE C-LD, Table 3
).
Renal Denervation
Arterial hypertension (AH) is the most frequent comorbidity in patients with AF, and
this condition is also an important risk factor for the triggering and maintenance
of AF. The potential antiarrhythmic role of renal denervation was demonstrated in
animal studies suggesting a beneficial effect on AF inducibility, maintenance, and
progression.
307
,
595
,
596
,
597
The positive impact of renal denervation on AF recurrence was demonstrated in a first-in
human study, including 27 patients with paroxysmal or persistent AF and refractory
hypertension. At 12-month follow up, the group of patients who underwent PVI plus
renal denervation had a significantly higher success rate in terms of freedom from
AF compared with PVI alone (69% vs 29%, respectively). Also, the reduction in BP was
much more significant in the PVI-plus-renal-denervation group.
331
Recently, data were reported from a combined analysis of two randomized studies with
a large and diverse group of 80 patients with AF and hypertension. For the entire
cohort, renal artery denervation significantly reduced the rate of AF recurrences;
however, this result was more pronounced in patients with persistent AF and refractory
hypertension.
331
A case report using renal denervation instead of PVI in a patient with drug-refractory
persistent AF was recently published, with no AF recurrence at 6-month follow-up.
Moreover, the renal denervation resulted in a reduction of LA size.
598
The mechanism by which renal denervation, when combined with PVI, can impact outcomes
of AF ablation has not been well defined. One potential mechanism is through improved
control of hypertension. An alternate mechanism is through a decrease of central sympathetic
activity by renal denervation.
599
The current body of evidence supporting a role of renal denervation in improving outcomes
of AF ablation is extremely limited. This is an area in need of further investigation.
At the present time, we do not advise renal denervation as a technique to improve
outcomes of AF ablation outside of a clinical trial. This sentiment reflects not only
the limited body of literature supporting this approach, but also the recent large
prospective randomized SIMPLICITY HTN-3 trial that showed that renal artery denervation
was safe, but was not effective in lowering hypertension.
600
Epicardial Ablation of AF
More data concerning thoracoscopic epicardial ablation and combined epicardial-endocardial
ablation procedures have been published since the last AF ablation consensus statement.
In addition to a potentially more durable lesion set, other advantages of an epicardial
approach include access to epicardial structures such as the ligament of Marshall
and GP, management of the LAA, and avoidance of damaging collateral structures, such
as the PN and esophagus.
To date, three randomized prospective trials have compared a video-assisted thoracoscopic
surgical (VATS) approach to percutaneous endocardial catheter ablation for the treatment
of patients with paroxysmal and non-PAF, most of whom had failed an initial catheter
ablation.
585
,
586
,
601
,
602
A meta-analysis of these and other observational studies demonstrated a significant
improvement of arrhythmia-free survival for the VATS procedure (78.4 vs 53%; RR 1.54;
95% CI 1.50–2.14; I
2 = 0%; P <.0001), with a clearer benefit for patients with persistent AF.
603
Complications were three times more frequent in the VATS group, mostly due to pneumothorax
and pleural effusion. VATS procedures can also provide a reasonable outcome for patients
with large atria and long-standing persistent AF.
604
,
605
Many observational studies have reported promising results for so-called hybrid ablation
procedures, which combine elements of VATS and catheter ablation procedures; however,
no randomized controlled trials (RCTs) have been performed to demonstrate effectiveness
and safety relative to either procedure alone.
606
,
607
,
608
,
609
,
610
,
611
,
612
,
613
,
614
,
615
,
616
Before these approaches are applied more widely, a streamlining of the workflow of
the dual procedure approach will be required.
Nonablative Strategies to Improve Outcomes of AF Ablation
AAD Therapy
There is evidence that reverse remodeling occurs after cardioversion of AF. The evidence
in support of this conclusion is based on changes in atrial APD, ERP, CV, and P wave
duration when measured 1–4 weeks after achieving sinus rhythm.
617
,
618
,
619
,
620
The changes in P wave duration occur more slowly and do not predict long-term maintenance
of sinus rhythm.
619
An important question is whether AAD therapy can be used to prevent or initiate reverse
remodeling even prior to ablation, thereby improving the success rate for ablation
procedures. AAD therapy would be beneficial if it prevented electrical and structural
remodeling by reducing the burden of AF, but it might also affect the therapeutic
endpoints of conduction into or out of the PVs and the automaticity of PV or non-PV
triggers of AF. The effect of drugs on mapping putative rotational activity or repetitive
wavelets in humans with AF is unknown.
Four trials have evaluated the effect of preprocedural amiodarone or dofetilide therapy
on outcomes of ablation. One study reported that the recurrence rate of AF following
ablation was lower when treatment with dofetilide prior to ablation reduced the burden
of AF, and was associated with a decrease in P wave duration.
617
,
618
Another single-center nonrandomized study found that amiodarone prolonged the cycle
length of AF and reduced the time spent on CFAE ablation, but it did not have any
effect on long-term outcomes.
619
A second single-center study treated patients with Class I or III drugs for long-standing
persistent AF and compared the outcomes of ablation in those who were successfully
converted to sinus rhythm months prior to ablation as opposed to those who were not.
They observed decreases in LA dimensions (LADs) in the group that achieved preprocedural
sinus rhythm. Long-term freedom from recurrent atrial arrhythmias was higher in the
group that achieved sinus rhythm prior to ablation.
620
The multicenter randomized Effect of Amiodarone on the Procedure Outcome in Long-standing
persistent AF Undergoing PV Antral Isolation (SPECULATE) trial studied the effect
of preprocedural interventions in patients with long-standing persistent AF. Termination
of AF was more common in the patients treated with amiodarone, and fewer non-PV triggers
were identified. At 6 months, both groups had similar recurrence rates; however, at
12 months, arrhythmia-free survival was higher in the patients who were not treated
with amiodarone. A significant limitation of the SPECULATE trial is that many patients
who were assigned treatment with amiodarone remained in AF; thus, there was no opportunity
for remodeling to occur.
621
From a practical standpoint, patients often require AAD therapy prior to ablation
to reduce the burden of symptomatic AF. Whether this delays the progression of remodeling
or reverses it is not well established, although there is evidence from these studies
that conversion to sinus rhythm affects the atrial electrophysiological properties.
Studies that showed improved outcomes in patients who regained sinus rhythm might
be interpreted to show that remodeling occurs and is beneficial, but the alternative
interpretation could be that patients who regain sinus rhythm have less advanced disease
and are better candidates for ablation. The data also suggest that amiodarone affects
the cycle length of AF, has increased conversion rates to sinus during ablation, and
might mask triggers of AF, which could adversely affect the success of the procedure.
Based on this information, the published literature, and the experience of this writing
group, the writing group recognizes that the usefulness of discontinuation of AAD
therapy prior to AF ablation in an effort to improve long-term outcomes is unclear
(Class IIb, LOE C-LD, Table 3
). The writing group also recognizes that the usefulness of initiation or discontinuation
of AAD therapy during the postablation healing phase in an effort to improve long-term
outcomes is unclear (Class IIb, LOE C-LD, Table 3
).
Risk Factor Modification
In Section 3 of this document, we have summarized the emerging data supporting risk
factor modification as an approach to improve outcomes of AF ablation. Based on this
information, the published literature, and the experience of this writing group, for
patients with AF, including those who are being evaluated to undergo an AF ablation
procedure, it is felt that that weight loss can be useful as part of a comprehensive
risk factor management strategy (Class IIa, LOE B-R, Table 3
). The writing group also recommends that it is reasonable to screen for signs and
symptoms of sleep apnea when evaluating a patient for an AF ablation procedure, and
recommends a sleep evaluation if sleep apnea is suspected (Class IIa, LOE B-R). And
finally, the writing group recommends that the treatment of sleep apnea can be useful
for patients with AF, including those who are being evaluated to undergo an AF ablation
procedure (Class IIa, LOE B-R, Table 3
).
Mechanisms of Nonisthmus-Dependent Atrial Flutter and Approaches to Mapping and Ablation
The occurrence of AFL after AF ablation is common enough that all operators performing
AF ablation should be skilled in mapping and ablating both typical and atypical AFL.
The incidence of AFL after AF ablation depends on the type of ablation performed during
the initial procedure, varying from 2.6% in centers performing PVI alone to 31% in
centers performing linear ablation.
622
,
623
,
624
,
625
AFL is less common after PVI with CB compared with RF-based PVI.
489
The mechanism of AFL is reentry. Reentrant arrhythmias include focal reentry occurring
through gaps in the prior PVI line (PV tachycardia) or macroreentry around anatomic
obstacles created during ablation (mitral annular flutter, LA roof-dependent flutter,
or septal flutters around areas of scar).
447
,
506
,
626
,
627
Typical cavotricuspid isthmus-dependent flutter can also occur (Figure 5
).
Determining the location of the reentry circuit starts with examination of the 12-lead
ECG. A clear isoelectric line in all 12 leads suggests a focal AT involving a small
reentrant circuit (e.g., microreentry), whereas continuous activation suggests a macroreentrant
flutter involving a larger circuit.
628
Typical cavotricuspid isthmus-dependent flutter frequently has an atypical appearance
on the 12-lead ECG after prior LA ablation, and this should not be excluded based
on an atypical ECG appearance alone.
629
Although extensive LA ablation can limit interpretation of the 12-lead ECG, certain
rules apply. Tachycardias arising near the PV ostia will typically have an inferior
axis and positive F waves across the precordial leads. An “m”-shaped F-wave in lead
V1 suggests a left PV exit. Right PV tachycardias are characterized by the ECG amplitude
in lead II greater than that in lead III and a positive F wave in lead I. Mitral annular
flutter has a similar appearance to left PV tachycardias, although an initial negative
component in the precordial leads or amplitude in lead V2 less than that in V1 and
V3 might be suggestive.
630
These rules, however, could be less applicable in patients with extensive scarring,
including that from prior ablations.
Initial localization of an atypical flutter can frequently be facilitated by simply
observing the activation sequence on a CS catheter. Proximal to distal activation
suggests cavotricuspid isthmus-dependent flutter, right PV tachycardia, or counterclockwise
mitral annular flutter, whereas distal to proximal activation suggests a left PV tachycardia
or clockwise mitral flutter. An “on time” or fused CS pattern could be suggestive
of a roof-dependent flutter.
631
When acquiring an electroanatomical activation map, each acquired point should be
carefully annotated by the operator, taking care to tag and not include widely split
potentials that might indicate a line of block. Multipoint mapping can decrease the
time needed for acquiring a map, but automated electrogram annotation might lead to
errors and confusing maps. A novel very automated high-density automated mapping system
has recently become available.
627
,
632
Early results using this system to determine activation sequences and perform ablation
based solely on activation rather than entrainment mapping have been encouraging.
627
However, the true clinical value of this type of system is unknown and will require
a prospective randomized comparison with conventional electroanatomical and entrainment
mapping. When performing ablation of AFL with a conventional 3D mapping system, scar
should be labeled as such to identify anatomic obstacles. Focal microreentrant tachycardias
can also occur and are typically indicated by centrifugal conduction away from a focal
area of onset and by long fractionated potentials with duration >50% of the tachycardia
cycle-length.
628
The main strength of activation mapping is that it is unlikely that the tachycardia
will terminate. The disadvantage is that these activation maps can be extremely difficult
to interpret and might not translate to identifying successful ablation sites. When
performing ablation of atypical AFL with a conventional 3D mapping system, especially
when a stable reentrant circuit is present that allows entrainment, most operators
find that entrainment mapping from multiple sites is a better and more accurate approach
to localize the reentrant circuit and target ablation lesions. It is for this reason
that entrainment mapping is the gold standard for mapping reentrant tachycardias and
is the preferred mapping strategy employed by most writing group members at the present
time. For atypical flutter, because fusion of the F wave can be difficult to interpret,
the primary goal is to identify regions with a postpacing interval within 20 ms of
the tachycardia cycle length. Care should be taken to pace at or near threshold, given
high-output pacing can capture adjacent tissue that leads to an erroneous postpacing
interval. High-output pacing can also lead to electrode polarization that obscures
the return electrogram. Once the reentry circuit is delineated, an ablation strategy
can be designed to connect anatomic obstacles and interrupt the tachycardia. Despite
this current preference, new high-density automated mapping systems have been developed,
as noted above, which allow development of successful ablation strategies based on
high-density activation mapping alone, without the risk of entrainment pacing resulting
in termination of the flutter under study or its degeneration into a different flutter
or fibrillation. Prospective randomized clinical trials will need to be performed
to determine the true clinical value of these new automated high-density mapping systems.
627
,
632
For PV tachycardias, 2 gaps in the PVI line are typically present and reisolation
of the PVs suffices to eliminate the tachycardia.
447
For macroreentrant tachycardias, ablation that connects anatomic obstacles is required.
The classic post-PVI macroreentrant tachycardia is mitral annular flutter; ablation
between the mitral annulus and left lower PV (mitral isthmus) is typically performed
(Figure 5
), although an anterior line between the mitral annulus and the LSPV, the RSPV, or
the roof line can also be performed. For mitral isthmus ablation, epicardial ablation
within the CS is required approximately 80% of the time. The endpoint of linear ablation
should be proof of bidirectional block using pacing maneuvers rather than simply tachycardia
termination. Interruption of the clinical tachycardia should be performed first, because
burst pacing might induce multiple tachycardias of unclear significance. After termination
of the clinical tachycardia, reisolation of any reconnected PVs should always be performed.
Anesthesia During AF Ablation
The type of anesthesia used for AF ablation depends in part on the availability of
anesthesia support for ablation procedures. Given the need to minimize patient movement
to improve catheter and mapping system stability, deep sedation or general anesthesia
is generally preferred. One prospective randomized clinical trial randomized patients
with general anesthesia or conscious sedation. This study reported that use of general
anesthesia increased the single procedure success rate, lowered the prevalence of
PV reconnection among those who needed a redo procedure, and shortened fluoroscopy
time and procedure time.
633
Another nonrandomized clinical trial reported improved efficacy of AF ablation with
use of jet ventilation.
634
A survey of the writing group members performing AF ablations found that 73% use general
anesthesia, 13% use deep sedation with an anesthesiologist, and 14% use moderate conscious
sedation with an electrophysiology nurse. Jet ventilation was used by only 8%. The
major reason cited for not using general anesthesia was lack of anesthesiologist availability.
Some proponents of not employing general anesthesia believe that the risk of an atrial
esophageal fistula (AEF) could be higher in patients in whom general anesthesia is
employed.
635
,
636
,
637
,
638
,
639
Recurrent AF with or without PV Reconnection
Some degree of PV reconnection is observed in more than 80% of patients who are returned
to the electrophysiology laboratory for a clinically indicated electrophysiology procedure.
PV reconnection is also observed in patients doing well post-PVI. The Gap-AF trial
reported PV reconnection at 3 months in 70% of patients randomized to complete PVI
and in 89% of patients in whom a PV “gap” was left intentionally. AF recurred during
the first 3 months postablation in 62% of the patients with complete PVI vs 79% of
the patients in whom a gap was left intentionally.
456
When reconnection of the PVs is observed, it is recommended that the PVs be reisolated.
This can be accomplished by a limited approach, which involves only targeting those
PVs that demonstrate reconnection, and only targeting the segment of the PV circumference
in which the PV reconnection is detected. Among the writing group members, 73% employ
this strategy. An alternate approach is to be more liberal with ablation, with creation
of a new circumferential lesion set around each of the PVs, which demonstrates reconnection.
This approach is employed by 20% of the writing group members. An even more liberal
approach is to repeat the entire WACA lesion set that was delivered the first time;
this approach is employed by the remaining 7% of the writing group members. In the
small proportion of patients in whom no PV reconnection is observed, there is agreement
that a number of non-PV-based strategies should be considered, including searching
for non-PV triggers, delivery of one or more linear lesions, isolation of the CS,
isolation of the LAA, ablation of autonomic ganglia, CFAE ablation, and rotational
activity ablation. A recent report suggested that the best outcomes following ablation
of non-PV triggers are achieved in patients with a well-defined provocable target.
640
Each of these strategies has been described in detail in the rest of this document.
Endpoints for Ablation of Paroxysmal, Persistent, and Long-Standing Persistent AF
PVI is the cornerstone of AF ablation. Among the writing group members, 95% employ
this endpoint during all AF ablation procedures. PVI is demonstrated by entrance block
alone by 35%, and both entrance and exit block by 65%.
Beyond PVI, other endpoints, particularly during ablation for persistent AF, are unclear.
It has been suggested that regardless of other non-PV targets ablated, the endpoint
for ablation of persistent AF should be the termination of AF either to a regular
ATA, or to a sinus rhythm. Although termination of AF has been shown by some to be
predictive of longer-term outcome, other studies have not confirmed this finding.
399
,
400
,
401
,
515
,
621
,
641
,
642
It is unclear whether acute, intraprocedural termination is a true indication of procedural
success, or simply might indicate patients with less persistent AF who are destined
to do better regardless of the approach used. A substudy of the STAR AF II trial has
suggested this latter point.
643
Slowing of AF cycle length as measured from the CS or the LA or RA appendage has also
been used as a surrogate for acute procedural success. However, AF cycle length prolongation
can be difficult to measure reliably in AF, and prolongation is often used as a harbinger
of acute termination. Again, longer baseline AF cycle length can be an indication
of AF that is more likely to terminate or respond to ablation rather than indicating
a procedural endpoint in and of itself.
643
Thus, AF termination of cycle length prolongation might not be useful as a sole procedural
endpoint.
Other non-PV targets have been suggested for ablation, particularly for persistent
AF. CFAEs have been put forward as an important target, although many recent randomized
studies and meta-analyses have not concluded that there is any benefit.
644
Ablation of non-PV focal triggers identified via isoproterenol challenge, ablation
of atrial scarred regions, or ablation of localized rotational activations (so-called
rotational activity) have also been reported to have benefit over PVI alone.
140
,
534
,
538
,
645
It appears that regardless of which target is chosen, complete local elimination of
the target should be the goal, so as not to leave behind partially ablated tissue
that could serve as a site for future AT recurrence. The best method of ablating a
localized rotational activation is as yet unclear. Early descriptions suggested ablating
the center of activation with several lesions and then remapping to confirm that the
rotation is terminated.
563
Others have suggested that central ablation should be combined with creation of a
short line to an anatomical or ablated boundary that crosses and interrupts the rotational
pathway. The choice at this point is unclear. Similarly, for scar-based ablation,
the best methods of defining scar are not yet confirmed (late gadolinium enhancement
vs voltage mapping), and even for voltage mapping, the appropriate voltage cutoffs
have not yet been validated. Furthermore, it is unclear whether such scar regions
should be surrounded by lesions to isolate them from the rest of the atrium; whether
ablation within the scar to eliminate all residual electrograms (so-called homogenization)
should be employed; or whether these regions should also be tied to anatomical boundaries
by short linear ablations. It follows from earlier comments that these scar ablations
should be anchored to other nonconducting anatomical structures. There will need to
be much further research into the best ablative endpoint for these ancillary targets.
Empiric linear ablation likely does not add much to ablation of persistent AF.
646
,
647
However, if linear ablation along the roof or mitral annulus is added to target roof
or mitral-dependent flutters, then bidirectional block is a prerequisite endpoint.
Block across a line must be assessed in sinus rhythm and with differential pacing
maneuvers, and these are described in detail in the following section.
Section 6: Technology and Tools
In this section, we provide an update on many of the technologies and tools that are
employed for AF ablation procedures. It is important to recognize that this is not
a comprehensive listing and that new technologies, tools, and approaches are being
developed. It is also important to recognize that RF energy is the dominant energy
source available for ablation of typical and atypical AFL. Although cryoablation is
a commonly employed tool for AF ablation, it is not well suited for ablation of typical
or atypical AFL. Other energy sources and tools are available in some parts of the
world and/or are in various stages of development and/or clinical investigation. Shown
in Figure 9
are schematic drawings of AF ablation using point-by-point RF energy (Figure 9A) and
AF ablation using the CB system (Figure 9B).
Figure 9
Schematic drawing showing catheter ablation of atrial fibrillation using either RF
energy or cryoballoon AF ablation. (A) Shows a typical wide area lesion set created
using RF energy. Ablation lesions are delivered in a figure of eight pattern around
the left and right PV veins. Also shown is a linear cavotricuspid isthmus lesion created
for ablation of typical atrial flutter in a patient with a prior history of typical
atrial flutter or inducible isthmus-dependent typical atrial flutter at the time of
ablation. A multielectrode circular mapping catheter is positioned in the left inferior
PV. (B) Shows an ablation procedure using the cryoballoon system. Ablation lesions
have been created surrounding the right PVs, and the cryoballoon ablation catheter
is positioned in the left superior PV. A through the lumen multielectrode circular
mapping catheter is positioned in the left superior PV. Illustration: Tim Phelps ©
2017 Johns Hopkins University, AAM.
Radiofrequency Energy
Biophysics and Irrigation
The presumed basis of successful AF ablation is production of myocardial lesions that
block the propagation of rapidly firing PV triggers or modification of the arrhythmogenic
substrate responsible for reentry. Successful ablation depends on achieving lesions
that are reliably transmural.
648
,
649
The conventional approach employed by cardiac electrophysiologists to reach the goal
of AF ablation is RF energy delivery by way of a transvenous electrode catheter. RF
energy achieves myocardial ablation by causing resistive heating of the tissue with
subsequent heat conduction to deeper tissue layers. Most RF energy is delivered in
a unipolar fashion between the tip of the ablation catheter and a large surface-area
dispersive electrode applied to the patient's thorax or thigh. The position of the
dispersive electrode does not greatly affect lesion size or geometry. If a high-power
system is used, two dispersive electrodes should be employed to avoid skin burns.
With bipolar RF delivery, there is no dispersive electrode, and both electrodes are
active. One commercial system delivers RF energy simultaneously through multiple electrodes
in a unipolar, blended, or bipolar fashion, using either continuous unipolar delivery
with an offset of the phase of the RF wave between electrodes (phased RF delivery),
or field sequential unipolar and bipolar delivery between contiguous electrodes in
a prespecified ratio.
650
Although bipolar ablation can be effective in heating tissue between contiguous electrodes,
the lesions are not as deep as those using unipolar ablation.
Factors that will determine the size and depth of RF energy ablative lesions are power,
impedance, temperature, duration, and CF.
651
,
652
,
653
High-power delivery and good electrode–tissue contact promote the formation of larger
lesions and improve procedure efficacy. However, if the temperature of the electrode–tissue
interface exceeds 100 °C, then blood will boil and the blood proteins will form char
and coagulum. As coagulum adheres to the electrode, less surface area is available
for electrical conduction and the current density rises, resulting in more tissue
and blood heating in a positive feedback spiral leading to a rapid rise in electrical
impedance. Higher power delivery can be achieved with saline-irrigated tip catheters
that cool the endocardial surface and prevent char and impedance rise. Increased convective
cooling can also be achieved passively by using electrode material with high thermal
conductivity, such as gold.
653
The higher power delivery achieved with tip irrigation results in greater depth of
resistive heating, with significant increase in lesion size. If intramural temperatures
exceed 100 °C, steam expansion can suddenly vent through the endocardium or epicardium
(pop lesion) and potentially cause a perforation.
654
Because of more reliable creation of transmural lesions, and reduced risk of formation
of endocardial thrombus and char, AF ablation with RF catheters is most commonly performed
with tip irrigation. Optimal catheter–tissue contact is achieved by a combination
of steerable catheter selection, guide sheath manipulation, operator skill, and monitoring
catheter–tissue CF.
655
Significant complications can occur during AF ablation if high RF power is administered
in an uncontrolled fashion. The increased risk of AF ablation compared with ablation
of other arrhythmias can be attributable to the great surface area of tissue ablated,
the large cumulative energy delivery, the risk of systemic thromboembolism, and the
close location of structures susceptible to collateral injury, such as the PN, PVs,
and esophagus. Thrombus and char can be minimized by limiting power and/or target
temperature by monitoring the production of steam microbubbles at the catheter tip
with ICE, and by cooling the electrode–tissue interface with saline-irrigated tips.
656
,
657
,
658
,
659
Intramural steam pops can be reduced by limiting both power and the electrode–tissue
contact pressure. Duration of energy delivery affects the tissue temperature profile.
The half-time of lesion growth is approximately 5–15 seconds, depending on the power
used; thus, maximum lesion size is usually achieved within 1 minute. A long ablation
duration will allow the heat generated in the region of resistive heating to conduct
to deeper tissue layers, with maximum lesion size being achieved when the system has
reached steady state. A short duration will yield maximal heating close to the source,
with a steep drop in temperature in deeper layers, and might be preferred when ablating
thinner regions such as the posterior LA when heating of contiguous structures (esophagus)
needs to be avoided.
Immediately postablation, lesions show typical coagulation necrosis, hemorrhage, and
edema. Subacute lesions examined 2–7 days later show infiltration of inflammatory
cells, and early chronic lesions show replacement of myocardium with granulation tissue
at 4 weeks.
660
Myocardium exposed to temperatures of 50 °C or higher for more than several seconds
will show irreversible coagulation necrosis and evolve into nonconducting myocardial
scar.
652
The mechanism of acute injury to myocardium is attributed to thermal injury to the
sarcolemmal membrane with resultant depolarization and intracellular calcium overload.
661
,
662
In the border zone region of lesion formation, myocytes can become inactive or dormant,
but then subsequently reestablish a normal resting membrane potential and normal electrical
conduction. These dormant zones can be reactivated by the hyperpolarizing effects
of adenosine.
465
Conversely, the inflammatory response to the acute injury and damage to the microvasculature
can lead to lesion progression.
Various techniques have been proposed to minimize collateral injury. Temperature sensors
at the electrode catheter tip can provide gross feedback of surface temperature, but
because of passive convective cooling from circulating blood flow or active cooling
in a cooled tip catheter, temperatures measured at the catheter tip significantly
underestimate peak tissue temperatures. Limiting power and shortening duration of
energy delivery will limit collateral injury, but at the expense of reliably creating
transmural lesions. ICE has been used to monitor lesion formation. If the tissue shows
evidence of increased echogenicity, or if small gas bubbles are observed, then power
should be reduced or terminated.
663
,
664
Contact Force-Sensing Catheters and Systems
Contact Force
During RF catheter ablation, electrode–tissue CF is one of the primary determinants
of lesion size.
636
,
665
,
666
,
667
No effective lesion is formed without adequate CF, and excessive CF is associated
with excessive deep tissue heating and an increased risk of deep steam pop (and perforation)
and injury outside the heart, such as esophageal, pulmonary, and PN injury.
Ablation catheters using two different technologies have been developed recently to
measure real-time catheter–tissue CF during mapping and RF ablation. One catheter
uses three optical fibers to measure the microdeformation of a deformable body in
the catheter tip (TactiCath, St. Jude Medical, Inc.), which correlates with tip force.
668
,
669
,
670
The second catheter uses a small spring between the ablation tip electrode and the
catheter shaft, with a tiny magnetic transmitter in the tip and magnetic sensors proximal
to the tip to measure microdeflection of the spring (ThermoCool SmartTouch, Biosense
Webster, Inc.), corresponding to tip force.
671
,
672
,
673
Both systems have high resolution (<1 gram) in bench testing and accurately display
the direction of force. These two catheters, equipped with saline-irrigated tip electrodes,
underwent extensive preclinical studies and were introduced for clinical use, beginning
in 2010. The surrogate measures of contact used previously, including the fluoroscopic
appearance of catheter motion, intracardiac electrogram amplitude, and impedance,
have been found to be very poor predictors of CF.
668
,
670
,
671
,
672
,
674
Preclinical experimental studies have shown that (1) at constant RF power and application
time, RF lesion size significantly increases with increasing CF; (2) the incidence
of steam pop and thrombus also increase with increasing CF; and (3) modulating RF
power based on CF (e.g., high RF power at low CF and lower RF power at high CF) results
in a similar and predictable RF lesion size.
668
,
670
,
672
AF ablation studies using CFS catheters have provided important insight into the spatial
distribution of CF during PVI. When the operator was blinded to CF measurements during
catheter manipulation and ablation, sites of high CF were identified to be the RS
aspect of the anterior LA wall, the posterior antrum of the RSPV, the inferior posterior
LA wall, the posterior antrum of the LSPV, and the LA roof.
671
Sites of low CF have been identified to be anterior to the left PVs and right carina.
675
,
676
,
677
These low CF sites have correlated with sites of PV reconnection.
677
CFS catheters provide operator feedback to allow for more homogeneous force delivery
and reduce impedance rise, cardiac perforation, steam pops, and thrombus formation
while at the same time improving effective lesion formation.
453
,
668
,
671
,
676
,
678
,
679
,
680
Several clinical studies have compared circumferential antral PVI using the ThermoCool
SmartTouch CFS catheter with ablation using a non-CFS catheter. The SmartTouch catheter
has been shown to reduce gaps, prevalence of adenosine-induced dormant conduction,
fluoroscopy time, and AF recurrence.
468
,
673
,
679
,
681
,
682
,
683
One of the largest studies was a retrospective, case-control study of 600 patients
followed for mean duration of 11.4 ± 4.7 months. The use of the SmartTouch CFS catheter
predicted freedom from ATA in patients with PAF (hazard ratio [HR] 2.24; 95% CI 1.29–3.90;
P = .004), but not in those with non-PAF (HR 0.73; 95% CI 0.41–1.30; P = .289). These
findings could be due to differences in the AF substrate in which recurrence in patients
with PAF is attributed to gaps in lesion sets rather than advanced AF substrate, and
CFS improves lesion formation. There was no difference in complication rate between
the CFS and non-CFS catheters. Another evaluation of the SmartTouch catheter was the
ThermoCool SmartTouch Catheter for the Treatment of Symptomatic Paroxysmal Atrial
Fibrillation (SMART-AF) trial, which was a multicenter, prospective, randomized clinical
trial performed for FDA approval of this catheter.
673
The outcomes were compared with the earlier clinical trial for ThermoCool approval,
684
in which 170 patients were enrolled. The 12-month freedom from AF/AT/AFL was 72.5%
at 1-year follow-up, compared with 66% efficacy for the ThermoCool noncontact-force
catheter.
684
The average CF per procedure was 18 grams. Four patients experienced cardiac tamponade.
A post hoc analysis revealed that when the CF employed was between the investigator-selected
working ranges >80% of the time, outcomes were 4.25 times more likely to be successful.
673
The most recent study to evaluate the efficacy of CF catheters randomized 117 patients
with PAF to AF ablation with the Smart-Touch Catheter. Patients were randomized to
having the CF information available or not available to the operator. The availability
of CF information resulted in a lower incidence of acute reconnection (22% vs 32%);
however, there was no difference in long-term efficacy, fluoroscopy times, or complications.
685
The efficacy of the TactiCath CFS catheter for AF ablation has been evaluated in a
number of clinical trials, one of which resulted in FDA approval of this device. The
TOCCATA study enrolled 35 patients with PAF and demonstrated that CF predicted freedom
from AF postablation.
676
All the patients in whom the average ablation CF was less than 10 grams (n = 5) had
recurrent AF by 1-year follow-up; whereas, 80% of the patients (n = 8 of 10) were
free from AF at 1 year when the average CF was greater than 20 grams. The EFFICAS
I study enrolled 46 patients with PAF and correlated CF with incidence of gaps in
PVI lines 3 months after the initial PVI procedure.
453
The number of ablation lesions, minimum CF, and minimum force time integral <400 grams
were highly predictive of gap presence and PV reconnection 3 months postablation.
A small study enrolling 6 patients used late gadolinium-enhanced (LGE) cardiac MRI
to assess scar formation 3 months postablation following PVI. Increasing force-time
integral (FTI) correlated with increased LGE signal intensity.
680
This was particularly so when the FTI was >1200 grams. Segments with FTI <1200 grams
showed less scar formation 3 months postablation. In addition to being able to provide
feedback to improve durability of AF ablation lesions sets, the TactiCath catheter
has been shown to decrease fluoroscopy time and reduce the number of RF applications
for PVI compared with a non-CFS catheter.
686
The most recent and most important clinical trial of the TactiCath catheter was the
TOCCASTAR clinical trial performed for FDA approval of this device.
655
In this prospective, randomized clinical trial, 300 patients with PAF were randomized
to ablation with the TactiCath catheter or to the non-CFS ThermoCool ablation catheter.
No difference in efficacy was observed, with success rates of 67.8% and 69.4% in the
CF and control arms, respectively. When the CF arm was stratified into optimal CF
and nonoptimal CF groups, effectiveness was achieved in 75.9% vs 58.1%, respectively.
There was no difference in the rate of complications in the two groups. Cardiac tamponade
occurred in one patient in each group.
Despite the absence of prospective clinical trials that have proven that CF monitoring
improves not only the efficacy but the safety of AF ablation, operators worldwide
have quickly adopted these new advanced ablation tools. Many of these operators who
employ CFS during AF ablation believe that CF monitoring provides important biomechanical
feedback to improve effective lesion formation, durability of PVI, and clinical outcomes.
Future systems combining CF, RF power, and application time (such as the Force-Power-Time
Index) could provide real-time assessment of lesion formation to increase the efficacy
and safety of RF ablation. It should be remembered that CF is only one of the surrogate
markers of ablative energy delivery. Power, impedance, temperature, and other factors
remain in place and interact with the CF measurements. Several systems now employ
a monitoring system that uses an integral of two or more of these factors. It is also
possible that when higher CFs are realized, the power of RF delivery might need to
be reduced. Achieving an adequate CF does not eliminate the user's responsibility
to maintain awareness of other factors, such as power or other matrix components of
ablation.
A survey of the writing group shows that among those who perform AF ablation with
RF energy, 70% routinely use CFS. Two-thirds of the writing group members allow at
least 20 seconds at a given ablation site to elapse before moving the ablation catheter
to a new site. The target minimal CF used by the writing group members is > 5 grams
by 28%, >10 grams by 62%, >15 grams by 8%, and >20 grams by 3%. A CF upper limit of ≤ 30
grams is employed by 48% of the writing group members, less than 40 grams by 36%,
and <50 grams by 15%. As noted in Section 5 and Table 3
, the writing group recommends that when performing AF ablation with a force-sensing
RF catheter, that a starting point minimum targeted CF of 5 to 10 grams is reasonable
(Class IIa, LOE C-LD, Table 3
).
Cryoablation
In recent years, CBA has become the most efficient alternative to RF catheter ablation
(RFCA) for the treatment of AF (Figure 9B).
The CB single shot ablation approach to AF has been designed to shorten and simplify
the ablation procedure for achieving an effective PVI. Preclinical and clinical studies
have shown that CB is effective in achieving PVI, offering a valid alternative to
RF's point-by-point approach to PAF treatment.
494
,
687
,
688
The multicenter, prospective randomized controlled Sustained Treatment of Paroxysmal
Atrial Fibrillation (STOP-AF) trial has reported that PVI with the first-generation
CB achieved 69.9% freedom from AF at 12 months compared with 7.3% with AADs.
462
More recently, the second-generation CB has become available to overcome some of the
limitations of the first CB generation.
689
These improvements include expansion of the cooling zone from the equatorial surface
of the balloon to the entire distal half, leading to a more uniform circumferential
ablation.
473
,
484
,
690
,
691
,
692
Composite circumferential lesion size could be a second factor in this process.
In a prospective, multicenter registry, there was no difference between conventional
RFCA and CB in terms of acute success rate and overall complications; however, fluoroscopy
times were longer in CBA procedures.
693
Many studies (mostly nonrandomized) showed that CBA yields similar or higher success
rates in comparison to RF in patients presenting with drug-resistant PAF, and that
the procedure is somewhat less time-consuming and might be associated with a safer
profile.
482
,
694
,
695
,
696
More recently, the multicenter randomized clinical trial FIRE AND ICE, comparing conventional
PVI with RFCA (force-sensing catheters were used in approximately 25% of the procedures)
to CBA (CB-2 in approximately 75% of the procedures) in drug-refractory PAF has shown
that CBA is noninferior to RFCA with respect to efficacy and overall safety.
489
,
697
More specifically, the primary efficacy endpoint (any atrial arrhythmia recurrence,
use of AADs, or repeat ablation at 1 year) was not different between the CBA and RFCA
groups; neither was the primary safety endpoint. PN injury at the time of discharge
was the most frequent adverse event reported in the CBA group (2.7%), but lower than
what was observed in the STOP-AF trial (13.5%). Permanent PN injury occurred in 0.3%
of patients. A recent analysis of the secondary endpoints of FIRE AND ICE has shown
that CBA had significantly fewer repeat ablations, direct current cardioversions,
all-cause rehospitalizations, and cardiovascular rehospitalization during the follow-up
compared with RFCA, with a similar improvement in QOL.
490
A recent trial reported their pivotal findings on CBA as first-line therapy in a selected
population suffering from PAF; the authors suggest that it might be appropriate to
consider CBA therapy for PVI as first-line therapy in patients with PAF in the absence
of significant structural heart disease.
698
Yet, the decision whether to perform a catheter-based intervention in a symptomatic
patient still takes into account the stage of atrial disease, the presence and severity
of any underlying cardiovascular disease, potential treatment alternatives, and—in
particular—patient preference and operator experience.
7
Cryoballoon AF ablation requires a shorter learning curve than point-by-point RFCA.
The results of the currently ongoing Catheter Cryoablation vs Antiarrhythmic Drug
as First-Line Therapy of Paroxysmal AF (Cryo-FIRST) trial (NCT01803438), expected
in 2017, will help answer the question of whether to propose CBA as a first-line therapy
in highly symptomatic patients with PAF.
Laser and Ultrasound Ablation Systems
A laser balloon ablation system transmits light energy through a balloon filled with
deuterium oxide (D2O, or “heavy water”) to perform PVI.
498
,
508
,
699
,
700
,
701
The unique part of this system is that the lumen of the catheter contains a fiber
optic endoscope that allows PVI under direct visualization. The balloon is compliant,
allowing a variable inflation diameter from 25–32 mm, depending on PV size, and is
delivered via a 16 Fr outer-diameter steerable sheath. Once the balloon is inflated,
the diode laser emits energy in a 30-degree arc of overlapping lesions that can be
rotated around the circumference of the PV and tracked visually using special software.
The power of the laser ablation energy can be titrated from 5.5 to 12 W, lasting for
20–30 seconds for each ablation lesion. Lower power is used when blood is present
in the field of view or when the laser is overlying the posterior LA wall, and higher
power is favored over remaining PV segments in order to achieve persistent PVI.
502
The endoscope has a 115-degree field of view (partially blocked by the lesion generator),
and the balloon catheter is then rotated to complete the isolation. Each PV is typically
individually isolated, as opposed to the individual or pairwise isolation used during
point-by-point RF ablation. A multicenter, prospective pivotal trial of the laser
balloon for treating PAF found that freedom from AF after a single laser balloon ablation
was noninferior, and nearly identical, to the success rate using irrigated RF ablation
(61.1% laser vs 61.7% RF; P = .003 for noninferiority), with a similar safety profile.
503
PN injury was more common using the laser balloon (3.5% vs 0.6%; P =.05), but PV stenosis
was less common (0.0% vs 2.9%; P =.03). In a single-center randomized study, AF recurrence
after ablation was similar using the laser balloon compared with the first-generation
CB (27% vs 37%; P = .18).
501
,
502
The laser balloon has been used commercially in Europe and has received FDA approval
for use in the United States to treat patients with drug refractory recurrent symptomatic
PAF.
A novel automated low-intensity collimated ultrasound ablation system is in development.
702
This system uses low-intensity collimated ultrasound (LICU) to automatically create
a 3D anatomical map of the LA. A graphical interface allows the operator to define
a desired lesion set on the 3D map, then delivers computer-controlled LICU along the
desired ablation path to create a contiguous lesion. The lesions are created without
contacting the atrial wall and are calibrated with respect to detected tissue thickness.
Ultrasonic power is varied along the ablation path to achieve transmurality while
reducing the risk of damage to extracardiac structures. Animal studies show that PVs
are electrically isolated with a single planned set of lesions. Initial phase clinical
trials are being performed at this time, and the results are pending.
Other Balloon Technologies
Balloon-based ultrasound and RF ablation systems have also been developed for AF ablation.
703
,
704
,
705
The first of these balloon ablation systems to be approved for clinical use in Europe
was the focused ultrasound ablation system.
703
,
704
,
705
Although this balloon-based ablation system was demonstrated to be effective, it was
removed from the market because of a high incidence of AEFs, some of which resulted
in patient death.
The hot balloon ablation catheter employs a compliant balloon filled with saline that
is inflated to occlude the PV.
706
A central electrode delivers RF energy to the saline in the balloon, and a unique
mixing system creates turbulent flow, promoting uniform distribution of the heated
saline throughout the balloon. The balloon surface directly heats the PV wall circumferentially.
Tissue heating occurs through direct conductive heating.
707
This technology has been used to successfully treat patients with PAF, with a reported
65% long-term single-procedure success rate without AADs. The main reported complication
with this technology was PN palsy (3.4%) and PV stenosis (1.7%).
708
A recent prospective multicenter clinical trial compared the outcomes of hot balloon
ablation vs AAD therapy for PAF. Freedom from atrial arrhythmias was achieved at 12-month
follow-up in 59% of patients undergoing ablation vs 4.7% with AAD therapy. Serious
adverse events occurred in 10% of hot balloon patients. The incidence of PV stenosis
was 5.2%, and the incidence of PN injury was 3.7%. The clinical availability of this
ablation technology is limited at the present time.
709
Multielectrode Circumferential Ablation Catheters
Currently, two multielectrode circumferential catheter systems are in clinical use:
The PV ablation catheter (PVAC) and the nMarq system. From a historical standpoint,
the first catheter using a circumferential multielectrode approach for sensing and
simultaneous ablation with the same electrodes was the Mesh ablator.
710
However, due to technical limitations of the system and poor clinical outcome, this
system is no longer available. The nMARQ catheter is a combined decapolar irrigated
ablation and mapping RF system.
711
,
712
,
713
,
714
The catheter has a circular design and consists of 10 platinum-coated 3 mm electrodes
with a 4 mm interelectrode spacing. Irrigation is performed via 10 holes in each electrode.
RF ablation can be performed via all 10 electrodes simultaneously, up to a maximum
of 25 W in unipolar and 15 W in bipolar mode. In an initial evaluation phase in smaller
patient cohorts, a high acute success rate of PV disconnection was reported.
715
,
716
,
717
A multicenter prospective registry reported data on approximately 180 consecutive
patients with paroxysmal (140 patients) and persistent (40 patients) AF who underwent
nMARQ AF ablation. Aside from a high acute success rate, acute complications and rate
of AF relapse (e.g., 27% in the PAF group) were comparable to other ablation techniques
after a mean follow-up of 13.9 months.
718
Esophageal injury has been reported in several studies using the nMARQ AF ablation
catheter.
719
,
720
Comparing the intracardiac signals from the nMARQ to a standard “lasso”-like mapping
resulted in both underestimation of PV potentials with the nMARQ postablation (which
were still detectable in the lasso) and overestimation by sensing fragmented electrograms
that could not be verified with a lasso mapping.
721
This appears to be an area with a need for further investigation, because underestimation
of remaining PV potentials can lead to a pseudo-high acute success rate but higher
AF relapses during long-term follow-up. The nMARQ is not currently available for clinical
use in the United States. A prospective clinical trial is underway to demonstrate
the safety and efficacy of this ablation system, needed for FDA approval.
722
The PVAC in its first version used 10 platinum-iridium electrodes in a circular fashion
to deliver duty-cycled bipolar or unipolar phased RF energy via selected or even all
electrodes (temperature-controlled and power-limited: 60 °C/10 W/60 second delivery
time). Following initial, mostly single-center, experiences that demonstrated excellent
clinical efficacy, several studies reported a high incidence of asymptomatic cerebral
emboli (ACE) lesions after PVI with the PVAC compared with irrigated focal RF and
CBA.
650
,
723
,
724
,
725
,
726
,
727
These reports triggered an evaluation of the underlying mechanisms; the Endovascular
Revascularization and Supervised Exercise Therapy in Patients with Peripheral Artery
Disease and Intermittent Claudication trial subsequently demonstrated that through
modifications in the catheter design, including the elimination of overlying pole
1 and 10 ablation, and protocol for use, it was possible to reduce the incidence of
ACE lesions to 1.7%.
722
,
727
,
728
,
729
,
730
These findings were confirmed in the PRECISION GOLD trial.
731
,
732
This ablation system was not approved for clinical use by the FDA due in part to this
initial safety signal and the occurrence of 4 strokes (2.9% of patients randomized
to ablation) following ablation in the pivotal Tailored Treatment of Permanent Atrial
Fibrillation study.
733
,
734
An additional single-arm study to again elucidate the safety of PVAC technology, the
Evaluation of Multielectrode Phased RF Technology in Persistent AF (NCT01693120),
was subsequently launched but has recently been closed due to lack of enrollment.
In summary, there is considerable reason and data to believe that PVAC technology
in its redesigned format has achieved at least a similar safety profile as CB or irrigated
tip catheter ablation. The relative efficacy of this ablation system compared with
the CB system or point-by-point RF ablation will require an adequately powered prospective,
randomized clinical trial.
734
Several prospective and randomized data collections are starting, but results will
not soon be available, including the Efficiency Study Evaluating the Use of the PVAC
Catheter Technology for Performing Ablation in Patients with AF (CAPCOST) (NCT01562912)
and PVAC GOLD Versus Irrigated RF Single Tip Catheter with Contact FORCE Ablation
of the PVs for Treatment of Drug Refractory Symptomatic Paroxysmal and Persistent
AF (GOLD FORCE) (NCT02463851).
Electroanatomical Mapping Systems
AF is a disease frequently progressing from paroxysmal to persistent AF. The mechanisms
underlying the process of arrhythmia perpetuation are complex. Major contributions
to the understanding of the initiating and perpetuating factors derive from mapping
studies in both patients and in animal models of AF. Mapping and ablation of AF require
accurate navigation in the LA within the context of the underlying microstructures
and physiology of the electrogram formation. This can be obtained using standard fluoroscopy
or, more commonly, with EAM systems that combine anatomical and electrical information
by catheter sequential point-by-point or simultaneous multielectrode mapping, allowing
an accurate anatomical reconstruction of the 3D shell of the targeted cardiac chamber.
There are several different EAM systems that are widely used in clinical practice.
The current generation of the CARTO mapping system (CARTO 3; Biosense Webster, Diamond
Bar, CA, USA) relies both on a magnet-based system for accurate localization of dedicated
mapping or ablation catheters and an electrical impedance-based system that allows
for visualization of electrodes and shaft of various types of electrophysiological
catheters. The second EAM system is the electrical mapping system EnSite NavX (current
version, Velocity; St. Jude Medical, Minneapolis, MN, USA), which uses both voltage
and impedance for localization of proprietary and nonproprietary diagnostic and ablation
catheters. This system has now been modified to also provide magnetic-based navigation,
which is anticipated to increase the precision of this system. Another 3D mapping
system that has been developed is the 3D MediGuide system.
735
This sensor-based electromagnetic navigation system allows real-time catheter tracking
in the environment of prerecorded X-ray loops. This system has been shown to easily
integrate into the workflow of a standard AF ablation and allows for high-quality
catheter tracking. Studies have shown that this system is useful in reducing fluoroscopy
exposure for patients and staff. A third EAM system that is available for clinical
use is the magnetic electrical Rhythmia mapping system (Boston Scientific, Marlborough,
MA, USA), which is an EAM system that allows for automated high-density mapping using
a dedicated steerable 64-electrode mini basket catheter.
627
,
632
,
736
This system has only become available in the past several years, and as a result,
the experience with this system is limited. A recent report describes the value of
this system for activation mapping and ablation of complex left AFLs.
627
To further improve the anatomical accuracy of the maps, integration of 3D images obtained
by CT or MRI and of images acquired with intracardiac ultrasound during the procedure
has become available.
737
,
738
Another approach involves use of 3D rotational angiography images that can be merged
with live two-dimensional fluoroscopy.
739
This approach is rarely used at the present time. It is important to recognize that
CT and MRI are not real-time images, and that the accuracy of the use of multiple
imaging modalities is dependent on the accuracy of the image fusion. This requires
the matching of fiducial points from both image sets, and not simply their display
in the same user interface space. In addition, the utility of multimodal approaches
to ablation depends on the quality of electrogram acquisition and the registration
of that physiology onto the 3D images. Again, as more electrodes are simultaneously
used in mapping, synthesizing information from that number of electrograms might require
the use of electrogram single processes made simpler by mathematical manipulations,
such as fast Fourier transform, inverse solution, Hilbert, and phase transformations.
The positive and negative benefits of these manipulations require increased understanding
on the part of the user and do not excuse a clear understanding of the first principles
of cardiac electrophysiology.
The use of these 3D mapping systems has been demonstrated to reduce fluoroscopy duration.
740
,
741
,
742
However, several studies performed to define the clinical benefit of EAM systems have
generated mixed results: whereas some studies have reported that use of these mapping
systems with or without image integration improves the safety and efficacy of AF ablation,
other studies have reported contradictory findings.
743
,
744
,
745
,
746
,
747
Obviously, the use of 3D mapping systems will increase the cost of the procedure.
A survey of the writing group members showed that 93% routinely employ 3D EAM when
performing AF ablation with RF energy.
Robotic and Magnetic Catheter Navigation
The concept of remote catheter navigation is appealing for the operator because these
systems can reduce radiation exposure and the risk to the physician of developing
orthopedic problems related to prolonged use of protective lead aprons during protracted
cases. They also can facilitate analysis of intracardiac electrograms and 3D images
because the catheter navigation and analysis can be performed from the workstation
where the operator is seated. The four technologies developed to meet these objectives
include the magnetic navigation system designed by Stereotaxis Inc; a second magnetic
system referred to as the Catheter Guidance, Control, and Imaging (CGCI) system, for
which there is limited experience; a third robotic-controlled catheter system manufactured
by Hansen Medical; and the remote catheter system developed by Catheter Robotics.
748
,
749
,
750
,
751
These technologies have been used to ablate AF, and there is evidence that they are
safe, effective, and result in a significant reduction in fluoroscopy time and radiation
exposure; however, the studies are relatively small, not randomized, and the populations
of patients are not uniform.
646
,
647
,
748
,
749
,
750
,
751
,
752
,
753
,
754
,
755
,
756
,
757
,
758
,
759
Use of these technologies is a matter of operator preference. The potential advantages
of the systems are offset by additional costs for the navigation systems, disposables,
and maintenance contracts. A survey of the writing group members shows that 10% routinely
employ a robotic or magnetic system when performing AF ablation procedures.
Ultrasound
In the electrophysiology lab, ultrasound is a valuable tool, used both for guiding
vascular access and during the procedure. With a linear probe, central venous access
to the femoral, internal jugular, and subclavian veins can be obtained safely, reducing
complications, the number of attempts, and the time required to gain access.
760
,
761
The impact of real-time ultrasound guidance is even greater in obese patients, in
procedures with less experienced operators, and in patients undergoing anticoagulation
therapy.
ICE, which allows for real-time imaging of cardiac anatomy, is used in many electrophysiology
laboratories throughout the world to facilitate AF ablation procedures.
762
,
763
,
764
,
765
,
766
,
767
Advocates of the use of ICE find it to be of value because it can (1) help identify
anatomical structures relevant to ablation, including the PVs and esophagus; (2) facilitate
transseptal access and allow selective puncture in various regions of the fossa; (3)
guide accurate placement of the multielectrode circular ablation catheter and/or balloon-based
ablation system; (4) allow titration of the delivered energy; (5) provide feedback
about catheter contact; (6) allow for recognition of thrombus formation on sheaths
and catheters; and (7) allow early recognition of cardiac perforation and/or development
of a pericardial effusion.
767
,
768
Some centers also use ICE to screen for the presence of LAA thrombus, because it has
been shown to be comparable to transesophageal echocardiogram (TEE) when performed
by experienced operators. A survey of the writing group members shows that 53% of
the members routinely employ ICE imaging during AF ablation. Our survey revealed that
ICE was being used routinely by 87% of the writing group members in the United States
and Canada compared with 13% of the writing group members from other countries. Among
those who employ ICE imaging, 37% use ICE to screen for LA thrombi prior to performing
the transseptal stick.
PV Venography
PV venography is commonly performed at the time of AF ablation procedures.
769
,
770
The purpose of PV venography is to help guide catheter manipulation, determine the
size and location of the PV ostia, and assess PV stenosis, particularly among patients
undergoing repeat ablation procedures. Among the writing group members, 25% routinely
use PV venography during their AF ablation procedures. There are three techniques
that have been described for PV venography. The first technique involves selective
delivery of contrast media into each of the PV ostia. This can be accomplished by
positioning the transseptal sheath in the region of the right and left PV trunks and
injecting contrast, or by selectively engaging each of the four PV ostia using a deflectable
catheter or a multipurpose angiography catheter.
769
A limitation of the selective PV venography approach is that noncatheterized PVs can
be missed if a preacquired CT or MRI scan is not available to ensure that all the
PVs are identified. The second technique is performed by injection of contrast medium
into the left and right pulmonary arteries or the pulmonary trunk. The location of
the PVs can then be assessed during the venous phase of pulmonary arteriography. The
third technique involves the injection of contrast media in the body of the LA or
at the roof of the right or left superior PV ostium immediately after delivery of
a bolus of adenosine to induce AV block. The contrast media will fill the LA body,
the PV antrum, and the proximal part of the PV during the phase of ventricular asystole.
CT and/or MRI Scans and Rotational Angiography to Define the Anatomy of the Atrium,
PVs, and Antrum
The complex anatomy of the LA plays a major role in the pathophysiology of AF.
771
A detailed understanding of this anatomy is essential for a safe and effective AF
ablation procedure.
772
There is a significant inter- and intrapatient variability in the number, size, and
bifurcation of the PVs
67
,
773
,
774
,
775
,
776
,
777
,
778
(Figure 2
). Common variations include supernumerary right PVs (18%–29%) and common trunk (>30%),
mainly located on the left side and right middle or right top PV.
69
,
776
Knowledge of the presence of additional veins prevents placing ablation lesions over
their ostia, which could result in PV occlusion, whereas knowledge of the bifurcation
pattern is essential during CB PVI, in which wiring of various branches might be needed
to ensure optimal occlusion.
779
LA imaging facilitates ablation by providing detailed anatomical description of the
PVs, antrum, and the remainder of the LA, enabling selection of the most suitable
ablation technique prior to the procedure.
772
,
780
During the procedure, integration of LA images obtained by CT or MRI reduces procedural
time because it enables a more accurate reconstruction of the anatomy.
41
However, this requires accurate registration. Prior to RF ablation, imaging of LA
anatomy with either MRI or CT imaging is performed routinely by 59% of the writing
group members. Prior to CB, AF ablation imaging of the LA anatomy with either MRI
or CT imaging is performed routinely by 56% of the writing group members.
Another method of intraprocedural 3D imaging of the LA is rotational angiography.
After contrast medium injection in the right heart chambers, the fluoroscopy c-arm
is rapidly rotated around the patient, and images are acquired throughout the rotation
to generate 3D volumetric anatomical rendering of the LA. These images can then be
integrated into an EAM system or superimposed on the fluoroscopic projections of the
heart.
781
,
782
A survey of the writing group members shows that rotational angiography is routinely
performed prior to AF ablation by 0% of the writing group members.
After the procedure, LA imaging is valuable in detection of postprocedural complications
such as PV stenosis or AEF.
783
MRI of Atrial Fibrosis and Ablation Lesions and MRI-Guided AF Ablation
AF is associated with various degrees of structural remodeling of the atrial myocardium.
134
,
136
,
139
,
161
,
784
In the ventricular myocardium, MRI is an established modality to visualize myocardial
inflammation and fibrous tissue by using LGE.
134
,
560
,
561
,
785
,
786
However, high-resolution imaging of atrial fibrosis remains technically challenging,
with limited reproducibility of accuracy of MRI measures of fibrosis by different
centers.
787
In a recent study, MRI data of 17% of patients were excluded due to poor quality.
365
MRI may be performed before catheter ablation of AF to identify atrial fibrosis, or
after ablation to visualize RF lesions.
134
,
784
,
788
,
789
Several studies have demonstrated that the extent of atrial fibrosis evaluated by
LGE prior to ablation can predict the outcomes of catheter ablation of AF.
789
Other studies have reported contradictory results.
790
In the multicenter prospective DECAAF trial, the extent of atrial fibrosis found on
preablation MRI was categorized as stage 1 (<10%), stage 2 (10%–20%), stage 3 (20%–30%),
and stage 4 (>30%). AF recurrence 325 days after ablation was independently associated
with the extent of atrial fibrosis (15% for stage 1, 33% for stage 2, 46% for stage
3, and 51% for stage 4).
365
These preliminary results suggest that the extent of fibrosis can be useful to predict
arrhythmia recurrences and to guide the decision to perform catheter ablation in selected
patients with AF. Studies evaluating whether LGE can visualize scar lesions induced
by catheter ablation with RF cryoablation or laser ablation in atrial tissue, or identify
PV reconnection sites have reported conflicting results.
784
,
791
Overall, despite the promise of MRI techniques to improve the outcomes of AF ablation,
further investigation is needed before advocating the systematic use to assist catheter
ablation of AF. The DECAAF-2 study has just been launched for this purpose. This randomized,
prospective, multicenter clinical trial is designed to test the hypothesis that PVI
plus consolidation of fibrotic areas with RF ablation is superior to PVI alone.
791
A survey of the writing group members shows that MRI for detection of scar is routinely
performed prior to AF ablation by 8% of the writing group members.
During the past decade, a number of centers have developed the technology to allow
real-time MR-guided electrophysiology intervention. Advantages of this approach include
the absence of ionizing radiation and the ability to monitor lesion development in
real time. Although these systems are still under development and are not available
with routine clinical use at this time, this is an area of considerable interest that
could emerge as an important ablation monitoring and guidance strategy in the future.
792
,
793
,
794
,
795
Section 7: Technical Aspects of Ablation to Maximize Safety and Anticoagulation
Prevention of Thromboembolism During and Following AF Ablation
Patients with AF are at increased risk of thromboembolism during, immediately following,
and for several days to months after their ablation.
796
,
797
,
798
,
799
ACE lesions have also been observed after AF ablation.
800
The prothrombotic state associated with AF ablation results in a higher, but transient,
thromboembolism risk in patients with AF who were identified as low-risk before ablation.
Careful attention to anticoagulation of patients before, during, and after ablation
for AF is critical to avoid the occurrence of a thromboembolism event. Consensus recommendations
for anticoagulation prior to, during, and following ablation are summarized in Table
4
. The ablation procedure leaves patients with substantial areas of damaged LA endothelium
that can become a nidus for thrombus formation. Transseptal sheath placement and insertion
of electrode catheters can precipitate thrombus formation on the catheter or on or
within the sheath during the procedure.
768
,
801
,
802
,
803
,
804
The atrial tissue can be stunned for weeks or months postprocedure, leading to impairment
of normal contraction.
805
Anticoagulation, in turn, contributes to some of the most common complications of
the procedure, including hemopericardium, pericardial tamponade, and vascular complications.
806
,
807
,
808
Therefore, attention must be paid to achieving the optimal safe level of anticoagulation
throughout the process.
Screening for LAA Thrombi Prior to Ablation
Transesophageal Echocardiography
Thromboembolic stroke after AF ablation is a devastating consequence of an invasive
procedure. One of the mechanisms could be dislodgement of a pre-existing clot that
could be identified by a screening TEE. The risk of a thromboembolic event at the
time of an AF ablation procedure varies, depending on a number of factors, including
(1) the type of AF; (2) the presence, absence, and duration of AF as the presenting
rhythm on the day of ablation; and (3) the patient's stroke risk profile, including
LA size and CHA2DS2-VASc score. With careful, multiplanar inspection of the LAA and
the number of LAA lobes, the TEE can also provide additional information to help guide
the procedure, such as identification of a pre-existing pericardial effusion, globally
impaired cardiac function, presence of an atrial septal defect (ASD) or persistent
foramen ovale, or fibrosis of the interatrial septum after previous ablation.
809
,
810
,
811
In addition, LA anatomical features, such as a thickened ridge toward the left PVs,
PV stenosis or occlusion, or cor triatriatum, can be identified.
Because many centers perform their procedures on uninterrupted OAC, one could argue
that TEE is unnecessary; however, studies evaluating the incidence of LA thrombus
on TEE among patients undergoing AF ablation who have been therapeutically anticoagulated
have consistently demonstrated that 1.6% to 2.1% of patients will have a thrombus
or “sludge” in the LAA.
796
,
812
,
813
The probability of identifying a thrombus was related to the CHA2DS2-VASc score in
some but not in every case. Other risk factors for thrombus were LA size and a history
of persistent AF. Among patients with a CHA2DS2-VASc score of zero, a thrombus was
identified in < 0.3% of patients compared with >5% of patients with a CHA2DS2-VASc
score of ≥ 2. The practice of routine vs selective TEE surveillance for LAA or intracavitary
thrombus prior to PVI varies widely, given evidence to guide this decision is limited
in terms of important clinical outcomes.
796
,
809
,
810
,
811
,
812
,
813
,
814
A survey of the writing group members shows that 51% perform a TEE in all patients
presenting for AF ablation regardless of presenting rhythm and anticoagulation status.
This survey also revealed that 71% of the writing group members perform a TEE in patients
presenting AF who have been therapeutically anticoagulated for 3 or more weeks prior
to ablation. Among patients who present for AF ablation in sinus rhythm who have not
been previously anticoagulated, 78% of the writing group members routinely perform
a TEE. Among patients presenting for AF ablation who are chronically anticoagulated
with warfarin, 87% of the writing group members perform AF ablation on uninterrupted
warfarin. Among patients undergoing AF ablation who are chronically maintained on
a NOAC, 38% of the writing group members perform AF ablation on a patient receiving
uninterrupted NOAC without withholding a dose. For patients not anticoagulated prior
to ablation or in whom NOAC therapy is interrupted prior to ablation, 16% of the writing
group members reinitiate the NOAC at 2 hours, 12% at 3 hours, 37% at 4 hours, and
35% at 4 or more hours after initially achieving hemostasis. It is important to recognize
that this is a rapidly evolving area in AF ablation. The results of the above survey
were obtained prior to publication of the results of the Randomized Evaluation of
Dabigatran Etexilate Compared to Warfarin in Pulmonary Vein Ablation: Assessment of
an Uninterrupted Periprocedural Anticoagulation Strategy (RE-CIRCUIT) trial, which
demonstrated that performance of AF ablation on patients receiving uninterrupted dabigatran
results in a lower rate of major bleeds compared with the uninterrupted warfarin strategy.
815
,
841
Shown in Table 4
are the writing group recommendations concerning anticoagulation strategies prior
to ablation. As with the anticoagulation guidelines for cardioversion of AF, if a
thrombus is identified in the LAA prior to catheter ablation of AF, the AF ablation
procedure should not be performed.
Computer Tomographic Angiography
Data are emerging to suggest that CT imaging can be valuable in detecting thrombi
prior to an AF ablation procedure. Several studies have investigated whether CT imaging
can be used to screen for LA thrombi, with the hope of obviating the need for a screening
TEE in at-risk patients. Compared with TEE as a gold standard, several studies and
one meta-analysis have reported a high diagnostic accuracy of CT to detect LAA thrombi.
780
,
816
,
817
Other studies have reported lower diagnostic accuracy and high inter-reader variability
in detecting LA thrombi with CT imaging.
818
,
819
In a meta-analysis of studies using delayed imaging protocols, the diagnostic accuracy
for detection of LAA thrombi was reported to be 99%.
817
These findings suggest that cardiac CT (with an acceptable radiation dose) could be
of value in detecting LA thrombi. It is important to note that in many centers the
CT is obtained days to weeks prior to ablation, rendering this imaging modality of
no value because of this time delay.
The writing group members believe that the data are currently insufficient to recommend
widespread use of CT imaging as an alternative to TEE for preablation screening for
LA thrombi. This sentiment reflects in large part a great variability in CT detector
imaging equipment and protocols. Further large-scale studies will be required before
CT imaging can be considered an alternative for TEE screening prior to AF ablation.
A survey of the writing group members shows 49% of the members employ CT imaging on
a routine basis prior to AF ablation. Among those who obtain CT imaging, 32% use the
CT image to identify LAA thrombi.
Intracardiac Echocardiography
Data are also emerging to suggest that ICE can be valuable in detecting LAA thrombi
prior to an AF ablation procedure. Imaging from the pulmonary artery is preferred.
Whereas the ICE-CHIP study demonstrated that ICE imaging from the RA had reduced sensitivity
in the detection of LA thrombi compared with standard TEE, other studies showed that
ICE imaging from the pulmonary artery can be used safely and effectively (compared
with TEE) for the evaluation of the LAA in patients undergoing ablation.
768
,
820
,
821
,
822
,
823
Of interest, ICE has been shown to have complementary value in rescreening the LA
and the LAA for thrombus after a recent negative or equivocal TEE.
824
These findings suggest that ICE could be of value in detecting LA thrombi. However,
the writing group members believe that the data are currently insufficient to recommend
widespread use of ICE imaging as an alternative to TEE for preablation screening for
LA thrombi. This sentiment reflects in large part a great variability in the skills
needed to both perform and interpret the results of ICE imaging for thrombi detection.
Further large-scale studies will be required before ICE imaging can be considered
to be a standard and proven alternative for TEE screening prior to AF ablation. A
survey of the writing group members shows that 53% of the members routinely employ
ICE imaging during AF ablation. Our survey revealed that ICE was being used routinely
by 87% of the writing group members in the United States and Canada compared with
13% of the writing group members from other countries. Among those who employ ICE
imaging, 37% use ICE to screen for LA thrombi prior to performing the transseptal
stick. Based on this information and a review of the literature, the writing group
recommends that use of ICE to screen for atrial thrombi in patients who cannot undergo
TEE imaging may be considered (Class IIb, LOE C-EO, Table 4
).
Anticoagulation
Systemic Anticoagulation Prior to AF Ablation
Many patients who are undergoing AF ablation have an elevated risk of stroke as assessed
using the CHA2DS2-VASc score and are therefore systemically anticoagulated with warfarin
or with a direct thrombin or factor Xa inhibitor.
825
,
826
,
827
,
828
Most operators initiate therapeutic anticoagulation for at least 3 weeks prior to
ablation in patients with a CHA2DS2-VASc risk score of 2 or greater, especially if
they are likely to present for the procedure in AF. Because of the slow offset and
onset of warfarin, these patients were historically transitioned or “bridged” with
heparin or low molecular weight heparin before and after the ablation procedure. An
increased recognition of bleeding complications associated with this practice, especially
at the site of vascular access, has led to the use of uninterrupted warfarin, which
has been shown to have a better safety profile, provided the international normalized
ratio (INR) is within the target range.
399
,
400
,
401
,
532
,
533
,
829
,
830
,
831
,
832
,
833
,
834
Dabigatran and the factor Xa inhibitors (apixaban, rivaroxaban, edoxaban) have a more
rapid onset of action, a shorter half-life, and a more predictable dose response compared
with warfarin. Accumulating evidence and several meta-analyses have demonstrated similar
efficacy and safety of dabigatran and the factor Xa inhibitors compared with warfarin
in the setting of catheter ablation.
835
,
836
,
837
,
838
,
839
,
840
,
841
,
842
,
843
These data provide reassurance; however, several methodological considerations warrant
mention. In most of these studies, one or two doses of the NOACs were held prior to
AF ablation. Nearly all of the included studies were observational in design, and
are therefore subject to confounding and selection bias. The sample sizes of the individual
treatment arms were small, and study heterogeneity precludes statistically robust
comparisons. In addition, the study populations were predominantly male, largely characterized
by normal renal function, and the mean patient age was 61 years, a decade younger
than the stroke prevention trial populations.
The results of the RE-CIRCUIT study were recently published, which was a head-to-head
comparison of performing AF ablation on patients receiving uninterrupted dabigatran
vs uninterrupted warfarin.
841
This study randomized 704 patients across 104 sites to these two anticoagulation strategies.
The incidence of major bleeding events during and up to 8 weeks postablation among
the 635 patients who underwent AF ablation was significantly lower with dabigatran
than with warfarin (5 patients [1.6%] vs 22 patients [6.9%]); absolute risk difference
[RD] −5.3%, RR reduction 77%. There were six patients with cardiac tamponade in the
warfarin arm vs one in the dabigatran arm. No strokes or other thromboembolic events
occurred in the dabigatran arm compared with one TIA in the warfarin arm. No patients
in the dabigatran arm required the specific reversal agent idarucizumab. There has
been one other smaller head-to-head comparison published of uninterrupted rivaroxaban
vs uninterrupted warfarin (Venture-AF, N = 248).
842
This study reported one major bleeding event, one ischemic stroke, and one vascular
death, each of which occurred in the warfarin arm of the study. A third trial of apixaban
vs coumadin is also underway (NCT02227550).
Based on these clinical trials, it is now apparent that a strategy of performing AF
ablation on patients receiving uninterrupted anticoagulation can be performed safely
and minimizes the risk of thromboembolic events. Specific recommendations for pre-
and intraprocedure anticoagulation are shown in Table 4
. Although further studies are needed to further define the efficacy and safety of
performing AF ablation on uninterrupted Factor XA inhibitors or direct thrombin inhibitors,
the writing committee believes that the data and worldwide experience are now sufficient
to provide a Class I recommendation for performing AF ablation with uninterrupted
dabigatran (Class I, LOE A) or rivaroxaban (Class I, LOE B-R), and a 2A recommendation
for the other XA inhibitors for which specific clinical studies have not been performed
at this time. Further studies are needed to determine if a TEE can be omitted in patients
with a high stroke risk profile who present for ablation in AF and are undergoing
ablation on uninterrupted anticoagulation. Data will also be needed on outcomes and
use of specific reversal agents in this setting, particularly for management of serious
procedural bleeding complications.
844
,
845
Table 4
summarizes the recommendations for anticoagulation pre-, during, and post-AF ablation,
both for warfarin and for the NOACs.
Intraprocedural Anticoagulation
Optimal anticoagulation using heparin with close attention to maintaining therapeutic
dosing during the procedure is important. It is recommended that heparin be administered
prior to or immediately following transseptal puncture during AF ablation procedures
and adjusted to achieve and maintain a target activated clotting time (ACT) of 300 seconds
or greater (Class I, LOE B-NR, Table 4
). It has been observed that thrombi can form on the transseptal sheath and/or the
electrode catheter almost immediately after crossing the septum and that early heparinization
substantially decreases this risk.
768
,
802
,
803
,
804
,
846
,
847
,
848
A recent meta-analysis of more than 7000 patients supports this recommendation, showing
that performing ablation of AF with a target ACT >300 seconds decreases the risk of
thromboembolic complications without increasing the risk of bleeding.
849
Seventy-seven percent of the writing group members administer heparin prior to the
transseptal puncture. A heparin loading dose should be administered initially, followed
by a standard heparin infusion. The ACT level should be checked at 10–15 minute intervals
until therapeutic anticoagulation is achieved, and then at 15–30 minute intervals
for the duration of the procedure. Patients receiving a vitamin K antagonist (VKA)
require less heparin and reach the target ACT faster compared with NOACs; thus, when
using anticoagulation strategies with the latter, more frequent ACT monitoring and
higher heparin doses should be used.
840
,
849
This recent report from a large-volume medication center employs an initial heparin
bolus of 50 units per kg in patients who are therapeutically anticoagulated with warfarin,
75 units per kg in patients who are not anticoagulated prior to ablation, and 120
units per kg for patients who are anticoagulated on a NOAC and have held one to two
doses. A survey of the writing group showed great variability in loading protocols
for heparin prior to an ablation procedure. The heparin dose should be adjusted to
maintain an ACT of at least 300–350 seconds throughout the procedure. One-third of
the writing group members routinely employ a target ACT of > 350 seconds.
820
,
830
,
846
Heparinized saline should be infused continuously through each transseptal sheath
to further reduce the risk of thrombi.
802
The risk of systemic embolization of thrombus formed on a sheath can be reduced by
withdrawing the sheath to the RA once a catheter is positioned in the LA. Heparin
infusion can be discontinued once all catheters are removed from the LA, and the sheaths
removed from the groin when the ACT is less than 200–250 seconds. Sheaths can be removed
during full anticoagulation by employing a figure-of-eight suture.
850
Alternatively, the heparin effect can be reversed with protamine (Class IIa, LOE B-NR,
Table 4
).
851
This approach is used by 70% of the writing group members.
In the event of persistent bleeding or cardiac tamponade, protamine should be administered
to reverse heparin. If bleeding resolves, then reversal of the oral anticoagulant
is not recommended, because this continues to offer protection from thromboembolic
complications postprocedure. However, if pericardial or other bleeding persists with
the above measures, fresh frozen plasma can be administered for reversal of warfarin.
Dabigatran can be reversed with idarucizumab.
844
Development of a reversal agent for Factor Xa inhibitors is underway but is not yet
available on a clinical basis.
845
Until these agents are available, it is recommended that prothrombin complex concentrates
(PCC: Factors II, VII, IX, and X) or recombinant activated factor VII (rFVIIa) be
administered.
852
The increasing availability of specific reversal agents for factor IIa and Xa inhibitors
will certainly encourage the adoption of continuous anticoagulation with the newer
oral anticoagulants during AF ablation.
Early Postprocedural Anticoagulation
There is a prothrombotic milieu following RF ablation for AF due to reduced contraction
of the atria, endothelial damage from ablation lesions, and a thrombogenic state.
Therefore, it is the consensus recommendation of the writing group members that patients
should be anticoagulated for at least 2 months postablation, regardless of their CHA2DS2-VASc
score or rhythm status (Class I, LOE C-EO, Table 4
). In patients treated with warfarin who have a subtherapeutic INR the day of the
procedure, there are two options. First, a direct thrombin or Factor Xa inhibitor
can be administered several hours following ablation.
826
,
827
,
853
,
854
Second, low molecular weight heparin (enoxaparin 0.5–1.0 mg per kg twice daily) or
intravenous heparin can be used as a bridge to resumption of INR 2.0–3.0. For most
patients, other than those with prosthetic valves who will need to remain indefinitely
on warfarin, initiation of a NOAC postablation is a preferred strategy to use instead
of heparin or low molecular weight heparin due to the increased bleeding risk with
these agents.
It is expected that patients will have their sheaths removed immediately after ablation,
either with or without the use of protamine to reverse the intravenous heparin used
during the procedure. Hemostasis can be achieved by either direct pressure or the
use of a figure-of-8 suture. Evidence for the safety of uninterrupted NOAC therapy
has increased with the recent publication of Venture AF and RE-CIRCUIT.
841
,
842
Despite these new data, some centers have the patient withhold one to two doses of
NOACs in the days prior to their ablation procedure. For these patients, reinitiation
of the NOAC should take place as soon as the clinician is satisfied that there is
no significant pericardial effusion or vascular bleeding following the ablation. Similarly,
for the small subset of low-risk patients who were not being treated with anticoagulation
before the procedure, a NOAC can be administered immediately following ablation. The
writing group members advise that readministration of a NOAC be given 3 to 5 hours
after completion of the procedure and removal of the vascular sheaths, provided there
is no evidence of ongoing bleeding, or a significant pericardial effusion or cardiac
tamponade is reasonable (Class IIa, LOE C-EO, Table 4
).
Anticoagulation Considerations Two or More Months Postablation
Whether elimination of AF or reduction of AF burden by catheter ablation results in
a significant reduction in stroke risk is an important, and as yet unanswered, question.
Until this important question is addressed by an adequately designed clinical trial,
adherence to the AF anticoagulation guidelines is recommended for patients who have
undergone AF ablation procedures, regardless of the apparent success or failure of
the procedure (Class I, LOE C-EO, Table 4
). The writing group advises that decisions regarding continuation of systemic anticoagulation
more than 2 months postablation should be based on a patient's stroke risk profile
and not on the apparent success or failure of the ablation procedure (Class I, LOE
C-EO, Table 4
). And finally, the writing group recommends that for patients in whom discontinuation
of anticoagulation is being considered based on the patient's values and preferences,
they should consider undergoing continuous or frequent ECG monitoring to screen for
AF recurrence (Class IIb, LOE C-EO, Table 4
). This recommendation is based on the following: (1) recurrences of AF are common
both early and late following AF ablation; (2) asymptomatic AF is common, and is more
common following AF ablation than prior to AF ablation; (3) AF ablation destroys a
portion of the atria and the impact of this on stroke risk is uncertain; (4) there
have been no large, randomized prospective trials that have assessed the safety of
discontinuing anticoagulation in this patient population; (5) studies have shown that
strokes in patients with AF might not be temporaneously related to an AF event
855
; and (6) the use of direct thrombin inhibitors or Factor Xa inhibitors, such as dabigatran,
rivaroxaban, edoxaban and apixaban, is more convenient than warfarin.
825
,
826
,
827
,
828
The small subset of writing group members who support the discontinuation of systemic
anticoagulation in patients with an increased stroke risk profile make the argument
that (1) continuing anticoagulation exposes patients to the risks for hemorrhage and
the unfavorable effects of anticoagulation on long-term QOL; (2) several large outcome
studies have reported a lower-than-expected stroke risk in patients who undergo AF
ablation compared with control populations
239
; and (3) one center has reported a low stroke risk in patients postablation who screen
for recurrence by pulse assessment or ECG monitoring.
238
,
407
,
409
,
545
,
856
,
857
,
858
,
859
,
860
In considering these consensus recommendations, it is worth commenting that some patients
who have multiple stroke risk factors are highly motivated to discontinue systemic
anticoagulation and are willing to accept a possible increased risk of stroke. It
is for these patients that we recommend that some type of continuous monitoring be
performed to screen for silent AF at regular intervals as long as they remain untreated
with systemic anticoagulation. A survey of the writing group members shows that 77%
continue anticoagulation indefinitely in patients who have undergone AF ablation and
who have a CHA2DS2-VASc score of 2 or greater. It is possible that the outcomes of
the CABANA and Early Treatment of Atrial Fibrillation for Stroke Prevention Trial
(EAST) (NCT01288352) will help clarify this issue. In selected patients with ECG,
evidence of AF control, and diligent follow-up for AF recurrences, 23% of the writing
group members indicated that they would consider discontinuing anticoagulation after
a conversation with the patients in which risks and benefits were discussed. This
survey also shows that only 1 writing committee member (2%) routinely discontinues
anticoagulation in all patients following AF ablation who are AF-free.
It is important to recognize that the above discussion has focused on patients at
high risk of stroke (i.e., CHA2DS2-VASc score ≥2). There is far greater flexibility
as to how anticoagulation is managed in patients at a low or moderate risk of stroke
because current guidelines do not mandate systemic anticoagulation. Another important
consideration is that patient preference plays a large role in this decision. It is
our belief that patients should be made aware of the available data and consensus
recommendations, and then should be encouraged to consider the risks and benefits
of continuing vs discontinuing systemic anticoagulation. Some patients who are at
increased risk of stroke are highly motivated to discontinue systemic anticoagulation
and are willing to accept an increased risk of stroke. For these patients, we recommend
diligent pulse assessment at least twice daily and strong considerations that some
type of continuous monitoring be performed to screen for silent AF at regular intervals
as long as they remain free from systemic anticoagulation. A final comment worth mentioning
is that the mechanisms of stroke are not limited to cardioembolism due to AF; thus,
other sources of emboli should also be considered, such as paradoxical embolism and
atheromas from the aortic arch. In the remainder of this section, we will briefly
review some of the available data.
In multiple randomized trials, AF ablation was superior to AADs in reducing AF recurrence
in drug-refractory patients.
861
However, stroke prevention among these strategies has been largely similar. One investigator
recently undertook a meta-analysis to evaluate whether AF ablation reduces the long-term
risk of stroke compared with AAD therapy.
857
Thirteen RCTs were analyzed, with 1097 patients treated by catheter ablation and 855
patients receiving AAD therapy. Overall, seven patients (0.64%) in the catheter ablation
group had ischemic stroke or TIAs vs two patients (0.23%) in the drug therapy group.
No difference was shown in the rate of stroke or TIA between ablation and drug therapy.
To date, however, no AF ablation trial has evaluated whether successful ablation obviates
the need for long-term OAC, but there are reports from large administrative registries
and observational studies addressing this issue.
One study evaluated the long-term results of OAC cessation after successful catheter
ablation of AF.
857
OAC and AADs were discontinued irrespective of AF type or baseline CHA2DS2-VASc risk
score in 327 patients with drug-refractory AF after catheter ablation. Patients with
a CHA2DS2-VASc score of 2 (45.4%) and 3 (23.2%) accounted for 68.8% of this cohort.
In the patients with a high risk of recurrence or prior thromboembolic complications,
OAC was continued for up to 6 to 12 months postablation, and antiplatelet therapy
was administered to all patients who maintained sinus rhythm upon OAC interruption.
After a follow-up of 46 months, 82% remained AF-free (free from AADs). No symptomatic
ischemic cerebrovascular events were detected during follow-up, despite interruption
of OAC in 298 (91%) patients and AADs in 293 (89%) patients.
Another study reported the patterns of anticoagulation use and cardioembolic risk
after catheter ablation for AF.
862
They found an increased use of NOACs after ablation from 0% in 2005 to 69.8% in 2014.
OAC discontinuation was high, with only 60.5% and 31.3% of patients remaining on OAC
at 3 and 12 months, respectively. The rate of discontinuation was higher in low-risk
patients (82% vs 62.5% at 12 months for CHA2DS2-VASc 0–1 vs ≥ 2, respectively; P <.001).
Stroke occurred in 1.4% of the patients with CHA2DS2-VASc ≥2 and in 0.3% of those
with a CHA2DS2-VASc of 0 or 1 over the study follow-up. The risk of cardioembolism
in the first 3 months after ablation was increased among those with any time free
from OAC (HR 8.06; 95% CI 1.53–42.3; P <.05). The risk of cardioembolism beyond 3 months
was increased with OAC discontinuation among high-risk patients (HR 2.48; 95% CI 1.11–5.52;
P <.05) but not low-risk patients, suggesting that continuing OAC for at least 3 months
in all patients and indefinitely in high-risk patients appears to be the safest strategy
in the absence of effective monitoring and AF detection.
An AF ablation registry reported data of patients followed up after ablation of PAF
in a high-risk group (previous stroke; group 1) and a low-risk group (no previous
stroke; group 2) based on data from the German Ablation Registry, to reveal real-life
prescription behavior.
412
Between April 2008 and April 2011, 83 patients in group 1 and 377 patients in group
2 with a first ablation of PAF were included in the registry. The results showed a
mean CHA2DS2-VASc score of 4.2 ± 1.4 (group 1) vs 1.6 ± 1.2 (group 2) (P <.0001).
OAC was discontinued in 38.6% of the patients in group 1 vs 66.3% of those in group
2 (P <.0001) during follow-up. Thromboembolism occurred more often in group 1 than
in group 2 (4.3% vs 0.3%, P <.05), arguing against OAC discontinuation in a high-risk
population without ongoing pulse assessment and ECG monitoring.
Another study in a large Danish cohort
410
evaluated the long-term risk of thromboembolism and serious bleeding associated with
OAC therapy beyond 3 months after RF ablation of AF. During a median follow-up of
3.4 years, 71 (1.8%) thromboembolism cases were identified, in which incidence rates
with and without OAC were similar at 0.56 (95% CI 0.40–0.78) and 0.64 (95% CI 0.46–0.89),
respectively. OAC therapy was significantly associated with serious bleeding risk
(HR 2.05; 95% CI 1.25–3.35). Of note, half the patients received OAC for at least
1 year after catheter ablation, including 56% of the CHA2DS2-VASc = 0 patients and
67% of the CHA2DS2-VASc = 1 patients. As expected, bleeding events were higher in
the patients who remained on anticoagulation after AF ablation (HR 2.05).
Another study assessed the feasibility for discontinuation of OAC after ablation based
on the AF burden documented by implantable cardiac monitors.
859
During a follow-up time of 32 ± 12 months (126 patient-years), 41 of the 65 patients
(63%) had an AF burden <1 hour per day and were able to stay off OAC. Twenty-one patients
(32%) had to reinitiate OAC due to an AF burden >1 hour, and three patients reinitiated
OAC due to other reasons. No stroke, TIA, or other thromboembolic event was observed
during follow-up. These are important data for those patients who decide not to receive
chronic OAC, and we suggest consideration of an anticoagulation strategy based on
AF burden measured by monitoring.
Another single-center report described outcomes in 635 patients with one or more risk
factors for stroke during a mean follow-up of 836 ± 605 days after an AF procedure.
545
Anticoagulation was discontinued in 434 of 517 patients who remained in sinus rhythm,
and aspirin and/or clopidogrel was prescribed. There were three ischemic strokes and
two TIAs in the anticoagulation discontinuation group. The estimated 5-year stroke
rate in this group was 3%.
An observational study from five large AF ablation centers included data from 3344
patients who underwent AF ablation.
238
Oral anticoagulant therapy was typically discontinued regardless of the CHA2DS2-VASc
score if patients did not manifest one of the following: (1) any recurrence of ATAs;
(2) severe PV stenosis; or (3) severe LA mechanical dysfunction. After discontinuation
of anticoagulation, the patients were treated with aspirin. If AF recurred, anticoagulation
was restarted in those with a CHA2DS2-VASc score of one or more. There were 347 patients
who had a CHA2DS2-VASc score of >2. Among these 347 patients, no thromboembolic events
occurred.
One of the most recent studies to be published reports data from the Swedish national
health registry.
863
Among 1175 individuals followed for more than a year post-AF ablation, 30% discontinued
warfarin treatment during the first year. In patients with a CHA2DS2-VASc score >2,
the patients discontinuing warfarin had a higher rate of ischemic stroke (1.6% per
year vs 0.3% per year for those who continued warfarin). Patients with a CHA2DS2-VASc
score >2 and who had had a prior ischemic stroke displayed an especially high risk
of stroke if warfarin was discontinued (HR 4.6). It is important to note that in this
registry, recurrence rates of AF after ablation were quite high. Sixty percent of
the entire cohort and 8 of the 11 patients with stroke (72.7%) underwent cardioversion
of AF or a second PVI. The study convincingly demonstrated that in patients with recurrent
AF after catheter ablation, a high CHA2DS2-VASc score, and/or a history of stroke,
OAC therapy should not be discontinued. Because there were so few patients without
AF recurrence, the question of whether “successful” AF ablation might convey a lower
risk was not adequately addressed.
As stated above, there is a lack of randomized trials evaluating this important clinical
challenge; however, there are some ongoing trials, such as EAST and CABANA, which
will address the prognostic impact of rhythm control therapy, including AF ablation
and the effect of rhythm control therapy on stroke. Other trials are needed to define
the optimal anticoagulation during AF ablation procedures in an era in which novel
anticoagulants are increasingly used. We are optimistic about the ongoing Optimal
Anticoagulation for Higher Risk Patients Post-Catheter Ablation for Atrial Fibrillation
(OCEAN) trial (NCT02168829), which will effectively determine whether successful long-term
reduction or elimination of AF with catheter ablation will reduce stroke risk sufficiently
to obviate the need for long-term OAC. Additionally, the ongoing Prevention of Silent
Cerebral Thromboembolism by Oral Anticoagulation With Dabigatran After PVI for Atrial
Fibrillation (ODIn-AF) trial (NCT02067182) will address the effect of dabigatran compared
with no OAC on the incidence of silent cerebral embolic events in patients with a
high risk for embolic events, but who are free from symptomatic AF after successful
PV ablation.
Until the outcomes of such trials are available, our current treatment recommendations
to continue OAC after catheter ablation of AF in patients at high risk for stroke
should continue. In patients who desire to discontinue anticoagulants because of ECG-documented
AF elimination who remain at risk because of high CHA2DS2-VASc score, an individualized
approach after full disclosure is warranted. It is important that patients who are
considering discontinuation of anticoagulation in the setting of a stroke risk profile
have a complete discussion of the potential risks of this strategy. As noted above,
the writing group recommends that, for patients in whom discontinuation of anticoagulation
is being considered based on the patient's values and preferences, they should consider
undergoing continuous or frequent ECG monitoring to screen for AF recurrence, although
recurrence of AF is only one of many reasons for stroke events after discontinuation
of anticoagulation (Class IIb, LOE C-EO, Table 4
). Whether this strategy results in a significant reduction of stroke risk remains
uncertain at this time.
Less information is available concerning the optimal approaches to anticoagulation
following surgical ablation of AF. Many variables need to be considered, including
whether the patient underwent ligation of their LAA and the patient's stroke risk
profile. At the present time, there is little to no evaluable evidence for or against
the merits of anticoagulation following surgical ablation when the LAA has been surgically
obliterated. In the absence of current evidence, the decision to anticoagulate and
the duration of treatment should be made on an individual basis weighing the risks
and benefits of anticoagulation in the postsurgical patient. It is, however, not unreasonable
to anticoagulate for several months following surgical ablation, provided there are
no other bleeding risks. For patients in whom appendage closure or ligation was performed
at the time of surgical ablation, and in whom discontinuation of anticoagulation is
being considered, TEE-based assessment of whether complete appendage closure has been
accomplished is recommended because incomplete closure of the LAA is not uncommon.
Anesthesia or Sedation During Ablation
Patients undergoing catheter ablation of AF are required to lie motionless on the
procedure table for several hours, and repeated stimuli from ablation are sometimes
painful. For these reasons, most patients are treated with conscious sedation or general
anesthesia. The choice of approach is determined by the institutional preference and
by assessment of the patient's suitability for conscious sedation.
General Anesthesia
AF ablation procedures are commonly performed under general anesthesia. Not only does
use of general anesthesia improve the safety of the procedure for patients at risk
of airway obstruction, but it also improves patient comfort and might improve efficacy
by preventing patient movement during the procedure. Given the need to minimize patient
movement to improve catheter and mapping system stability, general anesthesia or deep
sedation are generally preferred. One prospective randomized clinical trial randomized
patients with general anesthesia or conscious sedation. This study reported that use
of general anesthesia increased the single procedure success rate, lowered the prevalence
of PV reconnection among those who needed a redo procedure, and shortened fluoroscopy
time and procedure time.
633
General anesthesia is of particular importance for patients at risk of airway obstruction,
those with a history of sleep apnea, and those at increased risk of pulmonary edema.
General anesthesia may also be employed electively in healthy patients in order to
improve patient tolerance of the procedure. Anesthesia or analgesia needs to be administered
by well-trained and experienced individuals with monitoring of heart rate, noninvasive
or arterial line BP, and oxygen saturation. Guidelines for assessing levels of anesthesia
and training requirements for administration of intravenous sedation during procedures
have been developed by the American Society of Anesthesiologists, which can be found
on their website. A survey of the writing group members shows that in the United States
and Canada, 85% routinely employ general anesthesia. Outside the United States and
Canada, 45% routinely employ general anesthesia. (Please also see discussion of anesthesia
on page e51).
Conscious and Deep Sedation
Deep sedation is a step beyond conscious sedation and just before general anesthesia.
Generally, only anesthesia providers or specially trained physicians can provide deep
sedation because airway and hemodynamic management might be required. The major limitation
to deep sedation is the need for the patient to lie on the procedure table with minimal
movement during the entire procedure. RF lesions can be associated with intense pain,
resulting in patient movement. The location of sites eliciting pain with RF lesions
are not predictable, although are most often located on the posterior wall. Monitoring
esophageal temperature during deep sedation is possible, but more cumbersome, due
to intact airway reflexes that are abolished during general anesthesia. Patient movement
with right phrenic stimulation during CB procedures is also a common occurrence with
deep sedation, and is largely absent with the use of general anesthesia.
Jet Ventilation
Catheter stability and catheter contact during LA ablation are crucial for effective
lesion creation. Both catheter stability and catheter–tissue CF can be further increased
by reduced respiratory thoracic excursions. Data from one institution suggest improved
clinical outcome as a result of enhanced lesion quality and reduction of PV reconnection
when applying high-frequency jet ventilation in general anesthesia during PVI.
634
,
864
,
865
Further data from other centers are needed, however, before final conclusions can
be drawn. A survey of the writing group members reveals that in the United States
and Canada, 14% routinely employ high-frequency jet ventilation. Outside the United
States and Canada, 4% routinely employ high-frequency jet ventilation during AF ablation
procedures.
Summary
The type of anesthesia used for AF ablation depends in part on the availability of
anesthesia support for ablation procedures. Given the need to minimize patient movement
to improve catheter and mapping system stability, deep sedation or general anesthesia
is generally preferred.
Approaches to Minimize Risk of an AEF
A rare but potentially devastating complication of AF ablation is injury to the esophagus,
with the possible outcome of AEF or esophageal perforation leading to mediastinal
infection, stroke, and/or death.
866
,
867
,
1398
Another complication that is thought to be related to thermal injury to the periesophageal
vagal plexus is gastroparesis.
868
More information concerning the incidence, presentation, and management of these complications
is presented under Section 10. Because of the serious consequences of an AEF, it is
important to attempt to prevent severe esophageal and periesophageal injury. Some
operators design the ablation lesions to avoid the esophagus. The location of the
esophagus can be visualized using a variety of approaches, including multidetector
CT, topographic tagging of the esophageal position with an EAM system, barium paste,
and ICE.
869
,
870
,
871
,
872
,
873
,
874
,
875
,
876
It is important to know that esophagus location can change during the procedure, and
repeated imaging or visualization is needed to account for the motion of the esophagus.
However, it is difficult to accomplish complete PV ablation without some ablation
in close proximity to the esophagus. Strategies to prevent and treat esophageal injury
follow.
Reduced Power Delivery on the Posterior Wall
Higher power and greater depth of tissue heating or cooling are associated with increased
risk of esophageal injury. In order to minimize injury to the esophagus during RF
applications on the posterior wall close to the esophagus, several approaches can
be employed, including (1) reduction of RF power (e.g., ≤25 W); (2) shortening RF
application time (e.g., ≤20 seconds); and/or (3) decreasing CF (e.g., ≤10 grams).
The writing group recommends that RF power be reduced when creating lesions along
the posterior wall near the esophagus (Class I, LOE C-LD, Table 3
). Some reports employed the use of light conscious sedation to use pain to identify
potential esophageal injury. However, there are conflicting data on the specificity
of the pain response. It has been proposed that an alternative energy source, such
as the CB for PVI, could minimize esophageal injury
877
,
878
; however, AEF or periesophageal vagal plexus injury after CBA has been reported.
879
,
880
There are also data that other heat-based energy sources, such as high-intensity focused
ultrasound or laser energy, can damage the esophagus.
501
,
502
,
700
,
701
,
705
,
881
Although each of these approaches is variously adopted by different ablation centers,
each remains largely unproven due to the rarity of an AEF as a complication.
Esophageal Temperature Monitoring
A strategy to avoid esophageal injury employed by 65% of the writing group members
is luminal esophageal temperature monitoring, used to identify potentially dangerous
heating of the esophagus.
882
,
883
,
884
,
885
Unfortunately, because the esophagus is broad, the lateral position of the temperature
probe or mapping electrode might not align with the ablation electrode, and the operator
could receive a false impression of safety.
1398
There is general agreement among those operators who employ temperature probes that
an increase in esophageal temperature should trigger interruption of RF energy delivery.
Three-quarters of the writing group members terminate ablation if they observe a 1 °C
or 2 °C rise in temperature from baseline, or a recorded temperature of 39 °C–40 °C.
During CBA, two-thirds of the writing group members monitor esophageal temperature,
and terminate cooling if the esophageal temperature reaches 20 °C–25 °C. A variety
of esophageal temperature probes are available for clinical use.
886
A recent study has shown the superior thermodynamic profile of multisensor esophageal
recording systems; however, no clinical trial has demonstrated superiority in terms
of reducing AEFs.
646
,
647
This type of study would be impossible to perform due to the very low event rate of
this complication. Among the writing group members who employ esophageal temperature
monitoring, single thermocouple probes are used by two-thirds and multithermocouple
probes are employed by one-third. The potential benefit of multithermocouple probes
must be weighed against their increased complexity and cost.
886
,
887
,
888
,
889
The writing group recommends that it is reasonable to use an esophageal temperature
probe during RF ablation procedures to monitor esophageal temperature to help guide
energy delivery (Class IIa, LOE C-EO, Table 3
).
Another strategy to protect the esophagus uses active cooling.
890
,
891
,
892
,
893
This technique has not been tested on a large scale, and the data describing this
technique are limited. Selected operators use mechanical displacement of the esophagus.
894
,
895
This technique appears to be promising, but its use has been limited to a small number
of patients and is therefore an unproven approach.
Pharmacological Prophylaxis
Esophageal ulcers are found in a 5%–40% of patients following AF ablation. It is hypothesized
that AEF occurs because there is transmural necrosis of both the atrium and esophagus
with subsequent ulcer erosion from gastroesophageal reflux.
896
,
897
To prevent ulcer erosion, proton pump inhibitors (PPIs) have been employed, and are
used by 65% of the writing group members after ablation. PPIs are highly effective
in gastroesophageal reflux disease by reducing the acidity of the gastric juice and
healing esophagitis.
898
,
899
,
900
PPIs are effective in reducing the size of iatrogenic-induced ulcers, therefore could
also be helpful for ablation-induced ulcers.
901
Other mechanisms, such as traumatic injury of the esophageal wall, could also play
a potential role in fistula formation, although there is no proof of this concept.
Prophylactic short-term use of PPIs after AF ablation is assumed to be effective;
however, further large randomized studies are required to determine whether PPIs reduce
AEFs. Because of the low event rate of AEFs, such a study will not likely be performed.
At the moment, PPI therapy is justified as a singular preventive treatment.
Role and Indications for Endoscopic Screening for Ulceration Following AF Ablation
Because AEF can cause septicemia and air embolism leading to death, early detection
of esophageal tissue injuries is essential. Data evaluating the role of gastrointestinal
endoscopy for detection of esophageal tissue lesions are limited. In 185 patients
who underwent gastrointestinal endoscopy after LA RF ablative therapy, ulcer-like
or hemorrhagic esophageal thermal lesions (diameter: 2–16 mm) were observed in 14.6%
of the patients.
902
These lesions only occurred when the intraluminal esophageal temperature had reached
more than 41 °C. The odds of an esophageal lesion increased by a factor of 1.36 (95%
CI 1.07–1.74; P = .012) for every 1 °C rise in temperature.
Gastrointestinal endoscopy in a cohort of 425 patients 1 to 3 days after AF catheter
ablation, in whom intraluminal esophageal temperatures higher than 41 °C were recorded,
revealed esophageal tissue lesions in 11.6% of asymptomatic patients.
903
Hence, these observations suggest that asymptomatic patients could benefit from routine
gastrointestinal endoscopy after RF catheter ablative therapy when the intraluminal
esophageal temperature during the procedure has reached a certain target temperature,
such as 41 °C. However, there are no reports on the value of this type of follow-up
endoscopic examination after ablative therapy. Only one study did a follow-up endoscopy
at least 7 days after the first examination in patients with an esophageal lesion
diameter >5 mm and found regression of all 3168 lesions.
903
A PPI was used in all the patients for 4 weeks after ablation.
Role and Indications for CT Imaging for Diagnosis of Atrioesophageal Fistula
After ablation, symptoms and findings suggesting the possibility of evolving AEF include
chest pain, painful swallowing, fever, leukocytosis, TIA, and/or stroke typically
occurring between 1 and 3 weeks postablation. If esophageal injury is suspected, CT
imaging with intravenous and water-soluble oral contrast is recommended.
904
,
905
,
906
Findings on CT imaging on an AEF include mediastinal or pericardial free air, evidence
of free communication between the esophagus and pericardium or atrium, and inflammatory
phlegmon between the esophagus and the heart. Unfortunately, these CT findings are
usually observed late in the progression of AEF. The appearance of the CT scan early
in the course of this complication can be entirely normal. If esophageal injury postablation
is suspected, but if the CT scan is normal, the physician must continue to have a
high index of suspicion and repeat imaging if symptoms or findings do not resolve.
Esophageal ultrasound can also be useful in this setting to disclose muscle and external
injury, beyond a simple ulcer. Although a barium swallow can detect a fistula, its
sensitivity is low. If an AEF is suspected, endoscopy with air insufflation should
be avoided, given that insufflation of the esophagus with air can result in a large
air embolus, producing stroke or death. An alternative strategy, which some members
of the writing group employ and which appears to have lower risk is to use CO2 instead
of air for insufflation in this setting. If CO2 were introduced into the LA, there
would be little adverse consequence. The early recognition of an AEF can be missed
due to the low awareness of this rare complication. It is important for patients to
be educated as to warning signs and to contact their AF ablation center should any
suggestive symptoms develop.
Management of Atrial Esophageal Fistula
The management of AEF following catheter ablation for AF includes preventive measures
and therapeutic options. If AEF is diagnosed, available therapeutic options are as
follows:
surgical repair of the fistula via thoracotomy (combined LA and esophageal repair
with an intercostal muscle flap inserted in between to prevent future recanalization
of the fistula tract) via thoracotomy;
the less invasive esophageal stenting, followed by long-term antibiotic therapy; and
conservative management with aggressive chest tube drainage and treatment of sepsis.
341
,
417
,
907
,
908
,
909
,
910
,
911
Of the above three, conservative treatment of AEF is associated with a high mortality
rate.
907,1398
Similarly, with esophageal stenting, earlier studies have reported fatality in the
majority and survival in very few only after undergoing emergency surgical repair.
341
,
417
,
896
,
897
,
907
,
910
,
911
,
912
,
913
,
914
,
1398
Mixed results have also been shown for surgical repair of AEF complicating RFCA, some
with positive outcome and others with fatal ending.
341
,
417
,
910
,
911
However, the only reported survival in patients thus far underwent surgical fistula
repair, and failure of surgery has been mostly attributed to delay in diagnosis and
intervention.
341
,
417
,
910
,
911
Thus, based on currently available clinical information, it is apparent that early
surgical intervention is critical for survival in AEF manifesting as a complication
of AF ablation. Of note, there are few reports on successful resolution of the fistula
with stenting in patients with cardioesophageal (connecting to CS) and esophagopericardial
fistula.
905
,
915
,
916
In cases of perforation (not thermal injury) before the fistula has formed, closure
with stent or endoscopic clip can be considered.
917
,
918
,
919
Summary
Although all of the approaches described above for the prevention of AEF have been
variously adopted by different ablation centers, each remains largely unproven due
to the rarity of an AEF as a complication. Among the writing group members, 67% employ
an esophageal temperature probe (single thermocouple for two-thirds, multiple thermocouple
for one-third), 36% use 3D image integration and import the esophagus location into
the electroanatomical map, 91% decrease RF power when ablating on the posterior wall
of the atrium, 7% use barium paste, and none (0%) mechanically displace the esophagus.
Among the writing group members, 30% limit power to ≤ 20 W on the posterior wall,
45% limit it to 25 W, 18% to 30 W, and 7% use powers of > 30 W. The writing group
recommends that it is reasonable to use an esophageal temperature probe during RF
ablation procedures to monitor esophageal temperature and to help guide energy delivery
(Class IIa, LOE C-EO, Table 3
). The writing group recommends that RF power be reduced when creating lesions along
the posterior wall near the esophagus (Class I, LOE C-LD, Table 3
).
Despite its rarity, the devastating consequences of AEF demand that the operator maintain
a high index of suspicion for this diagnosis. Presenting symptoms, including fever,
dysphagia, and neurological deficits, often occur in the several weeks after the procedure.
918
Therefore, early signs of these symptoms should be reported by patients to their treating
electrophysiologist to avoid the delayed diagnosis.
908
If AEF is suspected, standard transesophageal endoscopy should be avoided, because
esophageal perforation can be exacerbated and air embolism promoted by required air
insufflation. An alternative strategy, which some members of the writing group employ
and which appears to have lower risk is to use CO2 instead of air for insufflation
in this setting. If CO2 were introduced into the LA, there would be little adverse
consequence. In patients diagnosed with an AEF, surgical treatment is recommended.
Section 8: Follow-up Considerations
Monitoring for Complications in the First Months After AF Ablation
AF ablation is an invasive procedure that entails risks, most of which are present
during the acute procedural period. However, complications can also occur in the weeks
or months following ablation.
920
,
921
,
922
Recognizing common symptoms after AF ablation and distinguishing those that require
urgent evaluation and referral to an electrophysiologist is an important part of follow-up
after AF ablation. Symptoms and complications can be divided into those that occur
immediately after ablation (0–3 days), early (1–4 weeks), and those that can occur
late (>4 weeks) after ablation.
Signs and Symptoms of Complications Within 1 Month Postablation
Shown in Table 5
is a list of signs and symptoms that can occur within the first several months following
ablation. These signs and symptoms are divided into those that occur within 30 days
of AF ablation and those that occur more than 30 days postablation. Some complications,
such as a stroke or development of an AEF, might present within the first month or
following the first postablation month and therefore are listed in both sections of
this table. The differential diagnosis, which should be considered, as well as the
recommended evaluation, are also shown. AF ablation is often performed under general
anesthesia. Some patients might feel fatigued for several days after prolonged general
anesthesia. Mechanical complications from endotracheal intubation and transesophageal
echocardiography, such as hoarseness and difficulties swallowing, might also occur
and typically resolve with time.
Table 5
Signs and symptoms following AF ablation
Differential
Suggested evaluation
Signs and symptoms of complications within a month postablation
Back pain
Musculoskeletal, retroperitoneal hematoma
Physical exam, CT imaging
Chest pain
Pericarditis, pericardial effusion, coronary stenosis (ablation related), pulmonary
vein stenosis, musculoskeletal (after cardioversion), worsening reflux
Physical exam, chest X-ray, ECG, echocardiogram, stress test, cardiac catheterization,
chest CT
Cough
Infectious process, bronchial irritation (mechanical, cryoballoon), pulmonary vein
stenosis
Physical exam, chest X-ray, chest CT
Dysphagia
Esophageal irritation (related to transesophageal echocardiography), atrioesophageal
fistula
Physical exam, chest CT or MRI
Early satiety, nausea
Gastric denervation
Physical exam, gastric emptying study
Fever
Infectious process, pericarditis, atrioesophageal fistula
Physical exam, chest X-ray, chest CT, urinalysis, laboratory blood work
Fever, dysphagia, neurological symptoms
Atrial esophageal fistula
Physical exam, laboratory blood work, chest CT or MRI; avoid endoscopy with air insufflation
Groin pain at site of access
Pseudoaneurysm, AV fistula, hematoma
Ultrasound of the groin, laboratory blood work; consider CT scan if ultrasound negative
Headache
Migraine (related to anesthesia or transseptal access, hemorrhagic stroke), effect
of general anesthetic
Physical exam, brain imaging (MRI)
Hypotension
Pericardial effusion/tamponade, bleeding, sepsis, persistent vagal reaction
Echocardiography, laboratory blood work
Hemoptysis
PV stenosis or occlusion, pneumonia
Chest X-ray, chest CT or MR scan, VQ scan
Neurological symptoms
Cerebral embolic event, atrial esophageal fistula
Physical exam, brain imaging, chest CT or MRI
Shortness of breath
Volume overload, pneumonia, pulmonary vein stenosis, phrenic nerve injury
Physical exam, chest X-ray, chest CT, laboratory blood work
Signs and symptoms of complications more than a month postablation
Fever, dysphagia, neurological symptoms
Atrial esophageal fistula
Physical exam, laboratory blood work, chest CT or MRI; avoid endoscopy with air insufflation
Persistent cough, atypical chest pain
Infectious process, pulmonary vein stenosis
Physical exam, laboratory blood work, chest X-ray, chest CT or MRI
Neurological symptoms
Cerebral embolic event, atrial esophageal fistula
Physical exam, brain imaging, chest CT or MRI
Hemoptysis
PV stenosis or occlusion, pneumonia
CT scan, VQ scan
AF, atrial fibrillation; ECG, electrocardiogram; CT, computed tomography; MRI, magnetic
resonance imaging; VQ, ventilation-perfusion.
Tenderness at the vascular access sites is common; hematomas present after sheath
removal will typically extend inferiorly (due to gravity) and might result in extensive
ecchymosis after ablation. Prompt ultrasound Doppler investigation should be performed
if an AV fistula or pseudoaneurysm is suspected. Worsening of back or buttock pain
is also common from prolonged supine positioning during the procedure. However, more
severe back pain or flank ecchymosis should prompt an evaluation for retroperitoneal
hematoma with CT imaging. Significant bleeding into the leg can also result in compartment
syndrome.
Shortness of breath soon after ablation might have several causes. The patient should
be examined after ablation for evidence of volume overload related to irrigated ablation
and diuresed as necessary. Volume overload can be observed in patients with normal
or reduced cardiac function, perhaps due to atrial stunning. If dyspnea persists or
occurs in the absence of volume overload, a chest X-ray should be obtained to exclude
an infectious process or elevation of the respective hemi-diaphragm. PN injury most
commonly occurs after balloon-based ablation, but can also occur after RF ablation.
503
Lack of diaphragmatic movement during inspiration under fluoroscopy (the sniff test)
is diagnostic of PN injury. Right PN injury is much more common after AF ablation
and is due to ablation near the RSPV or SVC (Figure 1
). Left PN injury less commonly occurs when ablating near the LAA. Although most cases
of phrenic injury recover with reinnervation over a 6–12 month period after ablation,
permanent diaphragmatic paralysis has been reported.
Chest pain is common after ablation; the causes include pericarditis, coronary ischemia,
and musculoskeletal pain. Symptoms of pericarditis (pleuritic chest pain) are the
most common (>75% of patients) and typically persist for up to a week postablation.
In the absence of evidence of hemodynamic compromise, an ECG is of little value. It
is important to recognize that nearly all patients will demonstrate a small pericardial
effusion following AF ablation as a result of edema. Nonsteroidal anti-inflammatory
agents are recommended for symptom control. Colchicine can also be used to treat pericardial
symptoms. Oral steroids should be avoided after catheter ablation unless pericardial
symptoms persist or are recurrent. Chest pain that is associated with ECG changes
or that occurs with exertion should prompt evaluation of coronary ischemia. In particular,
if ablation has been performed inside the CS to target the epicardial portion of the
mitral isthmus, or for isolation of a CS tachycardia, circumflex artery stenosis should
be considered.
923
Any unexplained hypotension during or following ablation should be evaluated promptly.
Transthoracic echocardiography or ICE (if during ablation) should be performed urgently
to exclude pericardial effusion or cardiac tamponade. A complete blood count should
be performed to exclude bleeding or infection.
Fever might occur early after ablation. We should exclude infectious sources such
as a urinary tract infection related to bladder instrumentation or pneumonia related
to intubation. Low-grade fever might also be related to pericarditis. In addition,
fever might be the first marker of an impending AEF formation. Chest imaging should
be considered if fever persists, an AEF is suspected, and no other clear infectious
source is identified.
Any neurological symptoms occurring shortly after ablation should be taken seriously,
with brain imaging performed to exclude an embolic event. Migraine-like signs and
symptoms have been reported and are most commonly benign and are attributed to the
residual ASD following transseptal puncture. As noted above, an AEF might also present
with neurological symptoms. It is also important to recognize that an AEF might present
as a neurological event and therefore must be considered the differential diagnosis
of neurological symptoms that develop post AF ablation.
Symptoms of pericarditis typically persist up to a week after ablation (Table 5
). If symptoms persist for >1 week or are associated with lightheadedness or shortness
of breath, further evaluation is warranted. Groin pain that persists past 7 days or
is getting worse should prompt a physical exam and vascular ultrasound to exclude
femoral access complications. A persistent nagging dry cough might also be observed
for up to 6 weeks after ablation. This complication is more common with CB than with
RF ablation and is likely related to direct bronchial or lung injury. This type of
cough is generally treated with antitussives and will typically subside over 4–6 weeks.
Some patients, particularly those with a history of migraines, might experience migraine
headaches in the first few weeks after ablation.
924
,
925
These headaches might be related to the residual ASD present after transseptal puncture
and will typically improve over several weeks. Hemoptysis is rare but might result
from pneumonia or pulmonary infarction due to an occluded PV, typically occurring
3–6 months after ablation. Dysphagia in the first days after ablation is most likely
related to irritation from transesophageal echocardiography or intubation. If dysphagia
persists, then imaging (chest CT or MRI) should be performed to exclude an AEF (see
late complications). The differential diagnosis of dyspnea occurring early after ablation
should include volume overload, pneumonia, or PN injury as outlined above. A chest
roentgenogram should be obtained. If symptoms persist with a normal chest roentgenogram,
we should also consider PV stenosis (see late symptoms, below). Vagal denervation
of the esophagus or stomach can occur after ablation due to ablation lesions placed
in the vicinity of the esophagus, particularly if extensive ablation is performed
along the LA posterior wall.
536
,
926
Symptoms can include nausea and early satiety. Patients should be advised to eat small,
frequent meals. Symptoms will typically improve over 4–6 weeks. If symptoms are profound
or persist, a gastric emptying study can be diagnostic. Pain at the site of sheath
insertion can result from an pseudoaneurysm, an AV fistula, or a hematoma. Evaluation
usually starts with a vascular ultrasound. Bloodwork and a CT scan might be appropriate.
Signs and Symptoms of Complications More Than a Month Postablation
Late symptoms of dysphagia and/or fever, particularly in the presence gastrointestinal
bleeding or any neurological symptoms, should prompt an urgent evaluation for an AEF,
a rare but potentially lethal complication after AF ablation (see Section 10).
341
,
417
,
866
,
910
If AEF is suspected, esophagogastroduodenoscopy should not be performed, because increased
pressure in the esophagus can lead to the introduction of air into the LA and stroke.
Imaging with CT or MR is preferred, with the presence of air in the mediastinum or
LA considered diagnostic. Although barium should not be introduced into the esophagus,
a small amount of water-soluble contrast can help identify the location of the fistula.
The recommended treatment for AEF at any stage is surgical exploration and resection
of the fistulae, typically requiring resection of the involved esophagus and repair
of the posterior LA wall with a pericardial patch. There have been reports of treatment
of early fistulae with covered esophageal stents; however, surgical treatment is generally
preferred. A persistent cough >6 weeks after ablation, particularly if associated
with atypical chest pain, recurrent pneumonia or hemoptysis, should prompt an evaluation
for PV stenosis.
927
,
928
A chest roentgenogram might also show evidence of atelectasis or infiltrate localized
to one lobe of the lung, which is typically related to focal pulmonary edema. Many
patients have received repeated courses of antibiotics for lung infection before the
correct diagnosis is reached. If PV stenosis is suspected, a chest contrast CT angiogram
or MR angiogram should be performed to examine PV anatomy and exclude PV stenosis
or occlusion. If PV stenosis or occlusion is detected, a ventilation or perfusion
scan is typically performed to quantify lung perfusion. Referral to a center with
expertise in PV stenting should be recommended early in the course of PV stenosis,
because dilatation is more difficult and has a higher incidence of pulmonary hypertension,
lung infarct, and hemoptysis once high grade stenosis has occurred (see Section 10:
Complications). Hemoptysis should trigger an evaluation for PV stenosis and usually
indicates the presence of complete branch or PV occlusion. Other late complications
include a stroke or embolic event related to recurrent AF or deep vein thrombosis
or pulmonary embolus related to femoral vein instrumentation. These complications
are uncommon because anticoagulation is typically reinstated after ablation.
ECG Monitoring Pre- and Postablation
Arrhythmia monitoring is an important component of the initial evaluation of patients
who are to undergo catheter ablation procedures for AF. Prior to undergoing a catheter
ablation procedure, it is important to confirm that a patient's symptoms result from
AF and to determine whether a patient has paroxysmal or persistent AF. The choice
of ablation technique, expectations with respect to the procedure's outcome, anticoagulation
strategies employed, and the need for TEE prior to the procedure might be impacted
by the accurate characterization of the AF type and burden. Preprocedure arrhythmia
monitoring is also useful to determine whether a patient has evidence of regular supraventricular
tachycardia that degenerates into AF as a triggering mechanism or has a pattern of
repetitive “focal firing,” characterized by the presence of frequent atrial premature
beats (>1000 per 24 hours) with frequent rapid salvos of nonsustained AT.
458
Focal AF is characterized by localized triggers arising from the PVs.
929
Either of these triggering patterns of AF initiation identifies a patient in whom
a more limited ablation, targeted at only the triggering arrhythmia focus or PV(s)
might be appropriate.
406
,
458
,
930
An assessment of the adequacy of heart rate control is particularly important in patients
with depressed left ventricular function who might show evidence of a reversible tachycardia-induced
cardiomyopathy.
234
ECG monitoring also plays an important role in the follow-up after an ablation procedure.
Early recurrences of AF are common during the first 3 months following a catheter
ablation procedure.
931
,
932
For this reason, arrhythmia monitoring to assess the efficacy of catheter ablation
is typically delayed for at least 3 months following catheter ablation unless required
to evaluate arrhythmia symptoms during the early postablation period. However, recurrences
particularly after the first month following an ablation procedure are predictive
of later recurrence of AF, and therefore monitoring may be used to identify patients
at higher risk of needing a second ablation procedure or ongoing AAD therapy.
272
,
329
,
933
,
934
,
935
The two main reasons to perform arrhythmia monitoring following catheter ablation
are clinical care and as part of a clinical research trial. From a purely clinical
perspective, arrhythmia monitoring is useful to determine whether a patient's complaints
of palpitations result from recurrent AF or other ATA. Complaints of palpitations
often result from atrial or ventricular premature beats and are not an accurate predictor
of recurrent AF.
57
,
936
Arrhythmia monitoring can also be of value in asymptomatic patients and can influence
decision making regarding anticoagulant therapy after ablation. Multiple studies have
demonstrated that asymptomatic AF commonly occurs in patients following catheter ablation.
56
,
57
,
63
,
413
,
442
,
936
,
937
,
938
Detection of these asymptomatic episodes of AF impact the characterization of the
procedure as “successful.” Arrhythmia monitoring is an essential component of clinical
trials aimed at assessing the outcomes of catheter ablation procedures and should
be incorporated into all clinical trials designed to assess the efficacy of AF catheter
ablation tools and techniques. The suggested monitoring strategies and minimum standards
to be used as part of clinical trials are discussed in Section 13: Clinical Trial
Design. These strategies and standards can be useful in tracking the outcome of clinical
care when assessing an institution's performance standards related to success and
complications of AF ablation procedures. However, it is recognized that clinical endpoints
and clinical trial secondary endpoints for defining success can include the elimination
of symptomatic AF and control of AF with previously ineffective AADs after the AF
ablation procedure.
Available Methods for Arrhythmia Monitoring
Use of ECG monitoring tools is essential to assess AF ablation success, and the monitored
results can have important implications in terms of clinical care and research outcomes.
Arrhythmia monitoring can be performed with the use of noncontinuous or continuous
ECG monitoring tools (Table 6
). The choice of either method depends on individual needs and the consequences of
arrhythmia detection. More intensive monitoring is associated with a greater likelihood
of detecting both symptomatic and asymptomatic AF.
57
,
414
,
937
,
938
,
939
,
940
,
941
,
942
,
943
,
944
The proportion of asymptomatic compared with symptomatic events might be higher after
AF ablation; two studies reported that the proportion of AF events that were asymptomatic
was 11%–35% prior to and 53%–65% after ablation.
63
,
945
,
946
Another study reported that for patients in sinus rhythm, 53.8% of AF episodes were
asymptomatic, with an increase in asymptomatic episodes changing from the acute to
the chronic period after ablation, demonstrating that AF success cannot be based on
the absence of symptoms alone.
936
Table 6
Types of ambulatory cardiac monitoring devices
Type of recorder
Typical monitoring duration
Continuous recording
Event recording
Auto trigger
Unique features
Holter monitor
24–48 hours, approximately 7–30 days
Yes
Yes
N/A
Short term, provides quantitative data on arrhythmia burden
Patch monitor
1–3 weeks
Yes
Yes
N/A
Intermediate term, can provide continuous data for up to several weeks; improved patient
compliance without lead wires
External loop recorder
1 month
Yes
Yes
Variable
Good correlation between symptoms and even brief arrhythmias
External nonloop recorder
Months
No
Yes
No
May be used long term and intermittently; will not capture very brief episodes
Smartphone monitor
Indefinite
No
Yes
No
Provides inexpensive long-term intermittent monitoring; dependent on patient compliance;
requires a smartphone
Mobile cardiac telemetry
30 days
Yes
Yes
Yes
Real time central monitoring and alarms; relatively expensive
Implantable loop recorder
Up to 3 years
Yes
Yes
Yes
Improved patient compliance for long-term use; not able to detect 30-second episodes
of AF due to detection algorithm; presence of AF needs to be confirmed by EGM review
because specificity of detection algorithm is imperfect; expensive
Pacemakers or ICDs with atrial leads
Indefinite
Yes
Yes
Yes
Excellent AF documentation of burden and trends; presence of AF needs to be confirmed
by electrogram tracing review because specificity of detection algorithms is imperfect;
expensive
Wearable multisensor ECG monitors
Indefinite
Yes
Yes
Yes
ECG 3 leads, temp, heart rate, HRV, activity tracking, respiratory rate, galvanic
skin response
AF, atrial fibrillation; ICD, implantable cardioverter defibrillator; ECG, electrocardiogram;
HRV, heart rate variability.
The identification of AF and the assessment of AF burden with intermittent monitoring
have been shown to depend on a patient's actual AF burden and improve with an increasing
frequency or duration of intermittent monitoring.
943
,
947
,
948
,
949
Conversely, the more complex and longer the method of monitoring used, the lower the
patient compliance.
Traditional AF detection tools for intermittent monitoring after AF ablation include
scheduled or symptom-initiated standard ECGs, Holter monitors, patient-activated and
automatically activated full disclosure external loop recorders, and transtelephonic
recordings. More recently, implanted loop recorders and external recordings with wireless
connection via smartphone applications have been used for longer-term monitoring to
detect AF after ablation.
The intermittent, scheduled use of continuous short-term ECG monitors after AF ablation
has utilized traditional Holter monitors and more recently patch ECG monitors. Holter
monitors use single- or multi-lead external recorders connected via wires to small
recording devices. Typical Holter monitors record 2 or 3 channels for 24–48 hours,
but some can record continuous 12-lead ECGs or for periods of 7–30 days. Patients
can record symptoms on a diary and/or by activating an event button. Because Holter
monitors are analyzed by trained technicians and are read by experienced physicians,
these approaches might represent the standard monitoring method against which other
methods should be compared. Newer wearable patch ECG monitors record from closely
spaced electrodes, removing the need for wires and typically generating up to 2 channel
recordings. These are water resistant, wearable for up to 30 days, and have enjoyed
superior patient acceptance over conventional wired monitor systems. Symptoms can
be recorded by an event button. Future devices are being developed with multiple sensors
that can record body temperature, activity, respiratory rate, and galvanic skin responses.
Patient- or event-activated external loop recorders can be used for longer or intermediate
duration monitoring, typically over weeks to months.
254
These memory loop recorders can be programmed to record ECGs for seconds to minutes
before and after the detection of an arrhythmia or a patient-triggered event and thus
can detect and correlate rhythms with even brief symptoms. External loop recorders
should be worn continuously to capture such events and typically are connected via
wires to skin electrodes.
Nonloop external event recorders can be used for intermittent transtelephonic recordings
that can be initiated by patients with symptoms or on a schedule. These recorders
are applied to the chest or held by hand. Older conventional transtelephonic monitors
required the recording of rhythm strips while connected in real time over the phone,
but more recent monitors allow the storage of rhythm strips with transmission at a
later time. Event recording occurs after an event is detected by the patient; the
diagnostic yield is dependent on the recognition of symptoms, the duration of symptomatic
episodes, or on scheduled or more frequent use to detect asymptomatic arrhythmias.
More recently, smartphone-based ECG monitors have been developed that can be helpful
for long-term intermittent surveillance.
950
,
951
Recordings from electrodes embedded in a smartphone case or a card are connected via
low-energy Bluetooth technology to smartphone applications. These monitors are nonlooping;
patients can record during symptoms that persist long enough to activate the application.
Recordings are stored and can be transmitted via wireless or cellular networks. In
a study conducted after AF ablation, a smartphone-based single-lead system was compared
to transtelephonic monitor ECGs with 100% sensitivity and 97% specificity in detecting
AF or flutter.
951
Multi-lead and reconstructed 12-lead recording devices are being developed, but have
not been studied in the setting of AF ablation. Continuous ECG monitoring technology
using such applications are also in development.
Mobile cardiac outpatient telemetry devices provide real-time monitoring and wireless
transmission to trained personnel at a central monitoring center with activation of
alarms to caregivers for specified significant arrhythmias. These monitors are typically
worn continuously for a period of 2–4 weeks and can record 1–3 leads connected to
a small device via conventional wires or embedded in a patch. The advantage of these
systems is their ability to capture and identify potentially severe or significant
arrhythmias in an immediate or timely fashion.
Continuous ECG monitoring for longer periods (1–3 years) can be facilitated with the
use of implantable devices. Long-term subcutaneous implantable loop monitors can facilitate
continuous AF monitoring based on R-R interval analysis over a time period of up to
3 years.
952
,
953
These types of continuous ECG monitoring devices have been used in several studies
to evaluate the results of surgical or catheter AF ablation.
127
,
607
,
938
,
953
,
954
,
955
,
956
,
957
,
958
,
959
,
960
,
961
Although implantable subcutaneous monitors hold promise for the determination of AF
burden in the long term, AF detection algorithms are primarily based on R-R interval
regularity, and important limitations include reduced specificity due to undersensing
of beats, oversensing of myopotentials, and irregular atrial and ventricular premature
beats, as well as limited memory resulting in electrograms not being retrievable to
verify the correct rhythm diagnosis.
941
,
944
,
962
Nevertheless, implantable continuous monitors can ameliorate patient compliance issues
and provide an assessment of long-term AF burden and late recurrences, including asymptomatic
episodes that might have implications for continuation of anticoagulation. In one
study after concomitant surgical ablation, ILRs compared with conventional Holter
monitoring facilitated more follow-up antiarrhythmic management, including cardioversions
and catheter ablation procedures, which were associated with a trend toward higher
sinus rhythm rates at 1 year.
942
Implantable pacemakers or defibrillators with atrial leads allow the burden of AF
to be assessed by tracking the number and duration of mode-switch episodes.
963
,
964
These devices can also assess long-term AF burden, burden trends, and late or asymptomatic
recurrences.
940
,
965
,
966
The ability to record intracardiac atrial electrograms provides excellent sensitivity
and specificity for the diagnosis of atrial arrhythmias, especially with durations
exceeding a few minutes.
937
,
967
,
968
Follow-up and Monitoring Guidelines for Routine Clinical Care
There is a consensus among the writing group members that all patients who undergo
catheter ablation of AF, regardless of whether they are enrolled in a clinical trial,
should be seen in follow-up a minimum of 3 months following the ablation procedure.
There is also consensus that all patients who undergo catheter ablation should be
seen by some type of physician (family physician, internist, cardiologist, or electrophysiologist)
on an annual basis thereafter. These ongoing interactions with the medical profession
allow the patient's clinical status to be evaluated, including an assessment of the
presence or absence of AF as well as their stroke risk profile and anticoagulation
needs. These interactions also provide an opportunity to focus on the treatment of
associated diseases and lifestyle modifications. These recommendations are slightly
modified from the previous edition of this document, which advised that all patients
who undergo catheter ablation of AF, regardless of whether they are enrolled in a
clinical trial, should be seen in follow-up at a minimum of 3 months following the
ablation procedure, and then every 6 months for at least 2 years. A 12-lead ECG was
recommended at all follow-up visits and more intense monitoring driven mainly by the
clinical impact of AF detection with strict monitoring necessary (suspected rate-related
cardiomyopathy). This modification of our writing group recommendations reflects,
in part, data from real life clinical practice.
969
This European study revealed that one-third of the 12-month follow-up evaluations
were performed by telephonic contact, only 87.2% of the patients had at least one
ECG during the follow-up, and the patients with continuous monitoring of ≥ 24 hours
(Holter- or implanted monitoring systems) represented only 57.4% of the population.
Explanations of this gap between prior expert consensus recommendations and routine
clinical practice might reflect the current disconnect between indications for catheter
ablation and clinical outcomes of the procedure. Another factor can be cost. On one
hand, the main indication for catheter ablation is symptomatic AF and decisions regarding
continuation of anticoagulation therapy should be based on the patient's risk factors
for stroke and not on the presence of or type of AF. At the same time, transtelephonic
or long-term monitoring is at times recommended after ablation to capture even asymptomatic
episodes of AF to evaluate the need to continue anticoagulation. The majority of writing
group members do not believe that data currently exist to support this common practice
of making decisions regarding anticoagulation based on the presence or absence of
AF (see Section 7).
A significant amount of information has accumulated showing that cardiac risk factors
such as obesity, sleep apnea, and hypertension are associated with structural and
electrical remodeling of the atria, which forms the substrate leading to AF development
and progression (see Section 3). The recommended indefinite annual follow-up visits
with a health care professional allow for the evaluation and treatment of associated
diseases and lifestyle modification rather than monitoring of the rhythm itself.
Early Recurrence After Ablation
Definition and Incidence
Early recurrences of AF after AF ablation has been defined as any recurrence of AF > 30 seconds
during the first 3 months of follow-up. Late recurrence has been defined as any recurrence
of AF > 30 seconds between 3 and 12 months after AF.
141
,
142
,
143
In using the term early recurrence of AF (ERAF) it is recognized that the early recurrence
might be AFL or AT. Although we considered defining a new term, early recurrence of
ATAs, post-AF ablation, for simplicity we have employed the term early recurrence
of AF. Throughout the document and this section of the document, we note that recurrences
can present in the form of AF, flutter, or tachycardia.
Early recurrences of AF after RF catheter ablation have been reported in up to 50%
of patients within the first 3 months of AF ablation.
253
,
329
,
436
,
684
,
932
,
935
,
970
,
971
,
972
Because these arrhythmias do not definitively indicate therapy failure over the long
term (only half of these patients will manifest later recurrences), this period is
also referred to as the blanking or therapy stabilization period.
935
,
973
It is also important to recognize that the later AF recurrences are observed during
the blanking phase, the lower the chance of long-term success.
935
Causes of Recurrences
The pathophysiological mechanisms of these early recurrences are attributed to various
mechanisms: primarily incomplete isolation of the PVs,
973
,
974
acute inflammatory changes owing to energy delivery,
755
recovery of conduction in a previously isolated PV,
448
,
622
,
975
modification of the ANS, changes in the atrial substrate, and delayed effect of RF
ablation due to lesion consolidation.
257
,
258
Early Recurrence as a Predictor of Failure
The occurrence of atrial arrhythmias early after ablation does not necessarily indicate
treatment failure later during follow-up.
974
Nevertheless, early recurrences have been shown to predict arrhythmia recurrences
late after catheter ablation of AF in some patients.
260
,
329
,
935
,
976
,
977
,
978
Management of early recurrences is controversial and has been treated by AADs, corticosteroids,
early cardioversion, or repeat catheter ablation.
Antiarrhythmic Drugs
Because early AF recurrence usually peaks within the first few weeks following PVI,
the temporary routine administration of AADs in the immediate postablation period
has been proposed as a potential preventive strategy.
1
,
979
Although the true efficacy of this approach is unknown, studies have suggested that
transient AAD use does not prevent late arrhythmia relapses.
935
,
980
The 5A study randomized 110 consecutive patients with PAF undergoing ablation to empirical
AAD therapy vs no AAD therapy for the first 6 weeks after RF catheter ablation.
980
The authors noted a significantly lower incidence of clinically significant atrial
arrhythmias (AF > 24 hours or associated with severe symptoms), cardioversions, and
arrhythmia-related hospitalization during the 6-week treatment period (13% vs 28%
in the AAD vs non-AAD group; P <.05); however, there was no difference in the 6-month
freedom from recurrent AF (72% vs 68%; P = .84).
980
As noted earlier in this document, the writing group also recognizes that the usefulness
of initiation or discontinuation of AAD therapy during the postablation healing phase
in an effort to improve long-term outcomes is unclear (Class IIb, LOE C-LD, Table
3
).
Corticosteroids
Given the association between AF recurrence and RF-induced inflammation, it has been
postulated that empiric pretreatment with high-dose corticosteroids could reduce the
incidence of ERAF and long-term recurrence. One study examined this hypothesis in
a population of 125 patients undergoing PV ablation for symptomatic PAF.
981
Corticosteroid therapy resulted in a significant reduction in the early AF recurrence
rate (27% vs 49% at 1 month with corticosteroids vs placebo, respectively), which
was driven by a marked reduction in the immediate recurrence rate (7% vs 31% within
72 hours, respectively). Interestingly, despite the lack of difference in the rate
of recurrence between 3 and 30 days (20% vs 18% in the corticosteroid and placebo
groups, respectively), the long-term freedom from AF without any AAD was significantly
higher in the corticosteroid group (85% vs 71% freedom from AF at 14 months, respectively).
Another study was published recently to evaluate the efficacy of corticosteroids to
prevent early and late recurrence. The authors enrolled 138 patients who were randomly
assigned to two groups (a steroid group and a control group). The primary endpoint
was ERAF during the blanking period (3 months postablation). During the blanking period,
51 of the 138 (37.0%) patients experienced ERAF after AF ablation. The steroid group
had a lower rate of ERAF than the control group (15 of 64 [23.4%] vs 36 of 74 [48.6%];
P =.003). There was no difference between the two groups in late recurrence during
a 24-month follow-up (log-rank test, P = .918). In a multivariate analysis, short-term
steroid therapy was independently associated with a lower rate of ERAF during the
blanking period (adjusted odds ratio [OR] 0.45; 95% CI 0.25–0.83; P = .01). The authors
concluded that periprocedural short-term moderate intensity steroid therapy reduces
early recurrence of ATA (approximately 3 months) after catheter ablation of AF; however,
it is not effective in preventing late (3–24 months) AF recurrence.
982
Additional information regarding optimum dosing, and safety and tolerability of corticosteroid
therapy post-AF ablation is needed before it can be recommended.
Colchicine
Colchicine, an anti-inflammatory agent, has been used post-AF ablation both to reduce
pericarditis-related pain, but also to reduce AF. Colchicine has been shown to reduce
postoperative AF following cardiac surgery,
983
,
984
and has also been studied following AF ablation. The first major study was a prospective
randomized trial in 161 patients undergoing ablation of PAF. Patients were randomized
to receive colchicine 0.5 mg bid or placebo.
985
At 3 months of follow-up, AF recurred in 34% of the placebo patients vs 16% of the
patients treated with colchicine. Colchicine led to a reduction in C-reactive protein
and IL-6. A subsequent randomized study of 233 patients with PAF demonstrated a long-term
recurrence rate of 31% among the patients treated with colchicine vs 49% among the
placebo patients.
986
A survey of the writing group members shows that 6% of the members routinely administer
colchicine for 1–3 months postablation. Ninety-four percent of the writing group members
do not routinely administer colchicine.
Cardioversion
Three studies examined long-term outcomes of patients who required cardioversion for
early recurrence of ATAs following RF catheter ablation. One study examined 55 patients
who underwent cardioversion 2.7 ± 1.4 months after the index procedure.
987
Sinus rhythm was restored in 39 of 45 patients with persistent AF (87%) and 9 of 10
patients (90%) with AFL (P = .77). After a mean follow-up of 15 ± 8 months postablation,
only eight patients (15%) remained completely free of AF in the absence of AAD therapy.
An additional 11 patients (20%) achieved partial success, as defined by a ≥ 90% reduction
in arrhythmia burden, whereas the remaining 36 patients (65%) were considered to have
failed ablation. Surprisingly, no differences were noted in acute efficacy or long-term
outcomes based on timing of cardioversion (e.g., cardioversion performed during or
following the 90-day blanking period).
987
Another study reported on outcomes of 384 consecutive patients undergoing AF ablation,
of whom 93 had cardioversion at a mean of 88 ± 72 days after ablation (74 for AF,
19 patients for AFL).
988
A mean of 16 ± 10 months after the index ablation procedure and 15 ± 10 months after
cardioversion, 25 of 93 patients (27%) remained free from recurrent atrial arrhythmias
in the absence of AAD therapy. In contrast to the earlier study, the patients in the
more recent study who underwent early cardioversion (within 30 days of arrhythmia
recurrence) were more than 20 times more likely to remain in sinus rhythm than patients
who were cardioverted after 30 days, regardless of the timing of recurrence or whether
concomitant AAD therapy was used. In those with a delayed cardioversion, only 2 of
47 patients (4%) remained in sinus rhythm without AAD therapy. In the multivariate
analysis, the time from atrial arrhythmia recurrence to cardioversion was the only
independent predictor of maintenance of sinus rhythm after a single ablation procedure
in the absence of an AAD (P <.001). Interestingly, these two studies reported similar
outcomes for patients who underwent cardioversion after 30 days, suggesting that if
a benefit is to be gained from early cardioversion, it must be performed within the
first month after arrhythmia recurrence. A larger study included consecutive catheter
ablations for AF.
989
Prompt electrical cardioversion was performed if AF or AFL was confirmed and sustained,
using a standard approach with the aim of performing cardioversion within 24 hours
of arrhythmia onset. Of the ablations performed, a total of 515 (29%; age: 65.6 ± 11.2 years;
male: 57.9%) developed AF or AFL that required cardioversion. The majority of these
arrhythmias first occurred in the initial 90 days (63.7%) postablation. During this
period, 62.8% were being treated with an AAD. Only 25.1% were using an AAD at 3 months.
The majority of patients postablation (75.6%) who experienced AF or AFL within the
first 90 days after ablation were in sinus rhythm, requiring no AAD at 1 year. Further,
48% of those patients with the first recurrence from 90 to 180 days were in sinus
rhythm with no AAD at 1 year. Thus, it appears that patients undergoing their first
cardioversion early after ablation (<3 months) were more likely to remain free from
arrhythmia at 1 year (75%).
989
An aggressive approach with early electrical cardioversion after LA catheter ablation
appears important to maintain sinus rhythm in order to minimize late arrhythmia recurrences,
reduce chronic AAD use, and prevent reablation procedures. When comparing an aggressive
rhythm control strategy with amiodarone and repetitive use of cardioversion vs amiodarone
and infrequent cardioversion in surgical RF ablated patients, systematic and repetitive
use of cardioversion resulted in a significantly higher portion of patients in sinus
rhythm during follow-up.
990
Although the development of a persistent atrial arrhythmia post-AF ablation is a sign
of poor prognosis, it is currently recommended to cardiovert those patients preferably
within 30 days of arrhythmia onset. Pathophysiological findings supporting rapid functional
and structural remodeling during AF encourage the clinician to cardiovert persistent
arrhythmias early post-AF ablation. However, the clinical data available supporting
this approach remain limited. The number of electrical cardioversions needed to treat
repetitive persistent AF recurrences postablation of persistent AF was investigated.
991
,
992
In this small trial of 40 patients, the number of electrical cardioversions ≥3 was
the only independent predictor of an ablation failure. Therefore, currently, reablation
should be considered in clinical practice after two cardioversions have been performed,
because of the high likelihood of recurrent arrhythmias.
Early Reablation
Performance of early reablation reduces the incidence of further recurrences, but
the overall number of procedures is higher in the medium-term follow-up. Two studies
evaluated the use of early reablation on long-term freedom from AF in patients with
ERAF.
141
,
142
,
143
,
989
,
993
In 302 consecutive patients with RF ablation for medically refractive AF, 151 experienced
an ERAF, 61 of whom underwent reablation within the first month (e.g., early reablation
group). The remaining 90 patients had a repeat procedure at least 1 month after the
index ablation. During a mean follow-up of 11 ± 11 months, patients with early reablation
had a lower rate of recurrences (51% vs 91%, P <.0001), symptomatic improvement, and
improved QOL. However, the total number of procedures required over the entire duration
of follow-up was greater in the patients who underwent early reablation (2.5 ± 0.7
vs 2.2 ± 0.6, P = .02).
993
The STOP-AF trial randomized 245 patients with PAF to medical therapy versus CB-based
PV ablation. Patients were followed for 12 months. Of the 163 patients randomized
to cryoablation, 84 patients experienced ERAF (51.5%). The only significant factor
associated with ERAF was male sex (HR 2.18; 95% CI 1.03–4.61; P = .041). Late recurrence
was observed in 41 patients (25.1%), and was significantly related to ERAF (55.6%
late recurrence with ERAF vs 12.7% without ERAF; P <.001). Among the patients with
ERAF, only current tobacco use (HR 3.84; 95% CI 1.82–8.11; P <.001) was associated
with late recurrence. Conversely, early reablation was associated with greater freedom
from late recurrence (3.3% late recurrence with early reablation vs 55.6% without;
HR 0.04; 95% CI 0.01–0.32; P = .002).
141
,
142
,
143
Although the clinical benefit of early reablation was demonstrated, the first month
following the procedure might not be the optimal time for a repeat intervention. On
the other hand, up to 60% of the patients experiencing this event within the first
months postablation will not have any further arrhythmias during long-term follow-up.
253
,
436
,
970
,
971
,
994
Therefore, reablation is not recommended in an ERAF that might be a transient phenomenon.
2
Conclusions
Theoretically, aggressive treatment of early recurrences of AF might prevent electrical
and structural remodeling and improve long-term outcome. Larger studies with more
reliable follow-up methods are needed to clarify the relevance and optimal management
of early recurrences.
Atrial Tachycardias After AF Ablation
ATs of new onset make up to 50% of all arrhythmias observed following catheter-based
ablation of AF.
253
,
436
,
507
,
508
,
622
,
623
,
624
,
625
,
630
,
870
,
871
,
995
,
996
,
997
,
998
,
999
,
1000
,
1001
,
1002
Most of these tachycardias originate in the LA, although RA cavotricuspid isthmus
(CTI)-dependent flutters might also occur. Patients with a regular AT of new onset
might complain of worsening symptoms due to a faster mean ventricular rate (frequently
2:1 ventricular response) than that during AF preablation. Rhythm control is often
difficult with AADs.
The mechanisms underlying regular LA tachycardias following AF ablation include focal
microreentrant tachycardias originating from reconnected PV ostia or macroreentrant
tachycardias around anatomic obstacles or scar from intrinsic LA disease or prior
ablation(s) (Figure 5
).
447
,
508
,
933
,
998
Occurrence of early AT within 3 months after ablation predicts occurrence of both
late AT and AF.
1003
,
1004
,
1005
However, because up to 49% of ATs resolve with time, ablation should not be undertaken
for early AT occurrence unless symptoms cannot be controlled.
1003
Initial treatment should include electrical cardioversion and AADs. Because Vaughan
Williams Class Ic antiarrhythmic agents promote slow conduction that can facilitate
macroreentrant tachycardias, Class III antiarrhythmic agents (dofetilide, sotalol,
or amiodarone), together with negative dromotropic agents, are typically preferred.
For those with intolerable symptoms or continued late AT recurrence, detailed activation
and entrainment mapping of the tachycardia results in effective ablation in approximately
90% of patients.
447
,
622
,
623
,
624
,
1006
,
1007
,
1008
Antiarrhythmic and Other Pharmacological Therapy Postablation
AF recurrences during the first 3 months after ablation are rather common. It is generally
believed that the mechanisms of AF in this setting are different from that of the
patient's clinical arrhythmia. Acute inflammatory changes owing to energy delivery
1009
; modification of the ANS with consecutive changes in the atrial substrate
257
; or delayed effect of radiofrequency ablation due to lesion consolidation have been
considered.
258
It is also suggested that AF might resolve completely upon resolution of the transient
factors promoting early AF recurrences. Accordingly, suppressive antiarrhythmic agents
are frequently prescribed for patients with AF recurrences during the first 1–3 months
following ablation.
253
,
436
,
988
,
1010
,
1011
Because ATs can also occur shortly after ablation, negative dromotropic agents (beta
or calcium channel blockers) are commonly continued for at least the first month after
ablation. The impact of empirical AAD therapy for 6 weeks after AF ablation on the
occurrence of AF was investigated in several randomized studies.
934
,
979
,
980
The drugs employed for this purpose vary, but most commonly are those that have been
used unsuccessfully prior to ablation; they include flecainide, propafenone, sotalol,
dofetilide, dronedarone, and amiodarone. The short-term use of AADs after AF ablation
decreased early recurrences of atrial arrhythmias and need for hospitalization or
cardioversion, but had no effect on the prediction or prevention of arrhythmia recurrence
at 6 and 12 months.
934
,
979
,
980
As noted earlier in this document, the writing group recognizes that the usefulness
of initiation or discontinuation of AAD therapy during the postablation healing phase
in an effort to improve long-term outcomes is unclear (Class IIb, LOE C-LD, Table
3
).
Because an inflammatory process after AF ablation can be one specific cause leading
to early recurrences, the efficacy of corticosteroids for preventing early postablation
atrial arrhythmias was investigated in several studies.
981
,
982
The prevalence of immediate AF recurrences (≤3 days after PVI) was significantly lower
in the corticosteroid group compared with the placebo group (7% vs 31%). However,
few investigators routinely administer steroids during or following AF ablation. The
use of PPIs or H2 blockers for 1–4 weeks following ablation has been suggested to
avoid esophageal ulcerations observed on endoscopy following AF ablation.
896
,
897
However, there are no randomized data available to demonstrate that this approach
reduces the incidence of esophageal symptoms or the development of an AEF. Early diagnosis
of AEF, with early employment of operative intervention, is the best treatment option
for AEF (please refer to Section 10 for more information). Attention to the control
of hypertension and addressing other AF risk factors such as sleep apnea and obesity
remain an integral part of AF management after the ablation procedure.
929
The impact of angiotensin-converting enzyme inhibitors and angiotensin receptor blockers
on the long-term outcome of AF ablation was investigated in a prospective registry
of consecutive patients undergoing catheter ablation of paroxysmal or persistent AF.
334
In that study, however, modulation of the renin-angiotensin aldosterone system did
not appear to affect maintenance of sinus rhythm after catheter ablation of AF. Thus,
the hypothesis that so-called medical upstream therapy can positively influence the
reverse atrial remodeling after catheter ablation of AF remains unproven.
Later-Term Repeat Ablation Procedures
Recurrences of AF (or AT) after index AF ablation procedures lead to repeat ablation
in a considerable number of patients. Recent data show a repeat procedure rate of
15% and 50% depending on the duration of follow-up and patient characteristics.
1012
Since early recurrences of AF and/or the development of AT are common during the first
2–3 months after AF ablation and might resolve spontaneously, repeat ablation procedures
should be deferred for at least 3 months following the initial procedure if possible.
Nevertheless, such early recurrences are associated with decreased long-term success
of the procedure.
260
It is also recognized that some patients will develop highly symptomatic early recurrence
of atrial arrhythmias that cannot be controlled with antiarrhythmic therapy or slowed
with rate controlling medications and are best managed with a reablation procedure
within the first 3 months post-AF ablation. Most studies have reported that patients
who fail an initial attempt at ablation and undergo a repeat ablation procedure demonstrate
resumption of electrical conduction of the previously isolated PVs rather than new
arrhythmogenic foci from nontargeted PVs or outside of the PVs.
263
,
440
,
446
,
1013
This outcome appears to be overwhelmingly the case for the first reablation procedure,
whereas in further redo procedures (e.g., second or third redo procedure) other mechanisms
also appear to play a more important role.
1014
Consequently, the first step when performing a second AF ablation procedure is to
check each PV for reconduction of electrical activity. If reconduction is found, the
primary goal should be reisolation of the PVs. If, however, there is no evidence of
PV reconduction, the decision on the best ablation technique is more complex. Several
targets have been proposed in this setting, such as LA substrate mapping and tailored
ablation guided by electrogram voltage, ablation with complex fractionated electrograms,
ablation of provoked non-PV triggers or sites commonly associated with non-PVs triggers
such as the SVC, or targeting of focal impulse and rotational activity mapping. However,
definitive evidence of the benefit or superiority of any of these techniques over
the others is lacking.
126
,
223
,
247
,
257
,
567
,
1015
,
1016
Data on current clinical practice confirm the prevailing uncertainty regarding the
best reablation technique.
540
High-dose isoproterenol infusions have been shown to be helpful in the provocation
of PV and non-PV triggers.
440
,
1013
A recent randomized trial showed that adenosine administration during the ablation
procedure might unmask dormant PV conduction and reduce the recurrence rate of the
procedure, but results were not confirmed in another trial evaluating ATP.
265
,
1017
The value of adenosine administration at the time of the redo procedure to demonstrate
latent PV conduction has not been demonstrated.
461
Autonomic Alterations
Potential side effects of AF ablation include transient and permanent alterations
in autonomic nerve activity. Transient (<6 months) elevation of heart rate, inappropriate
sinus tachycardia and reduction of heart rate variability have been observed after
PVI.
223
,
257
Others reported an immediate decrease in autonomic function such as deceleration capacity
and acceleration capacity after PVI. Some of these changes can last for over a year.
126
,
1016
Although most autonomic alterations associated with PVI are transient and are not
associated with significant symptoms, more severe autonomic alterations can occur
in cases of periesophageal vagal nerve injury.
265
,
461
,
868
,
1017
,
1018
,
1019
,
1020
A prospective observational study showed a high incidence (33%–48%) of transient (<6 months)
new onset alterations in esophageal motility after AF ablation.
536
Although most patients recover within several months, gastric hypomotility can persist
for over 28 months after the procedure in rare cases.
1020
A case of achalasia cardia has recently been reported to occur after PVI.
252
,
1021
Another study showed a 7.9% prevalence of gastric hypomotility after high output (25–30
W) posterior LA ablation. Reduction of the output to 20–25 W at sites where the ablation
line transversed the esophagus eliminated the postablation esophageal hypomotility.
1020
In additional to the watts used during ablation, it is possible that both time and
CF are factors that determine periesophageal vagal nerve injury. However, the CF was
not evaluated in the latter study. In summary, most autonomic alterations associated
with AF ablation were self-terminating and asymptomatic. However, severe symptomatic
periesophageal vagal nerve injury can occur after LA posterior wall ablation.
Very Late Recurrence (More Than 1 Year) After AF Ablation
Many groups have reported the incidence of very late AF recurrences occurring up to
10 years postablation, even after an initially successful procedure at 1 year.
63
,
270
,
536
,
1022
,
1023
,
1024
A recent meta-analysis analyzed 19 studies including 6167 patients, describing outcomes
≥3 years after AF ablation with a mean follow-up ≥24 months after the index procedure.
Single procedure and multiple procedure freedom from atrial arrhythmias has been reported
to be 53% and 80%, respectively, with substantial heterogeneity noted for single-procedure
outcomes.
Very late recurrences have been noted after an initial freedom from AF at 1 year postablation,
with an annual recurrence rate estimated at 7.6%, reaching attrition rates of 16%–46%
and 30%–54% at 5 and 10 years, respectively. Interestingly, despite the recurrence
rates, a low incidence of progression (0.3% per year) from paroxysmal to persistent
AF as well as stroke rates <1% have been reported. Also noteworthy is the fact that
time to recurrence might influence outcomes. Patients with very late recurrences are
more likely to have sporadic episodes and a better response to AADs and repeat ablation
procedures than those with earlier recurrences.
The most consistent predictor of late recurrence is persistent AF. Other predictors
include hypertension, age, LA size, diabetes, valvular heart disease and left ventricular
dysfunction, and higher thromboembolic risk scores.
63
Recurrences in patients undergoing repeat ablation procedures have been noted to be
due mostly to PV reconnection. However, recent evidence pointing to the importance
of non-PV foci and gaps in prior ablation lines can also play a role. In particular,
the LAA and LA posterior wall have been shown to contain significant triggers in patients
with non-PAF and isolation strategies are suggested to be of benefit in improving
long-term outcomes.
Section 9: Outcomes and Efficacy
Overview
AF ablation is a maturing field. Prior to the publication of the initial consensus
report in 2007, the majority of the published literature on AF ablation consisted
of uncontrolled single- and multicenter reports.
1
Further, there had been no standardization in the design of clinical trials of AF
ablation, and the 2007 and 2012 consensus documents were developed in part to generate
standard terminology, definitions, and recommendations for end points, follow-up procedures,
and outcome reporting in an effort to make studies more rigorous and consistent.
1
,
2
Over the past 10–12 years, a large number of randomized trials have been completed
addressing various aspects of AF ablation. Many have compared AF ablation with AAD
therapy in both “first-line” (AAD-naïve patients) and “second-line” (following the
failure of 1 or more drugs) settings.
261
,
377
,
378
,
379
,
462
,
529
,
684
,
733
,
1025
,
1026
,
1027
,
1028
,
1029
,
1030
In some cases, these trials have supported regulatory approval of specific ablation
technologies.
462
,
503
,
655
,
673
,
684
,
733
Some trials have compared AF ablation with other standard pharmacological or nonpharmacological
approaches to rate control.
235
,
236
,
237
,
390
Many other trials have compared various ablation techniques or alternative ablation
systems with each other. Table 7
provides a summary of the outcomes of a selected group of clinical trials of AF ablation.
This table includes a summary of the clinical trials that have been performed for
FDA approval, clinical trials of AF ablation as first-line therapy, as well as randomized
clinical trials of AF ablation for PAF, persistent AF, mixed trials, and randomized
trials of AF ablation in patients with HF.
Table 7
Selected clinical trials of catheter ablation of atrial fibrillation and/or for FDA
approval
Trial
Year
Type
N
AF type
Ablation strategy
Initial time frame
Effectiveness endpoint
Ablation success
Drug/Control success
P value for success
Ablation complications
Drug/Control complications
Comments
Clinical Trials Performed for FDA Approval
JAMA 2010; 303: 333-340 (ThermoCool AF)
684
2010
Randomized to RF ablation or AAD, multicenter
167
Paroxysmal
PVI, optional CFAEs and lines
12 months
Freedom from symptomatic paroxysmal atrial fibrillation, acute procedural failure,
or changes in specified drug regimen
66%
16%
<0.001
4.9%
8.8%
FDA approval received
JACC 2013; 61: 1713-1723 (STOP AF)
462
2013
Randomized to cryoballoon ablation or AAD, multicenter
245
Paroxysmal
PVI
12 months
Freedom from any detectable AF, use of nonstudy AAD, or nonprotocol intervention for
AF
70%
7%
<0.001
3.1%
NA
FDA approval received
Heart Rhythm 2014; 11: 202-209 (TTOP)
733
2014
Randomized to phased RF ablation or AAD/cardioversion, multicenter
210
Persistent
PVI + CFAEs
6 months
Acute procedural success, ≥90% reduction in AF burden, off AAD
56%
26%
<0.001
12.3%
NA
Not FDA approved
JACC 2014; 64: 647-656 (SMART-AF)
673
2014
Nonrandomzied multicenter study of contact force-sensing RF catheter, comparing to
performance goals
172
Paroxysmal
PVI, optional CFAEs and lines
12 months
Freedom from symptomatic AF, flutter, tachycardia, acute procedural failure, or changes
in AAD
72.5%
N/A
<0.0001
7.5%
NA
FDA approval received
Circulation 2015; 132: 907-915 (TOCCASTAR)
655
2015
Randomized to contact force sensing RF catheter or approved RF catheter, multicenter
300
Paroxysaml
PVI, optional triggers, CAFEs and lines in both arms
12 months
Acute procedural success + Freedom from Symptomatic AF/Flutter/Tachycardia off AAD
67.8%
69.4%
0.0073 for noninferiority
7.2%
9.1%
FDA approval received
JACC 2015; 66: 1350-1360 (HeartLight)
503
2015
Randomized to laserballoon or approved RF catheter, multicenter
353
Paroxysmal
PVI ± CTI ablation vs PVI, optional CFAEs, and Lines
12 months
Freedom from Symptomatic AF/Flutter/Tachycardia, acute procedural failure, AAD, or
non-prototocol intervention
61.1%
61.7%
0.003 for noninferiority
5.3%
6.4%
FDA approval received
First-Line Therapy Trials
JAMA 2005; 293: 2634-2640 (RAAFT)
377
2005
Randomized to drug, multicenter
70
Paroxysmal (N=67), persistent (N= 3)
PVI
12 months
Freedom from detectable AF
84%
37%
<0.01
9%
11%
NEJM 2012; 367:1587-1595 (MANTRA-PAF)
378
2012
Randomized to drug, multicenter
294
Paroxysmal AF
PVI, roof line, optional mitral and tricuspid line
24 months
Cumulative AF burden
13% AF burden
19% AF burden
NS
17%
15%
JAMA 2014; 311: 692-700 (RAAFT-2)
379
2014
Randomized to drug multicenter
127
Paroxysmal AF
PVI plus optional non-PVI targets
24 months
Freedom from detectable AF, flutter, tachycardia
45%
28%
0.02
9%
4.9%
Other Paroxysmal AF Ablation Trials
JACC 2006; 48: 2340-2347 (APAF)1027
2006
Randomized to drug single center
198
Paroxysmal AF
PVI, mitral line and tricuspid line
12 months
Freedom from detectable AF, flutter, tachycardia
86%
22%
<0.001
1%
23%
Circulation 2008; 118: 2498-2505 (A4)
261
2008
Randomized to drug
112
Paroxysmal
PVI (optional LA lines, CTI, focal)
12 months
Freedom from AF
89%
23%
<0.0001
5.7%
1.7%
NEJM 2016; 374: 2235-2245 (FIRE AND ICE)
489
2016
Randomized RF vs Cryo, multicenter
762
Paroxysmal AF
PVI
12 months
Freedom from detectable AF, flutter, tachycardia
64.1% (RF)
65.4% (cryo)
NS
12.8%
10.2%
JACC 2016; 68: 2747-2757
709
2016
Randomized to hot balloon or drug, multicenter
100
Paroxysmal AF
PVI
12 months
Freedom from AF
59%
5%
<0.001
10.4%
4.7%
Other Persistent AF Ablation Trials
NEJM 2006; 354: 934-9411026
2006
Randomized to RF ablation or to CV and short term amio
146
Persistent
PVI, roof, mitral line
12 months
No AF or flutter month 12
74%
58%
0.05
1.3%
1.4%
EHJ 2014; 35: 501-507 (SARA)1030
2014
Randomized to drug (2:1 ablation to drug), multicenter
146
Persistent
PVI (optional LA lines, CFAEs)
12 months
Freedom from AF/flutter lasting >24h
70%
44%
0.002
6.1%
4.20%
NEJM 2015; 372: 1812-1822
245
2015
Randomized ablation strategies, multicenter
589
Persistent
PVI alone versus PVI & CFAEs or PVI & lines
18 months
Freedom from afib with or without drugs
59% (PVI alone)
49% & 46%
NS
6%
4.3% & 7.6%
Other Mixed Paroxysmal and Persistent AF Ablation Trials
J Med Assoc Thai 2003; 86 (Suppl 1): S8-S161025
2003
Randomized to RF ablation or amiodarone
30
Paroxysmal (70%), Persistent (30%)
PVI, mitral line, CTI, SVC to IVC
12 months
Freedom from AF
79%
40%
0.018
6.70%
47%
EHJ 2006; 27: 216-2211028
2006
Randomized to RF ablation or drug, multicenter
137
Paroxysmal (67%), Persistent (33%)
PVI, mitral line, CTI
12 months
Freedom from AF, flutter, tachycardia
66%
9%
<0.001
4.40%
2.90%
JCVEP 2009, 20: 22-281029
2009
Randomized to RF ablation or drug, multicenter
70
Paroxysmal (41%), Persistent (59%) & type 2 DM
PVI, CTI, optional mitral line and roof line
12 months
Freedom from AF and atypical atrial flutter
80%
43%
0.001
2.90%
17%
Randomized Trials of AF Ablation in Patients with Heart Failure
NEJM 2008; 359: 1778-1785 (PABA-HF)
235
2008
Randomized to RF ablation of AVJ abl and BiV pacing
81
Persistent (50%), Paroxysmal (50%), EF 27% abl, 29% AVJ
PVI, optional linear abl and CFAEs
6 months
Composite EF, 6 min walk, MLWHF score; freedom from AF (secondary, mult proc, +/-
AA drugs)
88% AF free, EF 35% abl, 28% AVJ (P <.001), > QOL and 6 min walk increase with abl
<0.001
14.60%
17.50%
Heart 2011; 97: 740-747
236
2011
Randomized to RF ablation or pharmacological rate control
41
Persistent, EF 20% abl, 16% rate control
PVI, roof line, CFAEs
6 months
Change in LVEF, sinus rhythm at 6 months (secondary)
50% in NSR, LVEF increase 4.5%
0% in NSR, LVEF increase 2.8%
0.6 (for EF increase)
15%
Not reported
JACC 2013; 61: 1894-1903
390
2013
Randomized to RF ablation or pharmacological rate control
52
Persistent AF (100%), EF 22% abl, 25% rate control
PVI, optional linear abl and CFAEs
12 months
Change in peak O2 consumption (also reported single procedure off drug ablation success)
Peak O2 consumption increase greater with abl, 72% abl success
0.018
15%
Not reported
Circ A and E 2014; 7: 31-38
237
2014
Randomized to RF ablation or pharmacological rate control
50
Persistent AF (100%), EF 32% abl, 34% rate control
PVI, optional linear abl and CFAEs
6 months
Change in LVEF at 6 months, multiple procedure freedom from AF also reported
LVEF 40% with abl, 31% rate control, 81% AF free with abl
0.015
7.70%
AF, atrial fibrillation; RF, radiofrequency; AVJ, atrioventricular junction; abl,
ablation; BiV, biventricular; EF, ejection fraction; PVI, pulmonary vein isolation;
CFAEs, complex fractionated atrial electrograms; MLWHF, Minnesota Living with Heart
Failure; LVEF, left ventricular ejection fraction; QOL, quality of life; NSR, normal
sinus rhythm.
In this section, we will focus our review of this large and growing body of literature
on trials comparing AF ablation with alternative treatment approaches—primarily AADs—for
AF, to provide support for recommendations on the role of AF ablation in various patient
groups. Outcomes for specific ablation systems (CBA, rotational activity ablation,
and laser balloon ablation) will also be reviewed. Studies comparing ablation techniques
or lesion sets with each other are primarily discussed in Section 5: Strategies, Techniques,
and Endpoints.
Previous versions of the consensus report included a section on nonrandomized studies
of AF ablation. Due to the very large number of studies reported, the lack of standardization
among them, and their generally early time frame in the evolution of AF ablation,
we will not review that literature in the current document, and instead we refer readers
to the prior consensus documents and to a large meta-analysis on the topic.
262
Useful insights into AF ablation outcomes outside the setting of RCTs have also been
obtained from worldwide surveys on AF ablation, and these will also be reviewed.
In addition to a broad overview of AF ablation trials among commonly treated patient
groups, this section will also review outcomes of AF ablation in populations not well
represented in clinical trials and with specific ablation systems. Additionally, end
points beyond maintenance of sinus rhythm of considerable interest to the field (e.g.,
QOL, stroke, cost-effectiveness) will be examined.
Published Literature Review: Clinical Trials Performed for FDA Approval
When AF ablation began, procedures were performed using standard 4 mm and later 8 mm
tipped, nonirrigated RF catheters that had been developed and approved for the treatment
of other arrhythmias. The first two classes of devices to seek and achieve FDA approval
for ablation of AF were irrigated RF catheters and CBA catheters (Table 7
). In consultation with the FDA, the manufacturers of these devices were required
to conduct randomized trials comparing AF ablation to AADs and chose to evaluate patients
with PAF who had previously failed treatment with one or more drugs.
Although the two initial device approval studies had narrow entry criteria and enrolled
primarily young and healthy AF patients, they were conducted with great rigor and
contributed substantially to the previous literature comparing ablation to AAD therapy.
462
,
684
In both cases, protocol-defined success with ablation (66% and 70%, respectively)
was much higher than with drugs (16% and 7%), and acceptable rates of serious adverse
events occurred.
Given the overwhelmingly superior efficacy of AF ablation in this patient population,
ablation has become the standard of care in many centers. Accordingly, subsequent
FDA-regulated device approval studies of novel ablation technologies have not required
randomization against AADs, because doing so would be not be feasible. Instead, several
new technologies have been either compared with a previously approved device with
the same indications for use in a randomized, controlled noninferiority study or,
in the case of a second generation RF ablation catheter, compared with predefined
performance goals in a single-arm study. Examples of this pathway include recent trials
of force-sensing
655
,
673
and the laser balloon ablation system.
503
,
673
Each of these trials met its prespecified end points, generally confirming the safety
and efficacy of AF ablation in patients with PAF, but none demonstrated the superiority
of new technologies in the full study populations. Protocol-defined success rates
at 12 months in these studies ranged from 61% to 72.5% (primary effectiveness definitions
were not identical across studies). Because these studies were designed to demonstrate
noninferiority to an approved device with the same indications for use, they have
been subject to the same limitations in terms of patient population, follow-up duration,
etc., as the earlier studies.
An additional study of a phased array multielectrode RF ablation system performed
under regulatory supervision by the FDA in patients with persistent AF refractory
to ≥ 1 AAD has also been completed.
733
In this study, patients were randomized to ablation vs treatment with an alternative
AAD or increased dose of a previously ineffective drug and DC cardioversion. As expected,
protocol-defined success was higher following ablation at 6 months (56% vs 26%). However,
the study did not meet its prespecified safety end point, partly due to the occurrence
of 4 strokes (2.9% of the patients randomized to ablation) that mainly occurred during
early experience with the ablation system. As a result, this system has not been approved
in the United States.
For the purpose of regulatory approval, it is expected that future ablation technologies
designed to treat PAF will continue to be compared with previously approved ablation
systems in randomized studies. We believe that this is appropriate, although there
should be careful consideration of the possibility of a downward “creep” in acceptable
effectiveness (if each device is numerically inferior but statistically equivalent
to the prior comparator device). In the future, we expect that devices designed to
treat patients with symptomatic PAF might alternatively be evaluated in nonrandomized
trials, comparing prespecified performance goals or objective performance criteria
(OPC), if uniformly established and applied. However, given the rapid evolution of
the field of AF management, it should be understood that such performance criteria
are potentially subject to change over time. An OPC refers to a numerical target value
derived from historical data from clinical studies and/or registries and can be used
in a dichotomous (pass or fail) manner by the FDA for the review and comparison of
safety or effectiveness endpoints. Currently, no such OPC has been validated with
respect to catheter ablation of persistent AF or PAF. If an OPC is employed, it is
important to clarify the patient population to which it applies. It is anticipated
that the patient population should be similar to predicate patient populations. However,
in the clinical trials section of this document we have provided what we believe are
acceptable OPC for AF ablation clinical trials.
Studies seeking regulatory approval for the treatment of persistent and long-standing
persistent AF can follow one of two potential approaches. As in the past, future studies
might compare novel ablation systems against medical management because, at this point,
no ablation system is expressly approved for persistent or long-standing persistent
AF in the United States. Alternatively, a novel ablation system could be evaluated
in single-arm trials with prespecified OPCs.
AF Ablation as Second-Line Rhythm Control Therapy
At the time of this writing, at least 16 randomized clinical trials have been completed
comparing AF ablation with AADs in patients with AF refractory to one or more AADs.
Each of these trials is summarized in Table 7
. In addition to the trials for FDA approval listed in Table 7
, four of these trials exclusively enrolled patients with paroxysmal (or “early persistent”)
AF, three trials enrolled only patients with persistent AF, and three trials enrolled
patients with either AF pattern.
261
,
462
,
684
,
733
,
1025
,
1026
,
1027
,
1028
,
1029
,
1030
Additional randomized trials in patients with HF and persistent AF have been completed,
comparing ablation with rate control, amiodarone, or AV junction ablation with biventricular
pacing.
235
,
236
,
237
,
390
,
529
The HF trials will be reviewed in a later section of this document.
In general, the trials involving PAF focused on PVI (although adjunctive ablation
was allowed or encouraged to varying degrees), and reported success rates at 12 months
ranged from 59%–89%. In all cases, freedom from arrhythmia at 12 months was significantly
higher than with drug therapy, which had reported success rates of 5%–23%. Among trials
that included patients with persistent AF or combined paroxysmal and persistent populations,
the ablation techniques more frequently incorporated linear lesion sets or ablation
with CFAEs. Reported success rates with ablation ranged from 59%–80% at 6 or 12 months,
whereas success rates with drug therapy ranged from 9%–58%. In all cases, maintenance
of sinus rhythm was significantly higher with ablation.
It is difficult to directly compare adverse events from AF ablation to those from
AADs. In most of the above trials, low rates of serious procedural complications were
reported. With the exception of the HF trials, most of the second-line rhythm control
trials enrolled relatively healthy and young patients with AF. Mortality rates in
these relatively small trials have therefore been very low, precluding any meaningful
attempts to determine whether ablation has any impact on mortality.
The many trials comparing AF ablation with AADs for second-line rhythm control have
been evaluated in a number of meta-analyses and technology assessments.
262
,
1031
,
1032
Pooling of results across trials indicates that AF ablation is clearly superior to
AAD therapy for the maintenance of sinus rhythm. The impact of AF ablation on other
key outcomes, including HF, stroke, and QOL, will be reviewed in subsequent sections
of this document.
Outcomes and Efficacy of Catheter Ablation of AF as First-Line Rhythm Control Therapy
There have been several studies performed to investigate the role of AF ablation as
first-line therapy, prior to a trial of a membrane-active antiarrhythmic medication.
377
,
378
,
379
The Medical ANtiarrhythmic Treatment or Radiofrequency Ablation in Paroxysmal Atrial
Fibrillation (MANTRA-PAF)
494
trial compared catheter ablation with AAD therapy for the first-line therapy of symptomatic
PAF.
378
The trial did not show a reduction in the cumulative AF burden over 2 years; however,
catheter ablation was associated with a lower rate of AF recurrence (15% vs 29%, P
=.004) and a similar rate of complications (17% vs 15%) compared with AAD. The unexpected
result in the MANTRA-PAF might be explained by the ablation techniques with discretional
circumferential ablation without confirmation of PVI with a circular mapping catheter
as well as by the choice of reduction in AF burden on 7-day Holter as a primary endpoint.
Reductions in AF burden on a short 7-day Holter can be difficult to demonstrate in
a paroxysmal population. In the Radiofrequency Ablation versus Antiarrhythmic drugs
as First-line Treatment of Paroxysmal AF (RAAFT-2) trial, PV antrum isolation was
performed using irrigated-tip ablation catheters confirmed by recordings from a circular
mapping catheter.
379
The results of the RAAFT-2 demonstrated that AF or AT recurred in 55% of the catheter
ablation group compared with 72% of the patients in the AAD group after a 2-year follow-up
(P = .016).
Moreover, a meta-analysis showed that first-line therapy with catheter ablation was
more effective than AAD for long-term maintenance of sinus rhythm and was associated
with comparable rates of adverse events in relatively young patients with PAF and
minimal structural heart disease.
380
A preliminary analysis based on the results of the first RAAFT trial suggests that
catheter ablation as a first-line therapy also has a better cost-effectiveness profile.
1033
These results provide some support for the role of catheter ablation as first-line
therapy for PAF. Whether such benefits extend to elderly patients with PAF, patients
with associated structural heart disease, or non-PAF is still controversial.
One small, prospective, multicenter randomized study was performed to evaluate whether
catheter ablation is superior to AAD in patients with HF and persistent AF.
529
The main goal of the ablation procedure was PV antrum isolation and LA posterior wall
isolation. The results showed that catheter ablation was superior to amiodarone in
achieving freedom from AF at the long-term follow-up (70% vs 34%, P <.001). Moreover,
ablation improved QOL and exercise capacity, and reduced hospitalization (31% vs 57%,
P <.001) and mortality (8% vs 18%, P = .037). These data provide some support for
the notion of AF ablation as first-line therapy; however, further studies are needed.
Published Literature Review: Survey Results
A worldwide survey on the methods, efficacy, and safety of catheter ablation of AF
was first published in 2005.
806
The outcomes of nearly 9000 AF ablation procedures were reported. More than one ablation
procedure was performed in 27% of patients. The success rate, defined as freedom from
symptomatic AF in the absence of antiarrhythmic therapy, was 52%. An additional 24%
of patients were free of symptomatic AF in the presence of a previously ineffective
AAD. The incidence of major complications was 6%.
In a subsequent survey from the same group, the clinical outcome and safety of AF
ablation performed between the years 2003 to 2006 in 85 participating centers proved
to be better than in the previous years.
920
During a follow-up of 10 ± 8 months, 192 procedures per center were reported with
a 70% efficacy rate free of AADs, and an additional 10% efficacy rate in the presence
of previously ineffective AADs. Ablation of PAF was associated with a 35% and 66%
larger probability of success compared with ablation of persistent and long-standing
persistent AF, respectively. Despite a larger prevalence of centers reporting catheter
ablation of persistent and long-standing persistent AF, the overall complication rate
was 4.5%. There were 25 procedure-related deaths (0.15%), 37 strokes (0.23%), 115
TIAs (0.71%), and 213 episodes of tamponade (1.31%).
In a subsequent report analyzing the risk of periprocedural death by means of an aggregate
calculation from the previous two surveys, 32 fatal events were observed (0.98 per
1000 patients) during 45,115 procedures in 32,569 patients.
908
Cardiac tamponade was found to be the most frequent cause of death, with 8 patients
(1 more than 30 days) suffering a fatal outcome as a consequence of this complication.
Stroke was reported as the cause of death in 5 patients (2 more than 30 days), AEF
in 5 patients, and massive pneumonia in 2 patients.
More recently, the same authors provided a systematic analysis of 45 delayed tamponade
events (e.g., cardiac tamponade occurring at least 1 hour after procedure termination)
in 21,478 patients undergoing 27,921 procedures (0.2%).
1034
The median time to tamponade was 12 days (range: 0.2–45 days) after procedure termination,
with only 4 patients experiencing this event prior to discharge. The mode of clinical
presentation varied, with 39 patients exhibiting gradual progression to cardiac tamponade
and 6 patients experiencing severe symptoms within minutes. Two patients died from
this complication (risk of death 1 per 10,000 patients).
In January 2014, another survey reported on the first prospective series providing
preprocedural, procedural, and 1-year follow up data on 72 centers enrolling about
1400 patients undergoing a median of 1.2 procedures.
969
In their registry, the authors reported a 1-year success rate free from AAD therapy
of only 40% (44% in PAF; 30% in persistent AF; 37% in long-term persistent AF). Adding
AAD therapy increased the successful control rate to 72%. This result was achieved
with 20% of the patients having undergone at least a second procedure. Using a multivariate
analysis, the authors found that AF recurrence during the 3-month blanking period
was the only predictor of failure at the 1-year follow-up.
In 2014, the Prospective European Survey on AF Ablation investigators published a
prospective consecutive series of 946 consecutive patients enrolled in 35 centers.
1035
AF patterns were paroxysmal, persistent, and long-standing persistent in 52%, 36%,
and 12% of patients, respectively, with 12% of the centers offering AF ablation as
first-line therapy. PVI was performed in all the centers, with empiric linear lesions
and/or ablation of CFAEs being delivered as adjunctive approaches in patients with
non-PAF. RF was the dominant energy form used (more than 95% of procedures), with
cryoenergy and laser offered in 4% and less than 1% of procedures, respectively.
In a recent survey led by the EHRA, the strategy used by 30 European centers for treating
persistent AF was reported.
540
Almost half of the recruiting centers were performing more than 400 catheter ablations
per year and more than 200 LA ablations. PVI was the main technique in patients undergoing
first-time ablation for persistent, but not long-standing persistent, AF in the majority
of the centers (67%), with ablation using fractionated electrograms, either as an
addition to PVI or as a stand-alone procedure, in 13% and 3% of centers, respectively.
A stepwise AF ablation technique was used in only 3% of centers. In patients with
long-standing persistent AF, stand-alone PVI was adopted in only one-third of centers.
In the remaining two-thirds, ablation with fractionated electrograms, stepwise ablation
until AF was terminated, and PVI plus linear lesions at the LA roof or the mitral
isthmus were the most frequently reported techniques. When PVI was the only technique
used in patients with persistent or long-standing persistent AF, 20% and 10% of procedures
were performed with CB, respectively. The 1-year success rate after a single procedure
at 1 year was found to be 50%–60% in 40% of the centers, with three centers reporting
a success rate of less than 40% and three centers reporting a success rate higher
than 80%.
Outcomes of AF Ablation in Populations Not Well Represented in Clinical Trials
Outcomes of Catheter Ablation of Persistent and Long-Standing Persistent AF
Persistent AF is quite heterogeneous regarding the pathophysiological mechanisms responsible
for electrical and structural remodeling of the atria. In addition, persistent AF
itself is an independent predictor of recurrence, and catheter ablation has reduced
success compared with PAF.
268
Success rates vary according to the heterogeneity of the patient population and ablation
strategies that are encompassed under the umbrella “non-PAF.” It is now increasingly
well recognized that the duration of continuous AF is an important predictor of the
efficacy of AF ablation. Patients with continuous AF of 12 months or less duration
are very different from patients who have been in continuous AF for years.
The quality and quantity of data concerning the outcomes of AF ablation in patients
with non-PAF, including both persistent and long-standing persistent AF, is limited.
529
,
733
,
1015
,
1030
Table 7
shows the outcomes of four trials of catheter ablation for persistent AF.
245
,
733
,
1026
,
1030
Despite the widespread performance of AF ablation on patients with persistent AF,
no ablation catheters have received FDA or CE Mark labeling specifically for the indication
of ablation of persistent AF. One completed clinical trial was performed with a goal
of obtaining FDA labeling for ablation of persistent AF using a novel, phased RF multielectrode
ablation system.
733
In this study, patients were randomized to ablation or to treatment with an alternative
AAD or an increased dose of a previously ineffective drug, and DC cardioversion. As
expected, protocol-defined success was higher following ablation at 6 months (56%
vs 26%). However, the study did not meet its prespecified safety endpoint, partly
due to the occurrence of 4 strokes (2.9% of the patients randomized to ablation) that
mainly occurred during early experience with the ablation system. As a result, this
system has not been approved in the United States. There have been a number of studies
performed comparing ablation strategies in patients with persistent AF. The largest
was the recently published STAR-AF trial.
245
This well-performed and adequately powered study randomized patients with persistent
AF to ablation with PVI alone, PVI alone plus linear ablation, or PVI plus ablation
of CFAEs. No difference in efficacy was observed, and there was a trend toward superiority
of PVI alone.
It is important to note, however, that several prospective clinical trials are planned
or have begun in an effort to obtain FDA labeling for the use of point-by-point RF
ablation and cryoablation. Both these trials have chosen to enroll patients with early
persistent AF (and to exclude patients with long-standing persistent AF) and to employ
OPC. In addition to these trials, there has been one small, prospective, randomized
clinical trial that compared the outcomes of ablation with AAD therapy in 146 patients
with persistent AF. The efficacy of AF ablation in this study was superior to AAD
therapy.
1030
The writing group recommendations for techniques to be used for ablation of persistent
and long-standing persistent AF are shown in Table 3
. PVI remains the cornerstone of all AF ablation procedures and is recommended. Several
new ablation strategies are being explored for use in patients with persistent AF.
These approaches include mapping and ablation of rotational activity, ablation of
areas of low voltage, ablation of areas identified on MRI as showing fibrosis, ablation
of non-PV triggers, as well as LAA focal ablation, isolation, and/or ligation. Each
of these techniques is described elsewhere in this document.
In this regard, there is considerable debate as to which of these techniques, if any,
should be employed during an initial or repeat AF ablation procedure in patients with
long-standing persistent AF. An important study was a report of the 5-year outcomes
of the “stepwise” approach to AF ablation
515
The single-procedure efficacy of this approach at 1 year was 35%, falling to 17% at
year 5. With repeated procedures, the arrhythmia-free survival after the last procedure
at the 5-year follow-up was 63%. These and other trials are an important reminder
that new ablation strategies should not be widely adopted into routine clinical practice
until the safety, efficacy, and true clinical value of these new strategies have been
demonstrated in well-designed and adequately powered prospective randomized clinical
trials. As a result of these and other studies, use of the stepwise ablation strategy,
empiric linear ablation, and ablation of CFAEs are much less commonly performed today
than in the past, when this was a popular ablation strategy for patients with persistent
AF.
Outcomes of AF Ablation in Elderly Patients
Several studies have been published describing the outcomes of AF ablation in elderly
patients. One study compared the safety and efficacy of catheter ablation in three
groups of patients: <65 years, 65–74 years, and ≥75 years. Although the total study
population included 1165 patients, the group ≥75 years only included 32 patients.
Over a mean follow-up of 27 months, AF control defined as no AF on or off AADs or
“rare” AF was comparable in the older and younger patients. The older patients were
less likely to undergo repeat ablation and were more likely to remain on AADs. Complication
rates were similar.
1036
In another study of 174 patients >75 years, 55% of whom had PAF, 127 (73%) maintained
sinus rhythm after a single procedure, with an acute major complication rate of 1%.
1037
Another study evaluated catheter ablation for AF in 103 octogenarians with paroxysmal,
persistent, or long-standing persistent AF compared with patients <80 years.
399
,
400
,
401
The proportion of patients with the different types of AF was similar in both groups.
A higher rate of non-PV triggers (84% vs 69%, P = .001) was found in the octogenarians.
After a mean follow-up of 18 ± 6 months, 71 (69%) of the octogenarians remained free
from AF off AADs after a single procedure vs 71% in patients <80 years (P = NS). Complication
rates did not differ between the two groups. Other studies of octogenarians have found
similar results.
398
,
1038
In a retrospective cohort study involving Medicare claims for 15,423 patients who
underwent ablation procedures associated with a primary diagnosis of AF, it was found
that advanced age was a major risk factor for all adverse outcomes. However, the overall
rate of adverse outcomes was fairly small. Only 11% of patients underwent a second
ablation procedure by 1 year after the index procedure, a low rate that has been observed
in other studies.
1039
In another analysis of a large commercial claims database, acute complications in
patients over and under the age of 65 years were nearly identical.
1040
Although comparable rates of periprocedural strokes have generally been found, late
stroke might be more common in older patients.
1041
In general, studies have shown similar success rates with catheter ablation for AF
in older patients compared with younger patients, with comparable complication rates.
However, the small number of elderly patients in most studies compared with the much
greater prevalence of AF in the elderly indicates that ablation is being performed
in a highly selected group of older patients. A consistent finding is that older patients
are less likely to undergo a second procedure if the index procedure fails to eliminate
the arrhythmia. The recommendations for AF ablation in elderly patients are shown
in Table 2
.
Outcomes of AF Ablation in Patients with Congestive Heart Failure and the Impact of
Ablation on Left Ventricular Function
A number of clinical trials have examined the role of catheter ablation of AF in patients
with HF. The initial study to address this important topic was published in 2004.
232,1042
This study examined the role of catheter ablation in 58 patients with HF with an EF
of less than 45% and 58 controls. During a mean follow-up of 12 ± 7 months, 78% of
patients with HF and 84% of controls remained in sinus rhythm. Of particular note
is that the EF improved by 21% ± 13%. Improvements also were seen in exercise capacity
and in QOL. Another study is the Pulmonary Vein Antrum Isolation versus AV Node Ablation
with Bi-Ventricular Pacing for Treatment of AF in Patients with Congestive Heart Failure
(PABA-CHF) study that compared the efficacy of AF ablation with AV node ablation and
pacemaker implantation.
235
The primary endpoint of this prospective, multicenter clinical trial was a composite
of EF, distance on a 6-minute walk, and Minnesota Living with Heart Failure (MLWHF)
questionnaire score after a 6-month follow-up. This study demonstrated an overall
superiority of PVI to AV node ablation and pacing given by a lower score on the MLWHF
questionnaire (60 vs 82), longer walking distance (340 m vs 297 m), and higher EF
(35% vs 28%). A third case-controlled series reported that the efficacy of AF ablation
was similar in patients with and without LV systolic dysfunction and reported an improvement
in EF at the 6-month follow-up.
388
Since publication of the last consensus document, four additional prospective randomized
clinical trials have been published focusing on the outcomes of AF ablation in patients
with HF.
236
,
237
,
390
,
529
The first three were included in a recent meta-analysis.
392
The meta-analysis reported data from 4 randomized trials involving a total of 224
patients, 83% of whom had persistent AF. AF ablation was associated with an increase
in LVEF of 8.5% compared with rate control. AF ablation was also superior in improving
QOL as well as peak oxygen consumption and 6-minute walk distance. Major adverse events
were not significantly different. The most recent trial randomized patients with persistent
AF and HF (Ablation vs Amiodarone for Treatment of Atrial Fibrillation in Patients
With Congestive Heart Failure and an Implanted ICD/CRTD [AATAC] trial) to AF ablation
or treatment with amiodarone. Catheter ablation was more effective than amiodarone
in preventing recurrent AF (70% after a mean of 1.4 procedures vs 34%) and was associated
with a lower rate of unplanned hospitalization.
529
Taken as a whole, the results of these studies suggest that catheter ablation of AF
is safe and effective in selected patients with HF. As compared with rate control
alone, catheter ablation results in a greater improvement in EF. The recommendations
for AF ablation in patients with HF are shown in Table 2
.
Outcomes of AF Ablation in Patients with Hypertrophic Cardiomyopathy
AF is a commonly reported complication of hypertrophic cardiomyopathy (HCM) with a
prevalence and annual incidence of 22.5% and 3.1%, respectively.
1043
The substrate for AF is complex and determined by atrial fibrosis, atrial dilatation,
or intrinsic atrial myopathy. In patients with HCM, development of AF is associated
with marked exacerbation of symptoms, increased risk of stroke, and excess HCM-related
mortality.
1043
Due to the association of AF with HCM-related morbidity and mortality, there is general
agreement that vigorous maintenance of sinus rhythm should be attempted.
273
,
274
Randomized data regarding the efficacy of AADs are not available for patients with
HCM; in daily practice, however, drugs are frequently ineffective in eliminating AF
recurrence. In addition, the efficacy and safety of catheter ablation in the setting
of HCM is poorly characterized, with studies in small patient cohorts, observational
in nature, and providing contradictory results. A recent systematic review and meta-analysis
of these studies aimed to determine the efficacy and safety of catheter ablation of
AF in patients with HCM.
1044
Single-procedure success (freedom from AF or AT recurrence) was 38.7% in patients
with HCM (vs 49.8% in controls; OR 2.25; 95% CI 1.09–4.64; P = .03). Outcome after
≥1 procedure amounted to 51.8% (vs 71.2% in controls; OR 2.62; 95% CI 1.52–4.51, P = .0006).
Repeat procedures (mean difference = 0.16; 95% CI 0.0–0.32, P = .05) and AADs (OR
4.70; 95% CI 2.31–9.55, P <.0001) were more frequently needed in patients with HCM.
Sensitivity analyses suggested that the outcome in patients with HCM with less dilated
atria and PAF might be more comparable to the general population. Overall, the risk
of procedure-related adverse events was low. In summary, even though the likelihood
of recurrence is twofold higher, catheter ablation can be effective in patients with
HCM and AF, particularly in patients with PAF and smaller atria. The recommendations
for AF ablation in patients with HF are shown in Table 2
.
Outcomes of AF Ablation in Young Patients
As an age-related condition, AF is uncommon in young adults. However, younger patients
with AF are often highly symptomatic and might have a desire to avoid long-term medical
therapy, making catheter ablation a potentially attractive treatment option.
Limited information is available regarding the outcomes of AF ablation in unusually
young patients. At least two single-center studies and one multicenter study have
reported on the outcomes of AF ablation in unusually young patients.
405
,
1045
Two of these three studies defined young ablation patients as those under the age
of 45 years; the other reported on outcomes of AF ablation for lone AF, defined as
age <65 with no cardiac, pulmonary, or structural heart disease (mean age 45).
In a 2010 single-center study, 232 patients under age 45 were identified from an overall
ablation cohort.
405
The authors reported that younger patients had lower rates of major complications
compared with more typically aged AF ablation patients. The rate of the author-defined
primary outcome of AF control was similar across age groups, but a higher proportion
of young patients (76%) were AF-free in the absence of AADs after 1 or more ablation
procedures than older patients (from 53%–68%). A 2016 single-center study reported
on ablation outcomes in 76 patients with lone AF (9% of their overall ablation population).
Freedom from atrial arrhythmia after one procedure was 74%, whereas freedom from atrial
arrhythmia after the last procedure without AADs was 96%. The largest study on AF
ablation in younger patients was a multicenter German registry in which 593 patients
aged ≤45 years were compared with 6650 patients aged >45 years. In this study, the
younger patients had lower rates of complication, shorter hospital stays, and lower
rates of AF recurrence and AAD than older patients. Together, these studies suggest
that AF ablation might be both safer and more effective in younger patients compared
with “average” or older AF patients, although this result could be due in part to
a lower burden of cardiac and noncardiac comorbid diseases. It has been suggested
that AF ablation might more readily be considered first-line rhythm control therapy
in younger rather than older patients; however the evidence base for making such a
recommendation is not strong. The recommendations for AF ablation in young patients
are shown in Table 2
.
Outcomes of AF Ablation in Women
Multiple studies have found that women are more symptomatic from AF, have a lower
QOL, and are less tolerant of AADs than men.
806
,
1046
,
1047
,
1048
,
1049
However, the rate of referral of women for catheter ablation of AF is significantly
lower than men, and women are referred much later after failing more AADs.
920
There has not been consistent evidence to support female sex as a predictor of recurrence
after AF ablation, based on multiple univariate and multivariate analyses.
252
,
1050
,
1051
A systematic review of predictors of AF recurrence after catheter ablation reported
that none of the 23 studies found female sex to be a predictor of recurrence.
1050
At least four major studies have specifically examined outcomes after ablation of
AF in women. A large, retrospective multicenter study involved 3265 consecutive patients
with drug-refractory AF who underwent PVI.
289
,
290
,
291
Women constituted a much lower percentage of the patients referred for ablation, were
referred later for ablation, had failed more AADs, more often had hypertension, and
were older at the time of the procedure. After 24 ± 16 months of follow-up, the women
had significantly lower success rates than the men, defined as single-procedure freedom
from recurrent AF off AADs (68.5 vs 77.5%; P <.001). Another study also found a lower
success rate in women after a single catheter ablation procedure (35.6% in women vs
57.1% in men; P = .003); however, once repeat procedures were taken into account,
there was no significant difference in outcome.
1052
Other studies have not shown a difference in outcomes between men and women.
1053,1054
Most recently, a large-scale prospective analysis of sex-related differences in catheter
ablation of AF that enrolled 1124 patients with PAF was reported from Japan.
1054
After a mean follow-up of 31.7 ± 24.4 months following the index ablation, there was
no significant difference in success rates or complication rates between women and
men.
Sex-related recurrence rates have been reported as nonprimary end points in at least
17 other studies, most of which did not reveal significant sex-related differences.
1055
Female sex has been reported as a predictor of complications after AF ablation, and
higher complication rates from AF ablation in women have repeatedly been found.
252
,
289
,
290
,
291
,
806
,
808
,
920
,
1050
,
1051
,
1052
,
1053
,
1054
,
1056
,
1057
,
1058
,
1059
A multicenter U.S. retrospective study reported total complications of 3265 (518 in
women vs 2747 in men), with a 5% complication rate in women vs 2.4% in men (P <.001).
This study found more hematomas and pseudoaneurysms in women.
289
,
290
,
291
A large multicenter registry from Italy that enrolled 2323 patients also reported
a significantly higher complication rate in women (7% vs 4.4%), and female sex was
reported to be an independent predictor of a higher risk of complications by univariate
analysis (OR 2.643; 95% CI 1.686–4.143; P <.0001).
1059
Overall, studies have not shown a significant sex-related difference in outcomes with
AF ablation in women compared with men, but complication rates are consistently higher
in women.
Outcomes of Cryoballoon Ablation
Within the past 10 years, CB-based catheter ablation has emerged as an alternative
technique to RF ablation for the treatment of patients with symptomatic AF, especially
for those with PAF. This change is not only related to the simplified handling of
the cryoablation catheter when compared with point-by-point RF ablation, but also
to technological developments and the steadily increasing number of clinical trials
consistently reporting an overall comparable efficacy to RF ablation. It is important
to note that, as in the whole field of AF ablation, the reported efficacy outcomes
must be interpreted with caution due to differences in the intensity of follow-up
and endpoint definitions.
In 2012, the second-generation CB was introduced. A modified refrigerant injection
system allows for a more uniform cooling across the distal balloon hemisphere.
489
,
691
,
692
,
1060
,
1061
,
1062
,
1063
,
1064
,
1065
Since the 2012 update of this consensus paper, multiple randomized and nonrandomized
studies including a large-scale registry have been published that compared CBA against
point-by-point RF ablation with respect to rhythm outcome in patients with PAF.
490
,
492
,
493
,
695
,
696
,
1066
,
1067
,
1068
,
1069
,
1070
,
1071
,
1072
The majority of these studies revealed that CBA was similarly effective in the prevention
of arrhythmia recurrences, with arrhythmia-free survival ranging from 54% to 85% in
patients undergoing cryoablation and from 55% to 88% in patients undergoing RF ablation
after 1 to 2 years of follow-up. In particular, there was no difference in efficacy
when the second-generation CB was compared with advanced-generation RF catheters featuring
CF measurements for improved wall contact.
1068
,
1070
In the FREEZE-AF study, 315 patients with PAF were randomized to open irrigated radiofrequency
ablation or CBA for PVI.
1069
Cryoablation was exclusively performed with the first-generation CB catheter. The
primary endpoint was freedom from atrial arrhythmia recurrence with absence of persistent
complications. At 12 months, the primary endpoint was met by 70.7% of the patients
in the RF ablation group and by 73.6% of the patients in the cryoablation group after
at least one ablation procedure with similar rates of redo procedures in both groups
(19.5% vs 19.9%). Periprocedural complications occurred more frequently in the cryoablation
group compared with the RF ablation group (12.2% vs 5.0%), which was largely driven
by 9 transient PN injuries (5.8%) in the cryoablation arm.
The most robust data are provided by the FIRE AND ICE trial that, to date, is the
largest randomized trial comparing both technologies in patients with symptomatic
drug-refractory PAF.
490
In this multicenter trial, 762 patients were randomly assigned to undergo PVI by open
irrigated RF (approximately one-fourth with CF) or by CBA (approximately three-fourths
with CB-2). The primary efficacy endpoint was defined as first documented clinical
failure, a composite of recurrent AF, occurrence of AFL or AT, AAD use, or repeat
ablation. After a mean follow-up of 1.5 years, CBA was noninferior to RF ablation
with regard to efficacy, with the primary endpoint occurring in 34.6% and 35.9% of
patients in the cryoablation group and in the RF ablation group, respectively. There
was no statistically significant difference in the primary safety endpoint: a composite
of death, cerebrovascular events, and serious treatment-related adverse events (10.2%
vs 12.8% for cryoablation vs RF ablation, respectively). There were 10 PN injuries
(2.7%) in the cryoablation group, with nine of these injuries resolving by 6 months
after ablation. Thus, the incidence of permanent PN paralysis was 0.3%. A subsequent
analysis reported that the patients who underwent CBA had fewer repeat AF ablation
procedures, direct current cardioversions, all-cause hospitalizations, and cardiovascular
hospitalizations during follow-up compared with the group randomized to RF ablation.
489
Limitations of this subsequent analysis, which need to be considered when interpreting
the results, included the inclusion of nonprespecified endpoints, as well the fact
that this analysis was industry sponsored.
The role of cryoablation in patients with persistent AF is less well established.
To date, data are predominantly derived from relatively small, noncontrolled trials
and mostly reflect a single-center experience.
486
,
1073
,
1074
,
1075
,
1076
,
1077
Overall, cryoablation appears to be associated with a favorable long-term outcome
in patients with persistent AF, with arrhythmia-free survival ranging from 56% to
82%. In one non-randomized study, arrhythmia-free survival off AADs was similar when
cryoablation was compared with RF ablation at 1-year follow-up after a single procedure
(60% vs 50%).
1078
Preliminary results from a single-center study demonstrated the feasibility of extra-PV
CBA in patients with long-standing persistent AF.
1077
Future prospective randomized trials are needed to more precisely define the role
of CBA in patients with persistent and long-term persistent AF.
Outcome of Rotational Activity Ablation for AF
Several studies have used phase mapping techniques to identify the rotational activity
in patients with AF. Furthermore, catheter ablation of AF guided by phase mapping
targeting rotational activity has been found to be effective at eliminating AF in
some reports. However, the prevalence of rotational activity and the outcome of rotational
activity ablation have varied widely, and long-term outcomes of rotational activity
ablation are still lacking. An early investigator used the 64-pole basket catheter
to map rotational activity in patients with paroxysmal or persistent AF, and found
a high prevalence of rotational activity; application of RF energy on the rotational
activity eliminated AF in more than 90% of the patients.
563
A more recent study reported favorable results when using an ablation strategy that
combined PVI and ablation or rotational activity in patients with non-PAF. However,
another investigator
1079
used the same mapping tool and techniques for AF ablation and identified rotational
activity in less than 20% of AF patients.
569
Other investigators could not reproduce a high percentage of rotational activity in
patients with AF and found disappointing results with rotational activity-based ablation.
1080
Another investigator used the body-surface high-density mapping technique and identified
reentrant drivers in 80.5% of paroxysmal and persistent patients with AF, and AF was
eliminated in 75% of the AF with reentry drivers.
222
In another study, high-density activation mapping identified rotational activity in
15% of the patients with persistent AF.
224
Although the Non-Invasive Mapping of Atrial Fibrillation (AFACART) study also showed
an 80% success rate in terminating AF, the long-term success rate for eliminating
AF was significantly less. However, the duodecapolar mapping catheter with phase mapping
identified rotational activity in 65% of persistent AF and long-term persistent AF;
application of RF energy on these areas of rotational activity after PVI rendered
65% of the AF free (mean follow-up 18 months).
497
Although the application of phase mapping facilitates identification of rotational
activity, conventional activation mapping might not see rotational activity clearly.
Due to the controversy around the various ablation techniques for persistent and long-term
persistent AF, the prevalence and outcome of rotational activity ablations need further
investigation.
1081
Outcomes of Laser Balloon Ablation
Visually guided PVI using the laser balloon is a recently developed technology. It
was first introduced in Europe and was approved in the United States in 2016. Since
2010, there have been a number of publications describing its use.
497
,
498
,
499
,
501
,
502
,
503
,
1082
,
1083
,
1084
,
1085
The number of patients included in these studies has ranged from 50 to 200.
498
,
1084
The patients in all these studies had PAF, except for one study that included patients
with persistent AF.
1085
The laser balloon is highly effective in achieving PVI. The rate of acute PVI ranged
from 98% to 100%.
498
,
501
,
502
Remapping studies also demonstrated a highly durable rate of isolation of the PVs
using this technology.
503
The freedom from AF at follow-up ranged from 60% to 88%, which is comparable to the
outcome of PVI using RF energy in similar populations.
503
,
1085
The patients in all the published studies were followed for at least 12 months.
The laser beam positioning during PVI is executed under direct visualization. However,
manipulating the catheter in the LA is guided by X-ray imaging. The fluoroscopy time
for laser balloon PVI has been reported to range between 13 and 36 minutes, with a
total procedure time range of 2–4 hours.
498
,
1082
The FDA-reviewed HeartLight study was a prospective, multicenter randomized trial
comparing laser balloon PVI with conventional RF ablation.
503
,
1082
The 1-year success rate of the laser balloon did not differ from ablation with the
ThermoCool System (61.1% vs 61.7%, respectively). The rates of stroke (1.2%) and tamponade
(1.2%) were similar to RF ablation. Diaphragmatic paralysis secondary to PN injury
occurred in 3.6% of the patients with the laser balloon, which was more common than
with RF ablation. Persistent PN paralysis at 1 year occurred in 1.8% of patients.
PV stenosis was observed only in patients randomized to RF ablation (2.9%). There
were no deaths or AEFs in the study. This ablation system is now approved for clinical
use in Europe and the United States.
Long-Term Ablation Efficacy
During the past decade, a large number of studies have been published that have examined
the important issue of the long-term efficacy of AF ablation. Prior to this time,
most clinical studies presented data from short-term follow-ups, often less than 12 months
in duration. The first of these studies was published 5 years ago and described the
long-term outcomes of a series of 264 patients who were AF-free and off AAD therapy
at the 12-month point following an initial ablation procedure.
284
During a mean follow-up of 28 ± 12 months, AF recurred in 23 patients (8.7%). The
actuarial recurrence rate of AF at 5 years was 25.5%. Similar findings have been reported
in each of the subsequent trials.
266
,
267
,
268
,
1022
,
1086
,
1087
The predictors of late recurrence most commonly identified include persistent AF as
well as comorbid conditions. Despite the low single-procedure, long-term success rate
reported in virtually all of these clinical trials, they also reveal that with the
use of repeat AF ablation procedures and/or AAD therapy, much higher rates of freedom
from recurrent AF as well as concomitant reductions in AF burden can be achieved.
Impact of Catheter Ablation of AF on QOL
Because symptomatic improvement is a primary objective in the treatment of patients
with AF, formal assessments of QOL have played an increasingly important role in the
evaluation of ablation outcomes.
47
,
63
,
1088
These measures can provide a more global reflection of symptom change, symptomatic
arrhythmia burden, and the difference between actual and desired health and function
than more focused endpoints of rhythm status at specific points in time. Generic tools,
such as the SF-36 health survey,
1089
which is applicable to a broad range of disease states and health conditions, and
disease-specific questionnaires
1090
,
1091
developed to assess symptom burden in patients with arrhythmias, have been most widely
employed.
Patients with AF, as reflected by standardized SF-36 scores, have substantially impaired
QOL, below population norms and comparable to patients with coronary artery disease
and congestive HF.
47
,
1088
,
1092
A number of single-center, nonrandomized observational studies of AF ablation have
demonstrated significant and sustained improvements in QOL scores following catheter
ablation.
63
,
1088
Taken alone, these findings need to be interpreted cautiously, because in the absence
of a comparison group or treatment blinding, placebo effects cannot be excluded. Two
studies demonstrated that over a 12-month period following treatment, changes in QOL
scores were strongly related to the presence or absence of documented AF recurrence
within the previous 30 days.
1093
,
1094
More important are the results of randomized clinical trials that compared catheter
ablation with AAD therapy in patients with PAF, and evaluated QOL as an outcome measure.
261
,
377
,
378
,
379
,
684
Investigating catheter ablation as second-line therapy after failed AAD treatment,
catheter ablation was associated with significant improvements in SF-36 scores relative
to baseline, with restoration to levels at or above population norms.
261
,
684
QOL scores were significantly higher for patients treated with catheter ablation than
for patients treated with drug therapy, in whom there was little change from baseline
scores.
In the three trials investigating catheter ablation as first-line therapy for AF,
QOL improved with both AAD treatment and catheter ablation, and significantly more
with catheter ablation, using the SF-36,
377
,
378
,
1091
or 4312 EQ-5D379 instruments (EuroQOL five dimensions questionnaire).
A recent meta-analysis included data from 12 RCTs comparing catheter ablation (as
first- or second-line therapy) and AAD treatment, and including a total of 1707 patients
with symptomatic AF. In this analysis, catheter ablation led to greater improvements
in several areas of the SF-36 questionnaire and in the symptom frequency score from
baseline to 3 months follow-up. However, for all QOL metrics as well as for symptom
frequency and severity scores, the differences between catheter ablation and AAD treatment
diminished with increasing duration of follow-up, and no significant differences remained
beyond 9 months of follow-up.
1032
In the randomized trials, an impact of crossover from AAD treatment to catheter ablation
cannot be excluded. However, in an on-treatment analysis of data from a randomized
trial comparing catheter ablation and AAD treatment as first-line therapy, no differences
in QOL were observed between patients treated with catheter ablation, patients treated
with AADs, and patients treated with a combination of both.
494
Concerns have been raised that generic QOL instruments such as SF-36 are not sufficiently
sensitive or focused to detect changes in disease-specific symptoms such as those
associated with AF.
63
,
974
AF-specific QOL measures, including the AF Effect on QOL (AFEQT) questionnaire,
1095
the Mayo AF Symptom Inventories,
63
and the Arrhythmia-Specific questionnaire in Tachycardia and Arrhythmia (ASTA),
1096
have been developed and are in the process of validation. A recent study reported
that disease-specific assessments of QOL are superior to generic questionnaires.
1097
Preliminary findings indicate that these tools also demonstrate substantial improvements
in QOL with ablation, and can more accurately reflect ablation efficacy. However,
there is currently no general agreement that any of the AF-specific QOL instruments
are superior to others or to the general QOL instruments. The use of QOL measures
will be discussed further in the section.
Impact of Catheter Ablation of AF on LA Size and Function
Experimental and clinical research has demonstrated that in some settings AF results
in, or is accompanied by, electrical, structural, and functional remodeling of the
atrium.
14
,
587
,
1098
,
1099
The results of a subset of these studies suggest that AF can be viewed, in some patients,
as a rate-related atrial cardiomyopathy. As discussed elsewhere in the document, AF
can also follow and be the consequence of prior atrial damage and fibrosis (atrial
myopathy). To the extent that rate-related cardiomyopathies lead to reversible chamber
dilatation and dysfunction, it was anticipated that reverse remodeling might also
occur in a subset of patients who underwent AF catheter ablation.
Several studies have examined LA size before and after catheter ablation.
437
,
1100
,
1101
,
1102
These studies have demonstrated a significant decrease in the size of the LA after
PVI of PAF, regardless of whether echocardiography, MRI, or CT was used for LA imaging.
The reverse remodeling of LA was more pronounced when sinus rhythm had been successfully
restored.
1103
Although the precise mechanism of this decrease in size is not clear, it appears consistent
with reverse remodeling due to the decreased burden of AF and scar formation from
the ablation procedure.
The impact of catheter ablation of AF on LA transport function was investigated in
patients with paroxysmal and persistent AF, with conflicting results.
1104
,
1105
A meta-analysis showed a significant decrease in LA volume but did not find significant
changes in active LA function, including studies with persistent as well as PAF ablation
procedures.
1106
However, because AF eliminates essentially all contractility of the LA, there is general
agreement that restoration of sinus rhythm in patients with persistent AF improves
atrial function if sinus rhythm is maintained.
391
,
1107
,
1108
,
1109
However, ablation-related scarring with the risk of causing persistent atrial dysfunction
still remains a major concern after extensive ablation for persistent AF. The long-term
outcome after stepwise approach for persistent AF demonstrated the impaired contractility
and compliance of LA, which was related to scar burden.
1110
Moreover, a recent study has reported a series of patients who developed LA diastolic
dysfunction and pulmonary hypertension following AF ablation.
1111
The precise cause of “stiff LA syndrome” or a “noncompliant LA” and methods to prevent
it will clearly be an area for further study going forward.
Impact of Catheter Ablation on Stroke Risk
Conceptually, it appears logical that catheter ablation—by elimination of or reductions
in AF burden—lowers the risk of stroke or TIA; initial reports from single-center,
nonrandomized studies did demonstrate a relatively low rate of stroke or TIA after
catheter ablation.
231
,
545
To date however, there are no RCTs verifying the hypothesis that ablation lowers the
long-term incidence of stroke or TIA. Please refer to Section 7 for a more detailed
discussion of the recommendations made by the writing group for long-term anticoagulation
post-AF ablation.
Indirect evidence stems from four large, health administrative databases using propensity-score
matching to create a “control” population and to even out differences between patient
groups.
239
,
1112
,
1113
,
1114
In a very large, prospectively collected registry (the Intermountain Healthcare Database
in Utah), investigators reported a significantly lower rate of stroke in 4212 ablated
patients (follow-up 3.1 ± 2.4 years), compared with those who did not undergo ablation.
239
Moreover, ablated patients had comparable stroke rates when compared with age- and
sex-matched patients who did not have a history of AF. Both observations were independent
of baseline stroke risk score. Another propensity score-matched analysis of medically
treated and ablated patients within the U.S. MarketScan Research Database (n = 805
in each group with follow-up of up to 3 years), showed that AF ablation was associated
with a reduced risk of stroke or TIA compared with AAD therapy (HR 0.62; 95% CI 0.44–0.86,
P = .005).
1112
Similarly, data from the Taiwanese national health insurance claims database reported
lower risk of stroke in 846 ablated patients compared with the control group (HR 0.57;
95% CI 0.35–0.94; P = .026).
1113
Recently, a retrospective, propensity score-matched analysis (using as many as 51
parameters) of medically treated and ablated patients from Swedish health registries
(n = 2836 in each group during a follow-up period of 4.4 years) confirmed that ablation
was associated with a lower incidence of ischemic stroke than nonablated patients
(HR 0.69; 95% CI 0.51–0.93; P = .016).
1114
This association between ablation and stroke was pronounced in patients with a CHA2DS2-VASc
score ≥2 points, but was not discernible among patients with low stroke risk.
Three other observational studies determined possible predictors for stroke-free survival
within the ablated patient group.
241
,
242
,
408
Multivariate analysis in 174 ablated Taiwanese patients showed that ablation outcome
was the strongest independent predictor for survival free of major adverse cardiovascular
events, including stroke (HR 0.225; 95% CI 0.076–0.671; P = .007).
241
A Kaplan-Meier survival analysis demonstrated that ablation-treated patients without
AF recurrence had a lower incidence of ischemic strokes and TIAs (P = .015) compared
with patients with AF recurrence or medically treated patients. Of interest, a retrospective
analysis of 3058 ablated low-risk patients from a single-center registry showed only
a modest, non-significant reduction in the risk of cerebrovascular events in patients
who maintained sinus rhythm when compared with those who had AF recurrence.
242
The above studies suggest that catheter ablation can lower the risk of stroke via
maintenance of sinus rhythm. However it is recognized that the retrospective nature
of these studies makes them prone to bias. The above studies are limited by a lack
of detailed data on rhythm and/or anticoagulation status, selection bias (low stroke
risk at baseline), relatively short follow-up, and the extent to which patient groups
can be matched. Despite the fact that propensity score matching was successful in
creating a control population that was similar to the ablated group, adjustment is
only possible for observable factors. Unknown confounding factors could account for
why patients treated with ablation had lower rates of stroke or TIA (post hoc ergo
propter hoc). Bias of unmeasured variables can only be fully neutralized in RCTs.
Finally, it should be noted that some of the above studies made comparisons to historical
cohorts whose risk of stroke appears to be much higher than the risk reported in recent
studies.
Therefore, the above findings cannot be viewed as definitive and do not provide sufficient
evidence that ablation reduces stroke risk. Instead, they reinforce the hypothesis
behind studies like the CABANA trial or the EAST trial, which will provide more definitive
evidence. However, the results will not be available until 2018, and, as with most
long-term studies in ablation, their relevance could be challenged by the rapidly
evolving nature of the ablation field.
Predictors of Success Following AF Ablation
A large number of studies have been performed to examine clinical predictors of the
efficacy of AF ablation.
328
,
329
,
365
,
1050
,
1115
,
1116
,
1117
Factors that have been identified as predictors of a poorer outcome, at least in some
studies, include (1) non-PAF and particularly long-term persistent AF; (2) sleep apnea
and obesity; (3) increased LA size; (4) increased age; (5) hypertension; and (6) LA
fibrosis as detected by cardiac MRI.
365
A systematic review of predictors of AF recurrence after AF ablation analyzed data
from 45 studies, 25 of which included a multivariable analysis of predictors of recurrence.
1050
Among the 17 studies that examined AF type as a predictor of recurrence, 11 studies
reported no impact of AF type on recurrence, whereas six studies reported that the
presence of non-PAF was an independent predictor of a higher rate of recurrence (HR
ranging from 1.8 to 22). Seventeen studies evaluated EF as a predictor of recurrence.
Very few patients in any of these studies had an EF less than 40%. Among these 17
studies, only five reported a significant association between lower EF and a higher
rate of AF recurrence. Twenty studies examined LA diameter as a predictor of AF recurrence.
Very few patients in any study had LAD >60 mm. Among these 20 studies, four reported
a significant association between larger LAD and a higher rate of recurrence of AF.
Among 21 studies that examined the presence of structural heart disease as a predictor,
only one reported a significant association at 12 months of follow-up. Most studies
examined sex, and no association between recurrence and sex was found. Only one of
22 studies reported an independent association between age and recurrence.
Cost-Effectiveness of AF Ablation
The cost-effectiveness of AF ablation has been evaluated in a number of individual
studies and several systematic reviews.
1118
,
1119
,
1120
,
1121
,
1122
,
1123
,
1124
,
1125
The costs of AF ablation procedures can vary widely, depending on the treatment setting
and the actual equipment used.
409
,
1126
Estimates of the cost-effectiveness of AF ablation can vary further based on a number
of additional factors, including the patient population, the severity of symptoms,
the analytic time horizon, and assumptions about the impact of AF ablation on QOL,
stroke, and other clinical outcomes. One issue supporting the potential cost-effectiveness
of AF ablation is that the costs of ablation are at least partly offset over time
by reducing long-term, arrhythmia-related health care resource utilization for patients
not treated with ablation, as supported by some empirical evidence.
90
,
476
,
1033
,
1127
However, most formal cost-effectiveness studies have not found AF ablation to be cost
neutral or cost saving in the short to intermediate term.
The majority of published cost-effectiveness studies have compared AF ablation to
AADs as second-line therapy in patients with PAF.
1119
,
1120
,
1122
,
1124
,
1128
,
1129
In general, these studies have reported acceptable cost-effectiveness ratios—in the
range of $27,000 to $59,000 (Canadian) per quality-adjusted life year (QALY) gained
over 5-year time horizons.
1122
,
1128
Results would be more favorable if ablation were found to significantly reduce the
risk of stroke.
1118
U.S. experts have recently indicated that cost-effectiveness ratios below $50,000
per QALY indicate high value, and between $50 and $150,000 indicate intermediate value.
1130
Less is known about the cost-effectiveness of ablation in the first-line setting or
in patients with persistent or long-term persistent AF. One report based on the First
Line Radiofrequency Ablation Versus Antiarrhythmic Drugs for Atrial Fibrillation Treatment
(RAAFT) pilot study suggested that costs for patients initially treated with drugs
would catch up to those for patients treated with ablation within 2 years due to a
very high rate of crossover. However, another more detailed cost-effectiveness study
modeled after the MANTRA-PAF trial population indicated that AF ablation might only
be cost-effective as first-line therapy in younger patients.
1125
Assessments of cost-effectiveness at present rely greatly on extrapolations from clinical
trials with limited follow-up duration and sample sizes, necessitating assumptions
about key clinical benefits. Robust data from larger, longer studies will be needed
to refine cost-effectiveness estimates.
Section 10: Complications
Overview
Catheter ablation of AF is one of the most complex interventional electrophysiological
procedures. AF ablation by its nature involves catheter manipulation and ablation
in the delicate thin-walled atria, which are in close proximity to other important
organs and structures that can be impacted through collateral damage. It is therefore
not surprising that AF ablation is associated with a significant risk of complications,
some of which might result in life-long disability and/or death. In this section of
the document we will review the complications associated with catheter ablation procedures
performed to treat AF. The complications are defined and their mechanisms explored.
Emphasis is placed on both those complications that occur most frequently as well
as those very infrequent complications that have the potential to result in the greatest
disability and/or death. Means of avoiding complications are described and recommendations
are made regarding management should the complications occur.
It is noteworthy that the publications from which these data are derived come from
high-volume centers where one would expect the incidence of complications to be lower
than in lower-volume centers. As the practice of AF ablation grows with an increasing
number of low-volume centers performing these procedures, it is likely that the true
complication rate of AF ablation will be higher than described here. Furthermore,
other data such as those derived from the two worldwide surveys of catheter ablation
of AF were provided voluntarily and, again, are therefore likely to underestimate
the true complication rate.
806
,
920
It is notable that a recent paper reported on the trends in hospital complication
rates associated with AF ablation between 2000 and 2010 based on the Nationwide Inpatient
Sample involving 93,801 procedures.
921
The overall incidence of complications was 6.29%—increasing from 5.3% in 2000 to 7.5%
in 2010. The in-hospital mortality was 0.46%. Not surprisingly, lower operator and
hospital procedure volume was an important predictor of complications. These data
are a stark reminder that our efforts to eliminate complications associated with AF
ablation are incomplete and there is more work to do.
As our experience with AF ablation continues to grow, new complications are recognized
and are reviewed here. These include stiff LA syndrome, cough, pulmonary injury, gastric
hypomotility, and sinus tachycardia. Once again, the writing group strongly recommends
that standardized reporting of complications be part of all published reports on AF
ablation. In this document, we have provided definitions of the most important complications
associated with AF ablation (Table 8
). We hope these definitions and reporting standards can be incorporated in the design
of future clinical trials of AF ablation. Shown in Table 9
is an overview of the incidence, prevention, diagnosis, and management of selected
complications, and Table 5
presents signs and symptoms associated with various complications early and late postablation.
Table 8
Definitions of complications associated with AF ablation
Asymptomatic cerebral embolism
Asymptomatic cerebral embolism is defined as an occlusion of a blood vessel in the
brain due to an embolus that does not result in any acute clinical symptoms. Silent
cerebral embolism is generally detected using a diffusion weighted MRI.
Atrioesophageal fistula
An atrioesophageal fistula is defined as a connection between the atrium and the lumen
of the esophagus. Evidence supporting this diagnosis includes documentation of esophageal
erosion combined with evidence of a fistulous connection to the atrium, such as air
emboli, an embolic event, or direct observation at the time of surgical repair. A
CT scan or MRI scan is the most common method of documentation of an atrioesophageal
fistula.
Bleeding
Bleeding is defined as a major complication of AF ablation if it requires and/or is
treated with transfusion or results in a 20% or greater fall in hematocrit.
Bleeding following cardiac surgery
Excessive bleeding following a surgical AF ablation procedure is defined as bleeding
requiring reoperation or ≥ 2 units of PRBC transfusion within any 24 hours of the
first 7 days following the index procedure.
Cardiac perforation
We recommend that cardiac perforation be defined together with cardiac tamponade.
See “Cardiac tamponade/perforation.”
Cardiac tamponade
We recommend that cardiac tamponade be defined together with cardiac perforation.
See “Cardiac tamponade/perforation.”
Cardiac tamponade/perforation
Cardiac tamponade/perforation is defined as the development of a significant pericardial
effusion during or within 30 days of undergoing an AF ablation procedure. A significant
pericardial effusion is one that results in hemodynamic compromise, requires elective
or urgent pericardiocentesis, or results in a 1-cm or more pericardial effusion as
documented by echocardiography. Cardiac tamponade/perforation should also be classified
as “early” or “late” depending on whether it is diagnosed during or following initial
discharge from the hospital.
Deep sternal wound infection/mediastinitis following cardiac surgery
Deep sternal wound infection/mediastinitis following cardiac surgery requires one
of the following: (1) an organism isolated from culture of mediastinal tissue or fluid;
(2) evidence of mediastinitis observed during surgery; (3) one of the following conditions:
chest pain, sternal instability, or fever (>38 °C), in combination with either purulent
discharge from the mediastinum or an organism isolated from blood culture or culture
of mediastinal drainage.
Esophageal injury
Esophageal injury is defined as an erosion, ulceration, or perforation of the esophagus.
The method of screening for esophageal injury should be specified. Esophageal injury
can be a mild complication (erosion or ulceration) or a major complication (perforation).
Gastric motility/pyloric spasm disorders
Gastric motility/pyloric spasm disorder should be considered a major complication
of AF ablation when it prolongs or requires hospitalization, requires intervention,
or results in late disability, such as weight loss, early satiety, diarrhea, or GI
disturbance.
Major complication
A major complication is a complication that results in permanent injury or death,
requires intervention for treatment, or prolongs or requires hospitalization for more
than 48 hours. Because early recurrences of AF/AFL/AT are to be expected following
AF ablation, recurrent AF/AFL/AT within 3 months that requires or prolongs a patient's
hospitalization should not be considered to be a major complication of AF ablation.
Mediastinitis
Mediastinitis is defined as inflammation of the mediastinum. Diagnosis requires one
of the following: (1) an organism isolated from culture of mediastinal tissue or fluid;
(2) evidence of mediastinitis observed during surgery; (3) one of the following conditions:
chest pain, sternal instability, or fever (>38 °C), in combination with either purulent
discharge from the mediastinum or an organism isolated from blood culture or culture
of mediastinal drainage.
Myocardial infarction in the context of AF ablation
The universal definition of myocardial infarction
1399
cannot be applied in the context of catheter or surgical AF ablation procedures because
it relies heavily on cardiac biomarkers (troponin and CPK), which are anticipated
to increase in all patients who undergo AF ablation as a result of the ablation of
myocardial tissue. Similarly, chest pain and other cardiac symptoms are difficult
to interpret in the context of AF ablation both because of the required sedation and
anesthesia and also because most patients experience chest pain following the procedure
as a result of the associated pericarditis that occurs following catheter ablation.
We therefore propose that a myocardial infarction, in the context of catheter or surgical
ablation, be defined as the presence of any one of the following criteria: (1) detection
of ECG changes indicative of new ischemia (new ST-T wave changes or new LBBB) that
persist for more than 1 hour; (2) development of new pathological Q waves on an ECG;
(3) imaging evidence of new loss of viable myocardium or new regional wall motion
abnormality.
Pericarditis
Pericarditis should be considered a major complication following ablation if it results
in an effusion that leads to hemodynamic compromise or requires pericardiocentesis,
prolongs hospitalization by more than 48 hours, requires hospitalization, or persists
for more than 30 days following the ablation procedure.
Phrenic nerve paralysis
Phrenic nerve paralysis is defined as absent phrenic nerve function as assessed by
a sniff test. A phrenic nerve paralysis is considered to be permanent when it is documented
to be present 12 months or longer following ablation.
Pulmonary vein stenosis
Pulmonary vein stenosis is defined as a reduction of the diameter of a PV or PV branch.
PV stenosis can be categorized as mild <50%, moderate 50%–70%, and severe ≥70% reduction
in the diameter of the PV or PV branch. A severe PV stenosis should be considered
a major complication of AF ablation.
Serious adverse device effect
A serious adverse device effect is defined as a serious adverse event that is attributed
to use of a particular device.
Stiff left atrial syndrome
Stiff left atrial syndrome is a clinical syndrome defined by the presence of signs
of right heart failure in the presence of preserved LV function, pulmonary hypertension
(mean PA pressure >25 mm Hg or during exercise >30 mm Hg), and large V waves ≥10 mm
Hg or higher) on PCWP or left atrial pressure tracings in the absence of significant
mitral valve disease or PV stenosis.
Stroke or TIA postablation
Stroke diagnostic criteria
Rapid onset of a focal or global neurological deficit with at least one of the following:
change in level of consciousness, hemiplegia, hemiparesis, numbness or sensory loss
affecting one side of the body, dysphasia or aphasia, hemianopia, amaurosis fugax,
or other neurological signs or symptoms consistent with stroke
Duration of a focal or global neurological deficit ≥24 hours; OR < 24 hours if therapeutic
intervention(s) were performed (e.g., thrombolytic therapy or intracranial angioplasty);
OR available neuroimaging documents a new hemorrhage or infarct; OR the neurological
deficit results in death.
No other readily identifiable nonstroke cause for the clinical presentation (e.g.,
brain tumor, trauma, infection, hypoglycemia, peripheral lesion, pharmacological influences).^
Confirmation of the diagnosis by at least one of the following: neurology or neurosurgical
specialist; neuroimaging procedure (MRI or CT scan or cerebral angiography); lumbar
puncture (i.e., spinal fluid analysis diagnostic of intracranial hemorrhage)
Stroke definitions
Transient ischemic attack: new focal neurological deficit with rapid symptom resolution
(usually 1 to 2 hours), always within 24 hours; neuroimaging without tissue injury
Stroke: (diagnosis as above, preferably with positive neuroimaging study);
Minor—Modified Rankin score <2 at 30 and 90 days†
Major—Modified Rankin score ≥2 at 30 and 90 days
Unanticipated adverse device effect
Unanticipated adverse device effect is defined as complication of an ablation procedure
that has not been previously known to be associated with catheter or surgical ablation
procedures.
Vagal nerve injury
Vagal nerve injury is defined as injury to the vagal nerve that results in esophageal
dysmotility or gastroparesis. Vagal nerve injury is considered to be a major complication
if it prolongs hospitalization, requires hospitalization, or results in ongoing symptoms
for more than 30 days following an ablation procedure.
Vascular access complication
Vascular access complications include development of a hematoma, an AV fistula, or
a pseudoaneurysm. A major vascular complication is defined as one that requires intervention,
such as surgical repair or transfusion, prolongs the hospital stay, or requires hospital
admission.
AF, atrial fibrillation; CT, computed tomography; MRI, magnetic resonance imaging;
PRBC, packed red blood cell; AFL, atrial flutter; AT, atrial tachycardia; CPK, creatine
phosphokinase; ECG, electrocardiogram; LBBB, left bundle branch block.
^Patients with nonfocal global encephalopathy will not be reported as a stroke without
unequivocal evidence based on neuroimaging studies.
†
Modified Rankin score assessments should be made by qualified individuals according
to a certification process. If there is discordance between the 30- and 90-day modified
Rankin scores, a final determination of major versus minor stroke will be adjudicated
by the neurology members of the clinical events committee.
Table 9
Incidence, prevention, diagnosis, and treatment of selected complications of AF ablation
Complication
Incidence
Selected prevention techniques
Diagnostic testing
Selected treatment options
References
Air embolism
<1%
Sheath management
Nothing or cardiac catheterization
Supportive care with fluid, oxygen, head down tilt, hyperbaric oxygen
803
,
1218–1223
Asymptomatic cerebral emboli (ACE)
2% to 15%
Anticoagulation, catheter and sheath management, TEE
Brain MRI
None
723
,
724
,
728
,
731
,
800
,
1205–1217
Atrial esophageal fistula
0.02% to 0.11%
Reduce power, force, and RF time on posterior wall, monitor esophageal temp, use proton
pump inhibitors; avoid energy delivery over esophagus
CT scan of chest, MRI; avoid endoscopy with air insufflation
Surgical repair
637
,
705
,
806
,
866
,
877–920
,
1162–1178
,
1398
Cardiac tamponade
0.2% to 5%
Cather manipulation, transseptal technique, reduce power, force, and RF time
Echocardiography
Pericardiocentesis or surgical drainage
482
,
806
,
908
,
920
,
921
,
1034
,
1131–1135
,
1139–1141
Coronary artery stenosis/occlusion
<0.1%
Avoid high-power energy delivery near coronary arteries
Cardiac catheterization
PTCA
923
,
1233–1240
Death
<0.1% to 0.4%
Meticulous performance of procedure, attentive postprocedure care
NA
NA
921
,
806
,
908
,
920
,
1039
Gastric hypomotility
0% to 17%
Reduce power, force, and RF time on posterior wall
Endoscopy, barium swallow, gastric emptying study
Metoclopramide, possibly intravenous erythromycin
536
,
1017–1021
,
1179–1185
Mitral valve entrapment
<0.1%
Avoid circular catheter placement near or across mitral valve; clockwise torque on
catheter
Echocardiography
Gentle catheter manipulation, surgical extraction
1263–1269
,
1396
Pericarditis
0% to 50%
None proven
Clinical history, ECG, sedimentation rate, echocardiogram
NSAID, colchicine, steroids
985
,
986
,
1257–1262
Permanent phrenic nerve paralysis
0% to 0.4%
Monitor diaphragm during phrenic pacing, CMAP monitoring, phrenic pacing to identify
location and adjust lesion location
CXR, sniff test
Supportive care
462
,
482
,
490
,
503
,
532
,
533
,
536
,
706
,
707
,
779
,
808
,
903
,
920
,
1017
,
1075
,
1182–1201
Pulmonary vein stenosis
<1%
Avoid energy delivery within PV
CT or MRI, V/Q wave scan
Angioplasty, stent, surgery
244
,
434
,
462
,
482
,
498
,
503
,
927
,
928
,
1142–1160
Radiation injury
<0.1%
Minimize fluoroscopy exposure, especially in obese and repeat ablation patients, X-ray
equipment
None
Supportive care, rarely skin graft
747
,
749
,
763
,
1186
,
1241–1256
Stiff left atrial syndrome
<1.5%
Limit extent of left atrial ablation
Echocardiography, cardiac catheterization
Diuretics
1110
,
1111
,
1270–1275
Stroke and TIA
0% to 2%
Pre-, post-, and intraprocedure anticoagulation, catheter and sheath management, TEE
Head CT or MRI, cerebral angiography
Thrombolytic therapy, angioplasty
242
,
489
,
503
,
532
,
655
,
673
,
796
,
798
,
799
,
806
,
920
,
921
,
1202–1204
Vascular complications
0.2% to 1.5%
Vascular access techniques, ultrasound-guided access, anticoagulation management
Vascular ultrasound, CT scan
Conservative treatment, surgical repair, transfusion
806–808
,
834
,840
–
842
,
920
,
921
,
1224–1232
AF, atrial fibrillation; CT, computed tomography; MRI, magnetic resonance imaging;
TEE, transesophageal electrocardiogram; RF, radiofrequency; PTCA, percutaneous transluminal
coronary angioplasty; NA, not applicable; ECG, electrocardiogram; NSAID, nonsteroidal
anti-inflammatory drug; CMAP, compound motor action potentials; CXR, chest X-ray;
TIA, transient ischemic attack.
Cardiac Tamponade
Cardiac tamponade remains the most common potentially life-threatening complication
associated with AF ablation.
921
A recent paper reported on the trends in in-hospital complication rates associated
with AF ablation between 2000 and 2010 based on the Nationwide Inpatient Sample involving
93
,
801
procedures.
921
In this analysis, the overall incidence of a “pericardial complication” was 1.5%.
The incidence of pericardial complications increased from 0.74% in 2000 to 2.24% in
2010.
921
The markedly higher incidence of cardiac tamponade during AF ablation compared with
routine cardiac electrophysiology procedures can be attributed to a number of important
procedural differences, including extensive intracardiac catheter manipulation and
ablation, the common need for two or more transseptal punctures, and the need for
systemic anticoagulation.
806
,
920
,
921
,
1131
,
1132
,
1133
,
1134
,
1135
The most common causes of cardiac perforation leading to cardiac tamponade during
AF ablation are (1) misdirected transseptal punctures either with punctures performed
too posteriorly exiting the RA into the pericardium before entering the LA or punctures
exiting the LA via the roof, LAA, or the lateral LA wall; (2) direct mechanical trauma,
especially through the LAA; and (3) overheating during RF energy delivery, with or
without the development of a steam pop. Excessive power, temperatures, and CF might
also be contributory.
The need for periprocedural anticoagulation (with the use of interrupted or uninterrupted
OAC strategies) and for intraprocedural anticoagulation (with the infusion of intravenous
heparin to achieve a stable ACT above 300 seconds throughout the procedure duration)
can exacerbate the bleeding risk and increase the volume of bleeding following the
occurrence of one or more of the causes above. One initial large study reported that
uninterrupted VKA anticoagulation therapy did not result in a higher incidence of
tamponade compared with interrupted VKA anticoagulation therapy with bridging heparin.
532
,
533
This observation was further corroborated by two meta-analyses.
399
,
400
,
401
,
1136
Another study compared the outcomes of 23 patients who developed pericardial tamponade
with an INR <2 to 17 patients on warfarin with an INR >2. No difference was observed
in the initial pericardial drainage, or the duration of drainage; no patients required
surgery.
1137
A more recent shift in periprocedural anticoagulation strategies during AF ablation
involves performing AF ablation on uninterrupted NOAC therapy. The results of the
RE-CIRCUIT study, which was a head-to-head comparison of performing AF ablation on
uninterrupted dabigatran vs uninterrupted warfarin, were recently published.
841
This study randomized 704 patients across 104 sites to these two anticoagulation strategies.
The incidence of major bleeding events during and up to 8 weeks postablation among
the 635 patients who underwent AF ablation was significantly lower with dabigatran
than with warfarin (5 patients [1.6%] vs 22 patients [6.9%]; absolute RD -5.3%; RR
reduction 77%). It is notable that there were six patients with cardiac tamponade
in the warfarin arm vs one in the dabigatran arm. All the patients with cardiac tamponade
underwent successful pericardiocentesis with no need for surgical drainage. No strokes
or other thromboembolic events occurred in the dabigatran arm compared with one TIA
in the warfarin arm. No patients in the dabigatran arm required the specific reversal
agent idarucizumab. Another smaller prospective trial of 250 patients that randomized
patients to undergoing AF ablation on uninterrupted rivaroxaban versus uninterrupted
warfarin has been published.
842
The incidence of major bleeding was low (0.4%), and no patient developed pericardial
tamponade. A recent meta-analysis reported that performance of AF ablation on NOACs
was associated with a lower risk of minor bleeding and no major differences in the
risk of stroke or TIA, cardiac tamponade, or groin hematomas.
1138
Another recent study described the outcomes of 16 patients who developed a pericardial
effusion while taking an uninterrupted Xa inhibitor. Eleven occurred in the periprocedural
setting and 5 occurred between 1 and 28 days postprocedure. All the patients underwent
pericardiocentesis. Protamine and 4-factor prothrombin complex concentrate were given
to all periprocedure cases. Two patients required surgery. There were no deaths in
this series.
The incidence of tamponade might be as high as 6%
1135
and as low as 0%. The risk factors for tamponade identified in this study were linear
ablation lesions and higher ablation power. A “pop” was heard during eight of these
10 cases of tamponade. Another large series reported cardiac tamponade during 15 of
632 ablation procedures (2.4%).
1134
Two of these patients required surgical intervention. In contrast to the prior study,
no “pop” was reported. The two worldwide surveys of AF ablation reported a 1.2% and
a 1.3% incidence of cardiac tamponade, respectively.
806
,
920
A recent meta-analysis of ablation procedures reported a 0.9% incidence of tamponade.
1139
Women were 1.83-fold more likely to develop tamponade compared with men. A reciprocal
relationship between center volume and the incidence of outcomes of cardiac tamponade
was observed. Overall, 16% of tamponade cases required surgery, with lower rates of
surgery in high-volume centers.
1139
A meta-analysis of CBA with data on 1308 procedures reported an overall incidence
of cardiac effusion or tamponade of 1.5%.
482
A more recent prospective RCT of CBA vs RF ablation reported an incidence of tamponade
of 1.3% in the RF arm and of 0.3% in the CB arm.
489
Although it was hoped the recent introduction of force-sensing catheters would reduce
the rate of tamponade, this has not been confirmed in clinical trials. The incidence
of cardiac tamponade was 2.5% among 161 patients in the safety cohort of the recently
published SMART-AF trial of the Smart Touch catheter.
673
And in the TOCCASTAR trial, which randomized patients to ablation with a force-sensing
catheter (Endosense) or a standard irrigated RF catheter, no difference in the incidence
of cardiac tamponade was observed in the two arms (0.66% vs 0.7%, P = NS).
655
It is important to recognize that the presentation of cardiac tamponade might be delayed
and can occur any time from an hour after the procedure to weeks later.
1034
,
1139
The incidence of delayed tamponade was 0.2% in the worldwide survey report.
1034
Most, but not all, patients presented with warning symptoms and 13% of patients presented
with hypotension and shock.
Cardiac tamponade presents either as an abrupt dramatic fall in BP, or more insidiously,
as a gradual decrease in BP. In the latter case, administration of fluid might return
the BP to normal before it subsequently declines. However, it is vital that operators
and staff be vigilant to the development of cardiac tamponade, as a delay in diagnosis
can be fatal. Sixty percent of the writing group members use an arterial line for
BP monitoring during the AF ablation procedure. The development of hypotension in
any patient should be assumed to indicate tamponade until proven otherwise by immediate
ECG. An early sign of cardiac tamponade is a reduction in the excursion of the cardiac
silhouette on fluoroscopy with a simultaneous fall in systemic BP. Ninety percent
of the writing group members have an echo machine in their EP laboratory. Sixty percent
of the writing group members routinely image the heart with an echocardiogram prior
to the patient leaving the procedure room. Twenty percent of the writing group members
routinely obtain an echocardiogram of the heart prior to discharge. ICE has been reported
to allow earlier detection of pericardial effusion. It is important to recognize that
small, asymptomatic pericardial effusions are commonly observed following AF ablation
procedures. ICE imaging has the potential to detect pericardial effusion earlier.
A survey of writing group members reveals that 53% of members routinely employ ICE
imaging during AF ablation. Our survey revealed that ICE was being used routinely
by 87% of the writing group members in the United States and Canada as compared with
13% of the writing group members from other countries. Monitoring filling pressures
in the LA and RA can be helpful in order to evaluate progression of the effusion and/or
effective drainage of the pericardial collection. Ninety-three percent of the writing
group members hospitalize their AF ablation patients for at least one night following
their procedure.
The majority of episodes of cardiac tamponade can be managed successfully by immediate
percutaneous drainage and reversal of anticoagulation with protamine. In patients
anticoagulated with warfarin, fresh frozen plasma is often administered. And in patients
on an Xa inhibitor, 4-factor prothrombin complex concentrate is often appropriate.
For patients on dabigatran, the reversal agent idarucizumab is now available worldwide
and provides the opportunity to immediately reverse the anticoagulant effects of dabigatran.
844
Factor Xa inhibitors can be reversed with andexanet alfa (currently not approved for
clinical use).
845
Percutaneous drainage is best achieved by subxiphoid Seldinger puncture of the pericardial
sac and placement of an intrapericardial catheter. The pericardial tap can be performed
either with fluoroscopic guidance based on anatomic landmarks or with echo guidance.
1140
After initial aspiration, the BP promptly returns to normal. Once the pericardial
space has been drained, the patient needs to be monitored for ongoing bleeding with
the drainage catheter. The drainage catheter is typically left in place for at least
12 hours postablation. In rare cases, if there has been a tear, percutaneous drainage
might be inadequate, and surgical drainage and repair could be necessary.
1134
One recent meta-analysis reported that 16% of cases of cardiac tamponade required
surgical intervention.
1139
It is for this reason that AF ablation procedures should only be performed in hospitals
equipped or prepared to manage these types of emergencies with access to emergency
surgical support when required. Three cases have been reported of emergent drainage
of a pericardial effusion through a sheath, either inadvertently or purposely placed
into the pericardial space using an endocardial approach, although this would not
be considered to be a standard approach.
532
,
533
,
1132
,
1141
Early recognition and rapid appropriate treatment of cardiac tamponade is mandatory
to prevent irreversible deterioration in perfusion of the brain and other important
organs. In a dedicated worldwide survey, cardiac tamponade was reported to be the
most frequent cause of periprocedural death, with 25% of all fatalities occurring
in association with this complication.
908
PV Stenosis
PV stenosis is a well-recognized complication of AF ablation that results from thermal
injury to the PVs, including the media, intima, adventitia, and PV musculature. Since
first reported in 1998, numerous studies have sought to determine the incidence, cause,
diagnostic strategy and treatment approach for PV stenosis.
434
,
927
,
1142
,
1143
,
1144
,
1145
Although the precise pathophysiological mechanisms are still uncertain, a progressive
neointimal proliferation and myocardial fibrosis resulting in endovascular contraction
has been reported after extensive radiofrequency energy ablation (RFA) to canine PVs.
1146
PV stenosis has been described for both point-by-point RF ablation as well as CBA.
244
,
462
,
482
,
928
,
1146
,
1147
To the best of our knowledge, significant PV stenosis has not been reported with the
laser balloon system.
498
,
503
There are controversial data regarding any impact that RF power output has on the
rate of PV stenosis.
244
,
1147
The incidence of PV stenosis might be somewhat lower with CB AF ablation than with
RFA.
1148
,
1149
In experienced hands, however, PV stenosis has become an increasingly uncommon complication
with either ablation technology.
489
The highest risk for PV stenosis is associated with RFA close to the PV orifices and/or
within the PVs, with a 5.6-fold higher incidence in comparison with antral ablation.
1147
Ablation within the PVs should be avoided, but can occur due to shifts in the 3D electroanatomic
map, respiratory motion, poor catheter stability, and/or an inexperienced operator.
The published incidence of PV stenosis varies widely, from 0% to 40%.
434
,
505
,
778
,
1142
,
1144
,
1150
,
1151
This variation results from differences in the ablation technique, definitions of
PV stenosis, the intensity of screening for this complication, and the date the study
was performed. When PV ablation for treating AF began in the late 1990s, investigators
were unaware that PV stenosis was a potential complication. In contrast, operators
today understand that PV stenosis can be prevented by avoiding RF energy delivery
within a PV. This increased awareness and improvements in imaging modalities have
enabled better identification of the true PV ostium and have resulted in a dramatic
reduction in the incidence of PV stenosis.
1141
,
1147
The incidence of symptomatic PV stenosis in experienced hands approaches zero, although
the incidence of asymptomatic PV stenosis or PV narrowing might be higher.
Symptoms usually occur weeks to months after the ablation procedure.
927
,
1152
Prominent symptoms are dyspnea, hemoptysis, cough, (recurrent) pulmonary infections
or pneumonia, and chest pain.
1142
,
1143
,
1152
These have often led to a misdiagnosis of pneumonia, pulmonary embolism, or even lung
cancer; thus, patients should be told of the importance of returning to their ablation
center if such signs or symptoms develop. There are data showing a progression of
stenosis during 3 months after RFA despite a normal imaging examination at 1 month
after the index procedure. Furthermore, severe stenosis can also remain asymptomatic.
927
According to the percentage reduction of the luminal diameter, the severity of PV
stenosis is generally defined as mild (<50%), moderate (50%–70%), or severe (>70%).
In this consensus statement, we recommend that a significant PV stenosis be defined
as a > 70% reduction in luminal diameter. PV stenosis can develop in any PV; and in
some patients, multiple PV stenoses occur.
927
,
928
,
1143
,
1152
It is unclear whether such patients are more prone to develop PV stenosis compared
with others.
PV stenosis can be diagnosed by CT imaging, MRI, perfusion scans, TEE, or pulmonary
venography. The preferred imaging modality is MRI or CT because location and severity
of PV lesions can be precisely visualized. Advantages of MRI include the fact that
pulmonary perfusion data can be obtained simultaneously and that the diagnostic procedure
is free of radiation. Eleven percent of the writing group members routinely obtain
a CT or MR scan several months postablation to screen for asymptomatic PV stenosis.
Although the incidence of PV stenosis has decreased over recent years, it remains
a significant complication because it is difficult to treat and, rarely, it can lead
to death. It is notable that 51% of the writing group members report having had a
patient at their center develop PV stenosis requiring intervention. Most of these
procedures were performed more than a decade ago. The indication for intervention
is guided predominantly by the presence or absence of symptoms. Asymptomatic or mild
symptomatic PV stenosis should be managed conservatively with watchful waiting, given
symptomatic amelioration has been observed after PV stenosis or occlusion without
treatment and indicates collateral formation or recruitment.
1153
For symptomatic patients, PV angioplasty should be considered. In patients with more
than one PV stenosis, perfusion imaging may be applied to identify the “culprit” lesion.
The dilation procedure is often complex, especially if the target PV is completely
occluded with failed visualization from direct angiography via the LA as well as antegradely
via pulmonary artery angiography. Electroanatomical 3D mapping with registration of
the anatomy of the LA and the PVs, as well as fusion with the reconstructed LA from
the imaging scan before the index procedure, enables a precise localization of the
occluded PV.
1154
Baseline CT or MRI is more helpful in defining the PV anatomy.
Many PV stenoses are rigid and difficult to dilate. Even after acutely successful
angioplasty, PV restenosis occurs in up to 50% of cases.
927
,
1142
,
1143
,
1152
,
1155
Stent sizes of 9 mm or more, and especially drug-eluting stents, revealed significantly
better results, although drug-eluting stents of this size are not available.
1142
,
1143
,
1144
,
1156
Whether or not primary stenting of PV stenosis offers better results than angioplasty
alone has now been systematically studied by several groups.
1144
,
1155
The risk of restenosis is significantly less with PV stenting, providing a stent of
8–10 mm in diameter can be used. A further problem is the small sample size of the
published case series. Complications of interventional treatment of PV stenosis include
LA perforation with or without tamponade, but also PV dissection with massive bleeding,
stent embolization, and stent thrombosis.
1142
,
1143
There are limited data regarding the need for and intensity of anticoagulation and
antiplatelet therapy. For cases in which anticoagulation is otherwise indicated for
AF, a regimen including the addition of clopidogrel is most commonly used. Without
the indication for anticoagulation, warfarin and clopidogrel should be combined. The
duration of anticoagulation needed remains unclear. In the case of restenosing PVs,
anticoagulation for life might be necessary. In the setting of stable PV stents over
the course of 1–2 years, clopidogrel and, subsequently, warfarin can be discontinued.
The role of NOACs in PV stenosis has not been readily studied. Surgical patch repair
of primary PV stenosis in children reveals a 5-year success rate of 67%, with an in-hospital
mortality of 10%.
1157
Only one case of surgical treatment of severe PV stenosis with patch implantation
after catheter ablation has been reported.
1158
Thus, it remains unclear whether the results are better than with conventional interventional
treatment. Connecting the patch to the proximal end of the stenosis is difficult,
because this end is buried in the lung parenchyma. Given this challenge, and the excessive
risk, there is no foundation for recommending its use in patients with recurrent PV
stenosis after AF ablation, and decision making cannot be based on a single case report.
Even for patients with recurrent severe and persistent problems due to restenosis
despite interventional treatment, recurrent infection and hemoptysis are uncommon,
readily manageable, and the need for lobectomy or pneumonectomy is very rare. In the
largest series of PV stenosis to date, both patients who underwent subsequent pneumonectomy
at outside institutions died during or after surgery.
1155
Although lung transplantation can be considered in a case of congenital PV stenosis,
1159
this has never been required in AF-ablation patients. Dealing with patients with fibrosing
mediastinitis and PV or peripheral artery (PA) stenosis is, in contrast, exceptionally
difficult.
1160
Successful PV angioplasty or stenting usually results in a significant relief of symptoms.
1142
,
1143
,
1144
,
1145
,
1155
,
1156
Thus, follow-up strategies and intensity should be based on symptoms. Patients with
restenosis usually report an increase of complaints existing prior to the intervention.
In such cases, MRI is recommended. There is an additional critical consideration in
dealing with PV stenosis. With the decline in follow-up CT scans after AF ablation,
the occurrence of serious stenosis, hemoptysis, permanent PV occlusion, scarring,
lung infarction, and intraparenchymal hemorrhage has increased. Many such patients
are being inappropriately evaluated for lung cancer because of the appearance of intraparenchymal
hemorrhage. Candidate veins for intervention are also increasingly problematic. These
are more difficult to open and have a higher restenosis rate, requiring repetitive
reintervention. Because of this, it is recommended that if a patient does not undergo
a routine follow-up 3-month CT or MR, at a minimum, those with recurrent pulmonary
symptoms after AF ablation should be scanned to exclude PV stenosis. Patients should
also be routinely screened for symptoms at the time of follow-up evaluations. The
take-home message is to identify PV stenosis before it becomes a serious problem.
Atrial Esophageal Fistula, Atrial Pericardial Fistula, and Esophageal Hematoma
Esophageal injury is one of the most important complications associated with catheter
and surgical ablation of AF. In this section of the document we will focus on three
types of esophageal injury: (1) esophageal hematoma, (2) atrial pericardial fistula,
and (3) AEF. We will consider esophagopericardial fistula and AEF as one topic, and
will focus mainly on this serious and often lethal complication of AF ablation. However,
to be complete, we will also comment on the recently described complication of an
esophageal hematoma.
Esophageal Hematoma
The esophagus can be injured directly as a result of trauma from a transesophageal
probe. Esophageal hematoma is a recognized complication after a transesophageal echo
study, which can be performed in association with the ablation procedure.
1161
A recent study reported that 0.27% of the patients who underwent an AF ablation with
a preprocedure TEE experienced this complication. The predominant symptoms were pain
on swallowing, regurgitation, and hoarseness, with an onset within 12 hours of the
procedure. Fever and neurological symptoms were not present. The diagnosis was established
by a CT scan, which ruled out an AEF and revealed a hematoma localized to either the
upper esophagus or extending the length of the esophagus. Endoscopy can further confirm
the diagnosis. Conservative management is advised. Long-term consequences of this
complication include an esophageal stricture, esophageal dysmotility, and vocal cord
paralysis.
1161
AEF and Atrial Pericardial Fistula
Esophageal ulceration, perforation, or development of a left AEF or atrial pericardial
fistula, have been reported after both catheter ablation of AF and surgical ablation
of AF using unipolar RF current.
806
,
866
,
920
,
1162
,
1163
,
1164
,
1165
,
1166
,
1167
,
1168
,
1169
It is a possible complication after catheter ablation using any energy modality that
produces transmural atrial lesions. Although early reports showed AEF resulting from
RF ablation, more recently, AEFs have also been reported after CBA.
877
,
878
,
879
,
1170
An adequately powered study examining the relative frequency of this complication
with the two primary ablation modalities has not yet been performed. AEFs have also
been reported following ablation with a focal ultrasound balloon ablation system that
is no longer clinically available.
705
,
1167
Esophageal erosion has also been reported with a circular multielectrode irrigated
RF ablation system.
1171
It is notable that 51% of the writing group members report having had a patient at
their center develop an AEF following AF ablation. It should be clear, however, that
the occurrence of an esophageal ulcer is not the same as an AEF. Although AEFs can
be accompanied by ulcers, the presence of an ulcer is not predictive of an AEF. Occurring
in 10%–40% of patients undergoing an AF ablation, the prevalence of an AEF is closer
to one in one thousand in those with an ulcer.
Although the precise mechanism of esophageal tissue injury is not understood, potential
mechanisms include direct thermal injury, acid reflux, infection from the lumen, and
ischemic injury through thermal occlusion of end arterioles. It has been hypothesized
that vagal damage resulting from ablation on the posterior LA wall can cause gastroesophageal
reflux by damaging the vagal nerves that run along the esophagus, altering the lower
esophageal sphincter pressure. This hypothesis proposes that high esophageal acid
production could contribute indirectly to the formation of AEFs.
1172
,
1173
This hypothesis is attractive; however, one study that attempted to validate it by
measuring esophageal acid levels post-AF ablation was negative.
1173
The prevalence of esophageal reflux and an AEF are also very different.
Although the development of an AEF following AF ablation is a very uncommon complication,
its importance rests in the lethality of this complication. The Updated Worldwide
Survey on the Methods, Efficacy, and Safety of Catheter Ablation for Human Atrial
Fibrillation reported an AEF in six patients (0.04%).
920
This incidence was similar to a separate survey of members of the Heart Rhythm Society.
In this survey, an AEF was reported in 6 of
20
,
425
patients (0.03%).
1168
All six of these patients experienced major cerebrovascular events, and five (83%)
died. In contrast to an AEF, which is very rare, subclinical injury to the esophagus
is extremely common following AF ablation. A more recent study reported an AEF incidence
of 0.11%. In a number of studies, an endoscopy has been performed to screen for esophageal
injury 1–3 days following AF ablation.
1174
Esophageal tissue injury has been reported in up to 50% of patients.
637
,
882
,
1175
Observed asymptomatic esophageal ulcers were usually healed on repeat endoscopy at
2–3 weeks.
1176
One study reported endoscopy performed on 267 patients who underwent RF ablation.
The power on the posterior wall was limited to 25 W. Among these patients, 6 (2.2%)
had either erythema (n = 2) or a necrotic ulcer (n = 4) on endoscopy. Multivariate
analysis revealed that the distance between the LA and the esophagus was the only
independent predictor, although an LA isthmus line and CS ablation showed a trend.
900
After treatment with a PPI (pantoprazole or esomeprazole) and sucralfate, all recovered
without development of an AEF. One study reported a higher incidence of esophageal
injury among patients undergoing AF ablation with general anesthesia compared with
conscious sedation.
637
It has been proposed that this relationship reflects the absence of pain feedback
and reduced esophageal motility resulting from general anesthesia.
The clinical manifestations of an AEF usually present 2–4 weeks after the ablation
procedure. The most common symptoms are fever and recurrent neurological events (septic
emboli), but patients can present with septic shock, esophageal bleeding, or death.
A recent case series of 53 patients who developed an AEF following AF ablation reported
a mean interval between the procedure and presentation of 20 ± 12 days, ranging from
2 to 60 days. In this series, fever was the most common presenting symptom, followed
by neurological deficits and hematemesis.
1176
The preferred diagnostic modality is a chest CT scan.
1169
,
1176
It is important to recognize that a normal chest CT scan does not rule out the presence
of an AEF with 100% sensitivity. Ongoing vigilance and evaluation are important if
the clinical suspicion is high. Although a barium swallow can detect a fistula, its
sensitivity is low. IV contrast is much more likely to demonstrate a lesion passing
from the esophagus to the mediastinum, the pericardium, or the LA. If an AEF is suspected,
endoscopy with air insufflation should be avoided, given that insufflation of the
esophagus with air can result in a large air embolus, producing stroke or death. An
alternative strategy, which some members of the writing group employ and which appears
to have lower risk, is to use CO2 instead of air for insufflation in this setting.
If CO2 were introduced into the LA, there would be little adverse consequence. The
early recognition of an AEF can be missed due to the low awareness of this rare complication.
It is important for patients to be educated as to warning signs and to contact their
AF ablation center should any suggestive symptoms develop.
Considerable efforts have been made to reduce the frequency of this complication.
Approaches that have been proposed include avoiding ablation on the posterior wall
of the atrium (or at least over the trajectory of the esophagus), reducing RF power
on the posterior wall (to 25 W or less), using ICE to image the esophagus, and using
an esophageal temperature sensor.
637
,
900
Many institutions use an esophageal temperature probe to prevent thermal injury; however,
it is widely acknowledged that use of an esophageal temperature probe does not eliminate
the risk of esophageal injury.
341
,
417
,
910
A survey of the writing group members shows that 87% use lower RF power on the posterior
wall. This survey also reveals that two-thirds routinely use an esophageal temperature
probe. Among those who use a temperature probe, one-third report using a temperature
probe with multiple temperature sensors, whereas two-thirds use a probe with only
one temperature sensor. It is important to recognize that the temperature probe should
be as close as possible to the ablation catheter at all times during the procedure.
Another variable concerns when to stop power delivery. Whereas some operators ablate
until a predefined temperature has been met (e.g., 39 °C or 40 °C), other operators
use a more conservative approach and terminate power when the esophageal temperature
increases by as little as 0.2°. Esophageal temperature monitoring is also commonly
used during CB AF ablation. Energy delivery is generally stopped when the esophageal
temperature is lower than -20 °C. An alternative approach to the prevention of this
complication is to move the esophagus away from the site of ablation using an endoscope
or stylet positioned through a chest tube.
894
,
895
,
1177
None of the writing group members employ this strategy. Other widely used strategies
include the use of PPIs; although this approach is unproven, it has become a common
approach. Seventy-two percent of the writing group members employ a PPI for 1–4 weeks
following AF ablation. Use of PPIs is more common following RF ablation (95%) compared
with CBA (54%). It is important to note, however, that this practice is based on the
observation that esophageal ulcerations can be observed on endoscopy following ablation.
There is no proof that this approach reduces the development of an AEF.
Treatment of an AEF is a medical emergency that requires urgent surgical repair.
341
,
417
,
906
,
910
,
911
,
1169
,
1176
,
1178
Recent case series have reported an 83% to 100% mortality without surgical repair
compared with a 34% mortality with surgical repair.
341
,
417
,
906
,
910
,
1176
Although several case reports have been published describing favorable outcomes with
esophageal stent placement for treatment of an esophageal perforation or an esophageal
pericardial fistula, the mortality rate for stent placement in a patient with a true
AEF approaches 100%.
341
,
417
,
905
,
907
,
910
,
911
In summary, AEF is a rare but unpredictable complication with severe consequences
that might only be mitigated by cautious use of energy on the posterior wall of the
LA, early detection, and intervention. Prompt diagnosis and surgical treatment are
typically required. Support for the use of esophageal stenting is limited, and progression
of the AEF process can still occur despite this stenting procedure.
Gastric Hypomotility and Periesophageal Vagal Nerve Injury
Injury to the vagal anterior esophageal plexus can occur when RF energy is applied
to the posterior wall of the LA, which can cause acute pyloric spasm and gastric hypomotility.
Common symptoms include nausea, vomiting, bloating, and abdominal pain developing
within a few hours to a few weeks after the ablation procedure.
1018
,
1020
,
1179
,
1180
,
1181
Some patients also experience sinus tachycardia.
1180
The incidence of symptomatic gastric problems can be as high as 17%.
1020
,
1181
One recent study reported that asymptomatic functional impairment of the upper GI
tract occurred in 74% of patients. After AF ablation, although the abnormality is
often asymptomatic, the time to recovery is variable, with some patients recovering
within 2 weeks, but others requiring a much more protracted time to recovery.
536
The initial evaluation can include endoscopy or a barium swallow study to look for
residual food after an overnight fast. CT shows marked gastric dilation. Solid food
labeled with technetium-99 can demonstrate delayed gastric emptying. The 13C-acetate
breath test has been reported to be a noninvasive alternative to scintigraphy.
1182
Real-time MRI has been used to assess gastric motility and pyloric spasm.
1179
In addition, electrogastrography can reveal gastric dysrhythmia with bradygastria
in patients after ablation.
1183
The integrity of the vagal innervation to the gastrointestinal system can be assessed
by the pancreatic polypeptide response to sham feeding. Patients with this complication
exhibit an abnormal kinetic and peak response. The normal response is a biphasic increase
in pancreatic polypeptide. Injury to the vagus nerve impairs the first phase of the
response.
1017
After sham feeding, pancreatic polypeptide level elevation by less than 50% from baseline
was considered as abnormal.
Management of this complication depends on the severity of symptoms and whether gastric
immotility or pylorospasm predominates. Small, low-fat, and low-fiber meals can alleviate
symptoms. Intravenous erythromycin can be effective in the acute stage to improve
diabetic gastroparesis but has not been evaluated post-AF ablation.
1184
Metoclopramide can be used to promote gastric motility for 1–3 months, but long-term
treatment is associated with a risk of movement disorders. Botulinum injections or
surgery might be required to alleviate pyloric spasm.
1185
In severe cases, surgery or gastric pacing might be required.
1185
Although there is no established method to prevent injury to the vagal nerves, the
risk can be reduced by using the same techniques used to avoid an AEF, described earlier
in this document. A recent report identifies higher BMI and limiting the power to
20–25 W on the posterior LA wall as protective against periesophageal nerve injury
during AF ablation.
1020
Phrenic Nerve Palsy
PN palsy is an important complication of AF ablation and results from direct thermal
injury.
536
,
903
,
1017
,
1182
,
1183
,
1184
,
1185
The right PN is most commonly affected, given it descends in close proximity to sites
of ablation in the SVC and both right-sided PVs (Figure 1
).
536
,
903
,
1184
,
1185
,
1187
It courses slightly further from the RIPV so that injury during treatment of this
vein is less common than that occurring with RSPV ablation. PN palsy is observed with
all technologies for AF ablation, including RF, cryoablation, ultrasound, and laser
ablation.
490
,
536
,
903
,
1017
,
1182
,
1183
,
1184
,
1185
,
1187
PN palsy can be asymptomatic or can cause dyspnea, tachypnea, cough, hiccups, and
thoracic pain. The diagnosis is suggested when newly elevated hemidiaphragm with atelectasis
of the ipsilateral lung base is observed on postprocedure chest radiograph. When suspected,
diaphragm excursion should be evaluated using fluoroscopy (sniff test) or ultrasound
to confirm the diagnosis. Of the writing group members, 64% report having had a patient
at their center develop permanent PN palsy, and 36% of the writing group members report
having had a patient at their center develop permanent PN palsy following AF ablation
with RF energy.
The most common scenario in which PN injury occurs is with CBA, with an incidence
of transient PN palsy of 3.5%–11.2%.
462
,
1075
,
1188
,
1189
Permanent PN palsy resulting from CBA is far less common, with an incidence of 0.3%
in the recently completed FIRE AND ICE trial.
490
PN palsy has also been reported with the laser-balloon ablation system. In the HeartLight
study of the laser balloon, diaphragmatic paralysis secondary to PN injury occurred
in 3.6% of the patients with the laser balloon and was more common than with RF ablation.
Persistent PN paralysis at 1 year occurred in 1.8% of the patients.
503
The hot balloon ablation catheter employs a compliant balloon filled with saline that
is inflated to occlude the PV.
706
Because of the mechanism of balloon heating, the possibility of hot spots forming
in deeper tissue planes or in collateral structures such as the esophagus is unlikely.
707
The main reported complications with this technology were PN palsy (3.4%) and PV stenosis
(1.7%).
708
A recent, prospective, multicenter clinical trial compared the outcomes of hot balloon
ablation vs AAD therapy for PAF.
706
The incidence of PN injury was 3.7%.
Several mechanisms have been proposed to explain the increased incidence of balloon-based
(CB, laser balloon, hot balloon) AF ablation and PN injury. First, wedging or exerting
force to direct the balloon into the RSPV for complete PV occlusion can distort the
anatomy and decrease the distance between the RSPV endocardium and the right PN.
1190
Second, a small balloon size relative to PV diameter can increase the likelihood of
distal ablation in the vein.
779
Third, the broader, circumferential thermal gradient and use of additional freeze
cycles can increase risk of dose-dependent nerve palsy.
1075
Studies have shown a higher risk of PN injury associated with the smaller 23-mm balloon
compared with the larger 28-mm balloon with more proximal energy application.
462
,
482
The smaller balloon is potentially advanced further within the PV, causing distortion
of the anatomy, creating a higher susceptibility to PN thermal injury. PN palsy can
also occur during WACA using RF energy. This likely results from thermal injury to
the PN as it courses anterior to the right PVs.
The second most common scenario of PN palsy is during electrical isolation of the
SVC using point-by-point RF ablation; the reported incidence is 2.1%–10%.
1191
,
1192
Ablation within a persistent left SVC can result in left PN paralysis, but appears
rarely, and has been associated with the use of CB.
1193
Injury to the left PN during isolation of a persistent left SVC was not observed in
several case series using RF energy.
232
,
1042
,
1194
,
1195
Very rarely, ablation at the roof of the LAA can result in left PN damage
1184
; however, it was not observed in a large study in which LAA isolation was performed
using RF ablation.
532
,
533
The incidence of PN palsy is 0.17%–0.48% with PV antrum isolation using RF ablation,
even though the PN is found within the typical WACA and carina lines of the right-sided
PVs in 30% of patients.
808
,
920
,
1184
,
1196
This highlights the importance of factors other than anatomic proximity alone contributing
to the higher incidence of injury with CB.
A number of strategies have been employed to prevent PN palsy. These include limiting
ablation to antral regions with various balloon maneuvers; preablation high-output
pacing to establish whether the PN can be captured from the proposed ablation site
before ablation; PN mapping with anatomic tagging of its course using an EAM system
to guide the modification of the ablation lesion set; and monitoring of diaphragmatic
excursion with abdominal palpation, fluoroscopy, or intracardiac ultrasound while
pacing the PN from the SVC or subclavian vein during ablation.
1196
Monitoring the effects of pacing the right PN is now considered a standard part of
CBA and should be considered during SVC isolation using RF energy. Of the writing
group members, 96% report employing this technique when performing CB AF ablation.
Finally, diaphragmatic electromyography for direct monitoring of diaphragmatic compound
motor action potentials (CMAP) during ablation is a technique for early detection
of PN palsy that has been reported to reduce incidence of palsy.
1197
,
1198
CMAPs are recorded using body surface electrodes, esophageal electrodes, or a diagnostic
catheter positioned in the hepatic vein. A decrease in the amplitude of the myopotential
by 30% is more sensitive than abdominal palpation for predicting the subsequent reduction
in diaphragmatic excursion and nerve palsy.
1199
Energy delivery should be interrupted immediately at the first sign of PN injury.
One-third of the writing group members report employing this technique when performing
CB AF ablation. One-third of the writing group members also report pacing anterior
to the right PVs to tag the PN when performing AF ablation using RF energy.
PN palsy can be asymptomatic or can cause dyspnea, tachypnea, cough, hiccups, and
thoracic pain.
903
,
1017
,
1184
,
1187
The diagnosis is suggested when newly elevated hemidiaphragm with atelectasis of the
ipsilateral lung base is observed on postprocedure chest radiograph. When suspected,
diaphragm excursion should be evaluated using fluoroscopy (sniff test) or ultrasound
to confirm the diagnosis.
There are various stages of PN palsy, ranging from detectable decrease in CMAP before
a reduction in diaphragmatic excursion is perceived to persistent paralysis. With
CBA, most PN injuries are transient and resolve within minutes.
903
,
1184
In patients with persistent nerve palsy, most recover nerve function within weeks
and almost all by 12 months, although 18–24 months might be required in some patients.
1200
In a large meta-analysis of 22 studies enrolling 1308 patients undergoing CBA, 4.7%
had persistent PN paralysis after the ablation procedure, but only 0.37% had paralysis
lasting longer than 1 year.
482
The pathophysiology of the palsy differs by type of ablation energy. With RF ablation,
there is a dose-dependent response, and permanent palsy is characterized acutely by
edema, coagulation, and homogenization of cytoplasmic contents and smearing of nuclear
chromatin.
536
With CB, the palsy is also dose-dependent; however, histopathology studies have shown
Wallerian degeneration of large myelinated axons, and that axonal regeneration accounts
for late recovery of nerve function.
1201
There is no active treatment known to facilitate PN healing; however, in symptomatic
patients with permanent nerve palsy, diaphragmatic plication can improve dyspnea and
functional status.
Stroke, TIA, and Silent Microemboli
Stroke and TIA
Embolism of air or thrombus is one of the most significant complications of AF ablation,
and both are potential causes of cerebral, coronary, and peripheral vascular compromise.
The incidence of thromboembolism associated with AF ablation is reported to be between
0% and 7%.
242
,
489
,
503
,
532
,
533
,
655
,
673
,
796
,
798
,
799
,
806
,
920
,
921
,
1202
,
1203
,
1204
More than two-thirds of the clinical trials reviewed for preparation of this document
reported one or more cerebrovascular events. Thromboembolic events typically occur
within 24 hours of the ablation procedure, with the high-risk period extending for
the first 2 weeks following ablation.
798
,
1204
In one series that surveyed 26 embolic stroke events that occurred in a series of
3060 patients, long-term neurological outcomes were as follows: severe impairment
(3 patients, with 2 possibly related deaths); moderate impairment (10 patients); mild
impairment (9 patients); and unknown (4 patients).
1202
A number of potential explanations for the development of thromboembolic complications
have been proposed. These include the development of thrombi on or within stationary
sheaths or ablation catheters positioned within the LA, char formation at the tip
of the ablation catheter and at the site of ablation, disruption of a thrombus located
in the atrium prior to the ablation procedure, and electrical cardioversion during
procedures.
875
Incidence of these events can be reduced by a combination of detailed preprocedural
imaging, a strict anticoagulation protocol, meticulous attention to sheath management,
and careful control of RF energy to minimize the risk of char formation. Of the writing
group members, 68% report maintaining a constant heparinized flush through all long
sheaths with access to the LA, and most heparinize to an ACT >300 seconds before transseptal
catheterization.
Diagnosis of a symptomatic thromboembolic event is usually straightforward when ischemia
or infarction results from arterial occlusion interrupting perfusion of dependent
tissue. The potential manifestations depend on where the occlusion occurs, whether
it be intracranial, coronary arterial, abdominal, or in other peripheral arterial
beds. We have previously discussed the prevention of thromboembolism by intraprocedural
and postprocedural anticoagulation in Section 7: Technical Aspects of Ablation to
Maximize Safety and Anticoagulation. Treatment of a thromboembolic event will vary
according to the location of the embolus. Peripheral arterial embolization might be
amenable to surgical thrombectomy, whereas cerebral embolization has traditionally
been managed conservatively and the consequences accepted. There is growing interest,
however, in aggressive early management of such events, using either thrombolytic
drugs or percutaneous interventional techniques. Some delay in diagnosis of a thromboembolic
event that occurs during an ablation procedure while a patient is under general anesthesia
cannot be avoided.
Asymptomatic Cerebral Emboli
ACE is defined as an occlusion of a blood vessel in the brain due to an embolus that
does not result in any acute clinical symptoms and is therefore “silent.”
800
,
1205
Emboli can result from a thrombus, air, gas, tissue, or fat. During an AF ablation
procedure, potential sources of these microemboli include thrombi, which can develop
on intracardiac catheters; sheath materials; air introduction through a sheath during
catheter insertion or exchanges; dislodgement of thrombi in the heart; or as a result
of thrombi or gas that forms during the ablation process. Diffusion-weighted MRI (DW-MRI),
with or without fluid-attenuated inversion recovery (FLAIR) imaging, is very sensitive
for identifying acute ischemic injury and can detect a cerebral lesion created by
an embolus as early as 30 minutes postablation.
The first report of ACE lesions following AF ablation was published in 2006.
1206
In this report, 2 of 20 patients developed new asymptomatic cerebral lesions on MRI,
following AF ablation. Subsequent to this report, multiple studies have reported that
DW-MRI can detect new acute lesions created by emboli, following up to 50% of AF ablation
procedures.
723
,
724
,
800
,
1205
,
1207
,
1208
,
1209
The incidence of this complication initially appeared to vary according to the system
used for ablation, and was reported to be highest with the use of nonirrigated circumferential
multielectrode ablation catheters with duty cycled phased RF energy.
1209
,
1210
Based on these findings, modifications were made in anticoagulation, sheath management,
and energy delivery protocols. Following introduction of these modifications, two
subsequent studies reported a 2% or lower incidence of ACE lesions with use of this
same circular phased RF ablation catheter.
728
,
731
,
1211
One study examined the important question concerning whether these lesions persist
on repeat DW-MRI and T2 FLAIR scanning. In this study, 14 patients who had 50 new
silent cerebral emboli detected post-AF ablation had a repeat MRI a median of 3 months
later. It was notable that 47 of the 50 lesions (94%) resolved in the interim. The
three lesions in three patients that produced a residual defect at repeat scanning
were initially >10 mm in size, and one of these patients had neurological symptoms.
When considering the significance of the ACE lesions that have been observed following
AF ablation, it is important to note that cerebral embolism has also been observed
after most types of cardiac invasive procedures, including coronary angiography, carotid
artery stenting, and cardiac valve replacement.
1212
,
1213
Importantly, as of now, a direct link between silent cerebral embolism and a decline
in neurocognitive function has not been proven.
800
,
1205
,
1211
,
1212
However, one study has reported mild postoperative neurocognitive dysfunction in 13%
of patients undergoing ablation for PAF and in 20% undergoing ablation for persistent
AF. The precise mechanism of this neurocognitive dysfunction and its possible link
to ACE lesions needs to be explored further.
1214
A decade after the first description of ACE lesions following AF ablation, a tremendous
amount of new knowledge has been generated concerning this important complication
of AF ablation.
800
,
1205
,
1211
,
1215
,
1216
These efforts have resulted in a striking decrease in the incidence of this complication.
During this period of time, studies have identified a number of techniques to lower
the risk of ACE lesions, including (1) aggressive anticoagulation prior to, during,
and following ablation; (2) careful sheath management; (3) modifications in the delivery
of phased RF energy; and (4) choice of ablation energy source and lesion sets. The
long-term prognostic implications of ACE following AF ablation remain unclear. Because
multiple studies have reported that the majority of acute lesions regress without
evidence of chronic glial scar when reassessed several weeks to months later, the
occurrence of long-term sequelae appears unlikely.
1205
Nevertheless, there is a possibility of long-term sequelae, given the association
between silent cerebral infarcts and an increased long-term risk of dementia.
1217
While further work remains, the amount of progress is striking and will benefit our
patients in the long term.
Air Embolism
The most common cause of air embolism is introduction of air via the transseptal sheath.
Although this can be introduced through the infusion line, it can also occur with
suction when catheters are removed. Air embolism has been reported with coronary angiography,
percutaneous interventions requiring access to the LA, and during ablation procedures.
803
,
1218
,
1219
,
1220
,
1221
Air embolism to the cerebral vasculature can be associated with altered mental status,
seizure, and focal neurological signs. Central nervous system dysfunction is attributable
to both mechanical obstruction of the arterioles and thrombotic-inflammatory responses
of air-injured epithelium.
1219
,
1220
Although immediate diagnosis and treatment is based on clinical suspicion, prompt
MRI or CT scans obtained before the intravascular air is absorbed might show multiple
serpiginous hypodensities representing air in the cerebral vasculature, with or without
acute infarction.
803
,
1221
Most importantly, AEF should be ruled out if air embolism is documented after the
ablation. A common presentation of air embolism during AF ablation is acute inferior
ischemia and/or heart block. This reflects the preferential downstream migration of
air emboli into the right coronary artery (RCA). The preferential manifestation of
air emboli into the RCA territory might reflect the superior position of the RCA ostium
in the supine patient. Supportive care usually results in complete resolution of symptoms
and signs within minutes. However, pacing and cardiopulmonary resuscitation might
be needed if the hypotension and AV block persist. A recent study reported the clinical
characteristics and outcomes of 5 out of a series of 2976 patients who underwent AF
ablation who experienced a massive air embolism during the procedure. Hemodynamic
collapse and hypoxemia occurred in all the patients and persisted for 10–35 minutes.
Despite this, all the patients had complete recovery.
1221
it is imperative, however, that all infusion lines be monitored closely for bubbles.
Whenever catheters are removed, they should be withdrawn slowly to minimize suction
effects, and the fluid column within the sheath should be aspirated simultaneously.
Particular care is advised when inserting and removing balloon catheters through large
sheaths.
1222
Treatment should be initiated immediately in the laboratory if cerebral air embolism
is suspected. The most important initial step is to maximize cerebral perfusion by
the administration of fluids and supplemental oxygen, which increases the rate of
nitrogen absorption from air bubbles. For large air emboli, it might be beneficial
to briefly suspend the patient in a head-down position.
1218
,
1219
Treatment with hyperbaric oxygen can reverse the condition and minimize endothelial
thromboinflammatory injury if it is started within a few hours.
1220
Heparin appears to limit injury in animal models of cerebral arterial air embolism.
1223
Vascular Complications
Vascular complications, including groin hematoma, retroperitoneal bleed, femoral artery
pseudoaneurysm, or arteriovenous fistula, are the most common complications of AF
ablation. The incidence of the more significant of these complications (femoral pseudoaneurysm,
arteriovenous fistula, and retroperitoneal bleeding) varies from 0.2% to 1.5%.
806
,
808
,
920
,
921
,
1224
,
1225
,
1226
The first and updated worldwide surveys of AF ablation in 2005 and 2010, respectively,
reported that the incidence of vascular complications was 0.95% (84 of 8745 patients)
and 1.5% (240 of 16309 patients), respectively.
806
,
920
A report from the United States analyzing an estimated
93
,
801
AF ablations between 2000 and 2010 showed the overall incidence of vascular complications
requiring blood transfusion or surgical repair was 1.53%, which remained statistically
unchanged from year 2000 to 2010.
921
More recent reports from Czechia, Belgium, Japan, and the United States reported the
incidence of these complications as 1.1% (13 of 1192 procedures in 959 patients),
1.2% (15 of 1233 procedures in 947 patients), 0.2% (7 of 3373 patients), and 1.5%
(18 of 1190 patients), respectively.
808
,
1224
,
1225
,
1226
The incidence of vascular complications that result from AF ablation is lower than
those reported for ventricular tachycardia ablation (range, 3.6%–6.9%), in which femoral
arterial access is used in many cases.
1227
,
1228
Most groin hematomas can be managed conservatively or with ultrasound-guided compression.
However, complications such as femoral pseudoaneurysm, arteriovenous fistula, and
retroperitoneal bleeding might require blood transfusion and/or surgical or percutaneous
repair, which leads to increased morbidity and prolonged hospital stay.
1229
Rarely, a large dense hematoma can lead to femoral neurological sequelae.
The incidence of these complications can be related to the number and size of the
venous sheaths used, insertion of an arterial pressure line, and perhaps to the intense
anticoagulation management before, during, and after the procedure. Recent studies
have suggested uninterrupted warfarin as an optimal anticoagulation regimen because
it reduces stroke and nonmajor bleeding complications compared with interrupted warfarin
with heparin bridging.
834
Further, uninterrupted or briefly interrupted use of a direct oral anticoagulant was
shown to be as safe and effective as uninterrupted warfarin.
840
,
842
,
1230
The results of the RE-CIRCUIT study were recently published, which was a head-to-head
comparison of performing AF ablation on patients receiving uninterrupted dabigatran
vs uninterrupted warfarin.
841
This study randomized 704 patients across 104 sites to these two anticoagulation strategies.
The incidence of major bleeding events during and up to 8 weeks postablation among
the 635 patients who underwent AF ablation was significantly lower with dabigatran
than with warfarin (5 patients [1.6%] vs 22 patients [6.9%]); absolute RD -5.3%, RR
reduction 77%). There has been one other smaller head-to-head comparison published
of uninterrupted rivaroxaban vs uninterrupted warfarin (Venture-AF, N = 248).
842
This study reported one major bleeding event, one ischemic stroke, and one vascular
death, each of which occurred in the warfarin arm of the study.
The approach used for femoral venous access can impact on the risk of vascular complications.
When an inferior approach to femoral vein access is used, small medial branches of
the femoral artery, which can run across and superficial to the femoral vein, might
be penetrated before entry to the femoral vein, possibly leading to a femoral pseudoaneurysm
and arteriovenous fistula. When a superior approach is used, there is an increased
risk of retroperitoneal bleeding. To prevent these vascular complications, real-time
ultrasound-guided venipuncture is useful and can be recommended because it reduces
both major and minor vascular complications in patients undergoing AF ablation and/or
electrophysiological procedures.
1231
,
1232
Among the writing group members, two-thirds routinely use ultrasound imaging to guide
vascular access.
Acute Coronary Artery Occlusion and Stenosis
Injury to the coronary arteries during AF ablation is rare. In a consecutive series
of 5709 patients undergoing ablation of AF, coronary arterial injury was observed
to occur in eight patients (0.14%).
1233
The circumflex artery is in close proximity to the lateral LA and can potentially
be injured during ablation at sites adjacent to its course within the CS, the lateral
mitral isthmus, or the base of the LAA. Occlusion of the circumflex accounted for
three of the eight cases in the above series, all presenting with ventricular fibrillation
20 and 60 minutes after mitral isthmus ablation and 6 hours after ablation at the
LAA base, respectively.
1233
Others have also described features of acute myocardial infarction with ST segment
changes occurring during ablation at the mitral isthmus.
923
These patients have variably undergone unsuccessful intracoronary vasodilators or
thrombectomy and have had to progress to coronary stenting. A single case presenting
48 hours after mitral isthmus ablation with total circumflex occlusion and ventricular
arrhythmia storm is described as having ongoing ventricular arrhythmia requiring ablation
and defibrillator implantation, highlighting the potential for ongoing consequences
as a result of coronary artery injury.
1234
The sinus node artery originates from the proximal circumflex artery in one-third
of cases and then courses along the anterior LA and then the septal SVC, and could
therefore be susceptible to injury during ablation. In the above series, five of the
eight patients presented with acute sinus node dysfunction.
1233
In most of these cases, the culprit site was adjacent to the sinus node artery (per
CT) at the anterior LA or septal RA. All these cases presented with sinus arrest during
or within 1 hour of ablation and with no evidence of any other electrocardiographic
changes associated with coronary occlusion. Two of these patients eventually required
permanent pacemaker insertion with significant atrial pacing during follow-up. Others
have described a more transient sinus node dysfunction due to occlusion of the sinus
node artery.
1235
The cavotricuspid isthmus can be ablated in conjunction with AF ablation. This region
is in close proximity to the RCA, and injury to this vessel has been described.
1236
,
1237
These have occurred both acutely and later during the case, and with both septal and
lateral approaches to the ablation.
In addition to the direct injury and occlusion at the sites of ablation, a single
case of thromboembolic occlusion of the left anterior descending artery the day after
ablation has been described.
1238
This case was known to have factor V Leiden mutation, was therapeutically anticoagulated
with an INR of 2, and the activated clotting time had been maintained between 280
and 390 seconds. Angiography demonstrated thrombus in the left anterior descending
artery, requiring intervention. This case highlights the need for meticulous anticoagulation,
sheath management, and physician awareness of the potential for thromboembolism to
present as coronary occlusion. Although presentation with acute coronary artery occlusion
is low, the possibility of thermal injury without occlusion and the possibility of
subsequent remodeling leading to stenosis of a coronary artery should be considered.
The most vulnerable location for this would appear to be the circumflex vessel during
ablation of the mitral isthmus. In a series of 54 patients who had undergone mitral
isthmus ablation, coronary angiography was performed before and after ablation.
1239
Fifteen patients (28%) had angiographic changes following ablation, eight with midcircumflex
narrowing, one with circumflex and obtuse marginal narrowing, one with obtuse marginal
narrowing only, and five with distal circumflex narrowing or occlusion. A further
five had significant narrowing that resolved with intracoronary vasodilators. Patients
with such coronary arterial changes had a significantly longer ablation time within
the CS. Therefore, limiting excessive ablation, particularly in areas adjacent to
the coronary vasculature, should be a consideration in planning the ablation strategy.
In the intraoperative setting, late coronary stenosis has been described at sites
of previous ablation.
1240
There can be several determining factors in the development of coronary artery injury
during AF ablation. These include the degree of protective epicardial adiposity, coronary
blood flow, and the intensity and duration of ablation; however, the most predictable
is that of the location of ablation adjacent to the course of the coronary artery.
Careful monitoring and avoiding high-power energy delivery in the vicinity of these
vessels are potentially important in minimizing the risk of arterial injury.
Radiation Exposure During Catheter Ablation of AF
An important, less easily recognized, and rarely considered potential complication
of AF ablation is the delayed effect of the radiation received by the patients, including
acute and subacute skin injury, malignancy, and genetic abnormalities.
1
,
1241
,
1242
,
1243
,
1244
,
1245
,
1246
,
1247
Fluoroscopy is required for most components of the procedure, including catheter placement,
positioning a multielectrode catheter into the CS, double transseptal catheterization,
PV angiography, and LA ablation. A survey of the writing group members reveals that
two-thirds use single-plane fluoroscopy, whereas one-third employ biplane. One study
reported a mean fluoroscopy time >60 minutes, with corresponding higher effective
radiation doses in obese patients.
1244
,
1246
By using a vest containing 50–60 dosimeters to measure peak skin doses (PSDs), another
study reported a mean PSD of 1.0 ± 0.5 Gy in the right anterior oblique and 1.5 ± 0.4 Gy
in the left anterior oblique projection, during a mean fluoroscopy time of 67.8 ± 21 minutes.
1245
They estimated an overall lifetime risk of excess fatal malignancies normalized to
60 minutes of fluoroscopy of 0.07% for women and of 0.1% for men.
1245
The relatively low radiation exposure to the patients in this study despite the prolonged
fluoroscopy durations was attributable to the state-of-the-art very low pulsed fluoroscopy
frame rate, the avoidance of magnification, and the optimal adjustments of fluoroscopy
exposure rates. The resulting lifetime risk of malignancy was thus within the range
previously reported for ablation of supraventricular tachycardias. However, this study
demonstrated that catheter ablation of AF required significantly greater fluoroscopy
duration and radiation exposure than simpler catheter ablation procedures. Thus, and
especially because AF ablation procedures often need to be repeated, electrophysiologists
should make every attempt to minimize radiation exposure.
Increasing availability and familiarity of electrophysiologists with 3D mapping systems,
as well as the availability of CF monitoring, have significantly reduced fluoroscopy
time and the need for fluoroscopy in recent years.
747
,
1186
,
1248
,
1249
This can only be achieved, however, by an awareness of the importance of reducing
fluoroscopy time, and therefore radiation exposure, by the operator.
1250
It has been shown that use of optimized conventional fluoroscopy and optimized use
of 3D mapping can result in a marked reduction in radiation exposure.
1251
It is also important to recognize that fluoroscopy time is only weakly linked to true
radiation exposure, because it does not reflect the fluoroscopy equipment being used,
nor patient-specific factors such as obesity. The use of remote navigation for PVI
appears to be effective, with fewer periprocedural complications and significant reductions
in fluoroscopy exposure for both patient and operator.
749
,
1252
,
1253
Another interesting option to minimize radiation exposure to the operator and to alleviate
the orthopedic implications of conventional lead aprons is the use of a radioprotection
cabin or a suspended lead apron.
1254
More recently, it has been shown that PVI is feasible without using fluoroscopy or
with extremely limited fluoroscopy. To safely navigate catheters in the heart with
no fluoroscopy, intracardiac ultrasound is mandatory, as well as imaging integration
with preacquired CT or MRI.
763
,
1255
,
1256
Pericarditis
More than 50% of the patients who undergo catheter ablation of AF note some pleuritic
chest pain in the first several days following their procedure. It is also common
to observe a “trace” pericardial effusion following AF ablation. These largely self-limited
manifestations of AF ablation-induced pericarditis are so common and of so little
consequence that they are considered as part of the standard clinical course for patients
who undergo AF ablation rather than as a complication of the procedure. A small subset
of these patients will go on to develop more severe and clinically significant manifestations
of pericarditis. In two recent multicenter registries, pericarditis has been reported
to occur in 0.1% and 0.6% of patients, respectively.
1059
,
1257
When transmural lesions are generated during catheter ablation of AF, some epicardial
inflammation, and therefore some pericarditis, is inevitable. However, more extensive
pericarditis can complicate AF ablation procedures both acutely and at some delay.
These presentations include Dressler syndrome, pericarditis leading to delayed cardiac
tamponade, and constrictive pericarditis.
1258
,
1259
,
1260
These severe manifestations and consequences of pericarditis presented between 18
days and 3 months after their ablation procedures. The standard international practice
for a short hospital stay after AF ablation procedures can contribute to an underappreciation
of early postablation pericarditis.
There is currently no evidence to support the use of nonsteroidal anti-inflammatory
drugs (NSAIDs) or steroids to prevent AF recurrences. A single bolus injection of
low-dose hydrocortisone (100 mg) reduced the incidence of pericarditis from 2.5% to
1.1% in one recent series from Japan, but no difference in early or late recurrences
was found after AF ablation.
1261
Another Japanese study also failed to demonstrate a reduction in immediate, early,
or midterm AF recurrence with either a low-dose (hydrocortisone 100 mg) or moderate-dose
(methylprednisolone 125 mg) single steroid bolus.
Colchicine is currently the cornerstone of pericarditis treatment that occurs outside
of the AF ablation setting, although specific data after AF ablation are lacking.
In one trial, however, in which patients were randomized to a 3-month course of colchicine
(0.5 mg twice daily) or placebo, early recurrence was significantly reduced (33.5%
of placebo patients vs 16% for colchicine), and this was strongly associated with
a reduction in inflammatory mediators such as IL-6 and C-reactive protein. After a
15-month follow-up, a 37% reduction in the RR of AF recurrence was observed (number
needed to treat = 6).
985
In a subsequent randomized study of 233 patients with PAF, these investigators reported
that the long-term recurrence rate was 31% among the patients treated with colchicine
vs 49% among the placebo patients. Colchicine also resulted in an improvement in QOL.
986
Mitral Valve Trauma and Curvilinear Catheter Entrapment
Entrapment of a circular multielectrode mapping catheter by the mitral valve apparatus
is an uncommon but established complication of AF ablation.
1262
,
1263
,
1264
,
1265
,
1266
,
1267
,
1268
,
1396
It results from inadvertent positioning of a circular electrode catheter close to
the mitral valve or into the left ventricle, often during attempts to position the
catheter into the LIPV or when using such catheters to create electroanatomical maps
of the LA. This complication should be suspected when attempts to reposition the catheter
into another PV are met with resistance. When suspected, it is important to confirm
the diagnosis with echocardiography. Although successful freeing of the catheter has
been reported with gentle clockwise catheter manipulation and advancing the sheath
into the ventricle in two patients, there have also been a number of cases reported
in which the mitral valve apparatus and/or papillary muscles are torn during attempts
to free the catheter.
1263
,
1264
,
1268
,
1269
,
1396
There have also been several cases reported in which the distal tip of the circular
catheter broke off during attempts at catheter removal and had to be subsequently
removed either with a snare or with an open surgical procedure.
1263
,
1265
,
1266
We recommend that if gentle attempts to free the catheter fail, elective surgical
removal of the catheter should be performed.
It is important for all electrophysiologists who perform AF ablation to be aware of
this potentially serious complication. Every effort should be made to be certain that
the circular catheter is kept safely away from the mitral valve and that only clockwise
torque be applied to the catheter, with particular care taken when approaching the
LIPV. The incidence of this rare complication is unknown, but might have decreased
in recent years due to improved awareness.
Limited data are available regarding outcomes of AF ablation in patients with prosthetic
valves. One small, matched cohort study suggested that long-term outcomes might be
similar, but ablation procedures were longer and were associated with a numerically
higher rate of complications in patients with prior mitral or aortic valve replacement
(AVR).
908
The development of new perivalvular leak following AF ablation in a patient with a
mitral prosthesis has been reported, suggesting that care should be taken when ablating
near the annulus in such patients.
921
Mortality Risk with AF Ablation
Although AF ablation is generally considered to be safe, devastating complications
can occur rarely, some being fatal. In a recent survey, death was reported in 32 of
32
,
569
(or 1 in 1017) patients undergoing AF ablation procedures worldwide.
1039
The most frequent cause of death was cardiac tamponade, accounting for 25% of the
deaths, of which 3% occurred later than 30 days after the procedure. Stroke was responsible
in 16% of the cases, of which 6% occurred later than 30 days. AEF also accounted for
16% of the deaths, with extensive pneumonia responsible for 6%. Less common causes
of death observed in the periprocedural phase included myocardial infarction, irreversible
torsades de pointes, septicemia, sudden respiratory arrest, extrapericardial PV perforation,
occlusion of both lateral PVs, hemothorax, and anaphylaxis, which were each responsible
for 3% of early deaths.
Twenty-two percent of all deaths occurred more than 30 days after the procedure. Among
the identified causes of late death were asphyxia from tracheal compression secondary
to subclavian hematoma, intracranial bleeding, acute respiratory distress syndrome,
and esophageal perforation by the intraoperative TEE probe, with each cause contributing
to 3% of all late deaths.
It should be noted that these reported mortality risks of AF ablation came mostly
from experienced operators and centers. In the community setting, the mortality risk
of AF ablation can be much higher. Indeed, one study of
93
,
801
patients undergoing AF ablation in the United States between 2000 and 2010 showed
that one in 238 AF ablation patients were never discharged alive following their procedure.
These mortality risks were due primarily to inexperienced operators who performed
fewer than 25 procedures annually, and to low-volume hospitals that performed fewer
than 50 procedures annually.
921
When a 30-day all-cause mortality definition is used for AF ablation, AF ablation
mortality rises to 1 in 125 patients within the Medicare population (mean age of 72).
921
Awareness about the risk of death and the possible causes might help physicians set
more appropriate and efficient standards for procedural safety, and need to be considered
in the patient's decision-making process.
Stiff Left Atrial Syndrome
First described after mitral valve surgery in 1988, stiff LA syndrome was recognized
as a rare complication of LA catheter ablation in 2011.
1110
,
1111
,
1270
,
1271
,
1272
,
1273
One early report described a series of three patients with unexplained exertional
dyspnea, LA hypertension, and large V waves on LA pressure or pulmonary capillary
wedge pressure (PCWP) tracings after multiple surgical LA ablation procedures.
1271
A subsequent study prospectively collected 1380 consecutive patients undergoing ablation,
obtaining echocardiograms before and after ablation to assess for pulmonary hypertension.
1272
Excluding patients with PV stenosis or significant mitral valve disease, there were
19 patients (1.4%) with new or worsening pulmonary hypertension, LA diastolic abnormalities,
and clinical findings of dyspnea, HF, pulmonary hypertension (mean PA pressure ≥25 mm
Hg or during exercise ≥30 mm Hg), and large V waves (≥10 mm Hg and higher than mean
LA pressure tracings) on PCWP or LA pressure tracings. Other authors reported worsened
pulmonary hypertension (echocardiographic right ventricular systolic pressure (RVSP)
>35 mm Hg with increases of > 10 mm Hg) in 41 of 499 patients (8.2%) by 3 months after
ablation.
1110
These studies were flawed, however, by the low cutoff for diagnosing PA hypertension,
particularly after an ablation with excess volume delivery. Stiff LA syndrome was
also reported in 9 patients after surgical maze procedures, presenting with unexplained
dyspnea, severe pulmonary and LA hypertension, giant LA V waves, absent LA or LV A
waves, blunted X descents, and elevated left ventricular end-diastolic pressure attributed
to abnormal LA compliance and contractility.
1274
Studies have identified small LA size (≤45 mm), high mean LA pressure, severe LA scarring
(>60%), diabetes mellitus (DM), and OSA as independent predictors of pulmonary hypertension
or stiff LA syndrome postablation.
1272
The potential importance of scar burden and the extent of RF ablation to LA stiffness
or function has also been noted by other investigators. In another study of 26 patients
with mean follow-up of 80 months, LA scar by MRI was related to the number of procedures,
total RF duration, LAA EF, and expansion index.
1275
LAA EF correlated with exercise capacity at follow-up, and LA scar extent had a negative
correlation with exercise capacity. Another study reported that LA stiffness index,
derived from invasive pressure measurements and cardiac MRI volumes during sinus rhythm
(ΔP/ΔV) was higher in patients with persistent rather than PAF, older age, and prior
LA ablation.
1276
A subsequent study reported that in 70 patients with 12-month follow-up, LV diastolic
dysfunction worsened in 27% and correlated with total ablation time, concluding that
more aggressive ablation might aggravate diastolic dysfunction.
1145
The stiff LA syndrome fortunately appears to be largely responsive to diuretic therapy.
One study reported that all 19 of their patients had symptomatic improvement after
diuretic therapy, noting that diuretics appeared more effective for this syndrome
than for other forms of pulmonary hypertension.
1272
In contrast, another study reported a case of stiff LA syndrome after two AF catheter
ablation procedures that failed with furosemide and spironolactone, but which responded
to sildenafil.
927
In summary, stiff LA syndrome or worsened pulmonary hypertension appears to occur
in 1.4%–8% of patients after AF RF catheter ablation. The diagnosis of stiff LA syndrome
after AF or LA ablation should be sought for patients who present with unexplained
dyspnea with signs of right HF. Diagnosis can be made by signs of right HF in the
presence of preserved left ventricular function, pulmonary hypertension (mean PA pressure
≥25 mm Hg or during exercise ≥30 mm Hg), and large V waves (≥20 mm Hg and higher than
mean LA pressure tracings) on PCWP or LA pressure tracings in the absence of significant
mitral valve disease or PV stenosis. We also recommend that to reduce the risk of
stiff LA syndrome, judicious use of extensive LA ablation be considered in patients
with small LA size, high LA pressures, preexisting severe LA scarring, DM, or OSA.
Patients with stiff LA syndrome usually respond well to diuretics.
Cough
Cough is a specific respiratory symptom that can occur after catheter ablation of
AF. It might be a sign of underlying PV stenosis, PN injury, direct bronchial injury,
stiff LA syndrome, gastroesophageal reflux, pulmonary embolism, pericarditis, or other
iatrogenic respiratory complications such as ventilator-associated pneumonia or postprocedure
aspiration pneumonia. Although there is a paucity of data on the incidence and mechanisms
of postprocedure cough, the underlying mechanisms can vary according to the ablation
technology.
After RF ablation, cough might point to the presence of RF-induced PV stenosis. Whereas
mild PV stenosis is frequently asymptomatic, patients with more extensive and severe
PV narrowing can present with cough, dyspnea, chest pain, or hemoptysis.
1152
,
1200
Similarly, another study reported that in 18 patients with severe PV stenosis, 7 (39%)
reported cough.
462
Cough might also be a sign of RF-induced PN injury. Although a rare complication (0.48%),
RF-induced PN injury is frequently (9 of 22 patients) associated with immediate features
of dyspnea, cough, hiccup, and/or sudden diaphragmatic elevation.
1277
Cough following CBA is more frequent. In fact, as many as 1 in 6 patients can develop
a dry cough following CBA, which is usually self-limiting in 91%.
1278
Whereas the most evident mechanism for postprocedure cough is that of CBA-induced
PN injury (up to 11%), some reports suggest that the cough is caused by direct upper
airway irritation during CBA (bronchial or pulmonary injury).
1278
In an experimental model, Aryana et al showed that CBA can elicit direct and acute
bronchial inflammation, bleeding, and mucosal injury.
1277
A recent study reported ice formation within the left main-stem bronchus using real-time
bronchoscopy during CBA.
583
,
584
Given the increasing number of case reports detailing respiratory complaints after
CBA, a systematic examination of the short- and long-term consequences of CBA on normal
bronchial tissue during PVI is warranted.
Increase in Heart Rate and/or Sinus Tachycardia
A subset of patients will experience a significant increase in their resting sinus
heart rate following AF ablation.
110
Although this typically results in a 10–20 beats per minute (bpm) increase in heart
rate (well below the 100 bpm threshold to classify the increase as sinus tachycardia),
the resulting increase in heart rate can exceed 100 bpm in a very small subset of
patients. This phenomenon is related to shifts in autonomic tone following ablation
and is predictive of ablation success. This shift in autonomic tone results from ablation
of GP that are commonly located near the PV antra, as previously discussed.
110
,
121
Stimulation of GP has been shown to elicit AF by producing repetitive bursts of rapid
focal PV firing, and ablation of GP can play a role in AF treatment.
257
,
577
,
1279
Following ablation of GPs, signs of parasympathetic withdrawal such as increased heart
rate and attenuated heart rate variability can be observed, and these signs have been
associated with improved procedural outcomes.
118
,
126
,
577
,
1280
,
1281
Although the increase in heart rate and reduction in heart rate variability after
ablation typically follow a transient time course, with resolution within 3 months,
some studies have shown that the long-term persistence of these autonomic changes
is associated with improved clinical outcomes.
126
These clinical data are consistent with experimental findings demonstrating a reduction
in stellate ganglion nerve activity and subsequent AF with continuous low-level vagal
nerve stimulation.
1200
Thus, the observation of increased heart rate following ablation can be a normal finding
with potential positive prognostic implications regarding outcomes and is not necessarily
a procedural complication per se.
Section 11: Training Requirements
Overview
The strategies, specific methods, and technology pertaining to AF ablation are evolving.
Accordingly, the guidelines for training to perform this procedure must be flexible
in recognition of various approaches and technologies that will change with advances
in the field. Training for AF ablation should encompass six fundamental principles:
(1) appropriate selection of patients; (2) knowledge of the anatomy of the atria and
adjacent structures; (3) conceptual knowledge of strategies to ablate AF; (4) technical
competence; (5) recognition, prevention, and management of complications; and (6)
appropriate follow-up and long-term management.
The training required in each of these areas differs from other ablation procedures
because, in comparison, ablation of AF is technically more difficult, is associated
with greater risks, and requires more careful follow-up.
Appropriate Selection of Patients
Trainees should recognize clinical attributes that can increase the difficulty of
a transseptal puncture, increase the risk of the procedure, and affect short- and
long-term outcomes. These factors are discussed in Sections 8 and 9 of this document.
The trainee should also develop the judgment to decide whether conscious sedation
or general anesthesia would be most appropriate for the case under consideration.
It is also important to assess the severity of symptoms related to AF and the potential
benefit of an ablation procedure. Trainees should be experienced in counseling patients
about the potential risks and benefits of, as well as the alternatives to, an ablation
procedure and should be able to apply this knowledge for recommendations specific
to the needs of individual patients. They should also take into consideration the
prior use of AADs and pharmacological alternatives to AF ablation.
It is also important for electrophysiologists involved with catheter ablation to be
knowledgeable about surgical ablation techniques for AF. In particular, electrophysiologists
who perform AF ablation procedures must be aware of the indications, techniques, and
outcomes of surgical approaches for AF ablation. This applies both to the new minimally
invasive surgical approaches, AF surgery combined with other cardiac surgical procedures,
and the Cox-Maze III procedure (see Section 12).
Anatomy of the Atria and Adjacent Structures
Detailed knowledge about the anatomy of the LA and its adjacent structures is crucial
for performing the technical aspects of transseptal puncture and cannulation, LA mapping,
and isolation of the PVs or modification of the substrate that sustains AF. The trainee
must recognize the anatomic relationship of the atria, SVC, and PVs to the pulmonary
arteries, aorta, mitral annulus, PNs, sympathetic and parasympathetic innervation,
esophagus, and other mediastinal structures (Figure 1
). These anatomic relationships affect the ability to perform the procedure successfully
and to avoid complications.
Conceptual Knowledge of Strategies to Ablate AF
Trainees should understand the pathophysiology of AF and its implications for strategies
to ablate AF. This includes the role of the PVs, the SVC, the musculature of the LA,
and the potential impact of autonomic stimulation. They should understand the rationale
for isolation of the PVs and elimination of the foci that trigger AF, as well as the
basis for broad circumferential ablation of tissue or elimination of fractionated
potentials or other technologies that appear to alter the substrate that sustains
AF.
Technical Competence
The technical skills needed for ablation of AF are substantial. These include anticoagulation
management, transseptal needle puncture and cannulation of the LA, precise manipulation
of the catheter for mapping and ablation, identification of the pulmonary ostia, adjustment
of the energy used for ablation, and the appropriate use of fluoroscopy, radiographic
contrast for imaging, 3D mapping systems and/or ICE. Simulation technologies are evolving
that could help trainees gain experience with fundamental techniques in the early
phase of learning procedural skills or the recognition and management of acute complications
such as cardiac tamponade.
1250
,
1282
,
1283
There are substantial differences among laboratories in the use of radiographic contrast
imaging, EAM or echocardiography, and the number and types of catheters used to identify
electrical endpoints and to perform ablation. The degree of expertise gained in the
use of a specific technology will depend on where training is completed, as well as
the duration of training. Nonetheless, trainees should be expected to understand the
potential advantages and limitations of these systems and should have the ability
to interpret basic images and electrical recordings obtained from these various methodologies.
They should be well versed in the principles of radiation safety for patients and
the medical personnel who perform ablation procedures.
Training programs should emphasize the interpretation of intracardiac electrograms
for recognition of PV potentials and determination of when electrical isolation of
a PV has been achieved, the role of CS and LAA pacing in the differentiation of far
field electrograms from PV potentials, identification of fractionated low-amplitude
LA potentials, and techniques required to map and ablate right and/or LA tachycardias
or AFL. Concepts related to entrainment are especially important. Trainees need to
be skilled in identifying the presence, mechanism, origin, and ablation of other supraventricular
tachycardias that could act as triggering mechanisms for AF, such as AV nodal reentrant
tachycardia and AV reentrant tachycardia. Training and competence in RF catheter ablation
are essential because this ablation technology is needed for ablation of typical and
atypical AFL. Many electrophysiology laboratories also use RF energy as the preferred
energy source for ablation of AF. Many other electrophysiologists prefer CBA for their
AF ablation procedures. Other ablation technologies that are currently available in
some parts of the world include laser balloon ablation and ablation using circular
multielectrode RF ablation catheters. Trainees should be familiar with the advantages
and limitations of each energy source and associated delivery system.
Procedural Experience
The 2015 American College of Cardiology/American Heart Association/Heart Rhythm Society
Advanced Training Statement on Clinical Cardiac Electrophysiology proposed a minimum
of 5 five focal ATs, 30 macroreentrant ATs (including 20 isthmus- and 10 nonisthmus-dependent/complex
macroreentry) and 50 AF ablation procedures for those who undergo fellowships in clinical
cardiac electrophysiology.
1284
The writing group members are supportive of the requirement that trainees perform
at least 50 AF ablation procedures and at least 30 macroreentrant ATs (including 20
isthmus- and 10 nonisthmus-dependent/complex macroreentry) during fellowship training.
Furthermore, the writing group recommends that those performing the procedure perform
at least several AF ablation procedures per month to maintain competence.
These numbers underestimate the experience required for a high degree of proficiency.
991
,
992
,
1082
,
1285
,
1286
Exact numerical values are difficult to specify because technical skills develop at
different rates. Nonetheless, comparisons of high- and low-volume centers suggest
that outcomes are better at centers that have performed more than 100 procedures.
806
Other data report improved outcomes for operators with an annual procedure volume
of at least 25 cases and for centers with an annual procedure volume of at least 50
cases.
921
Moreover, the selection of patients and interpretation of AFL and other ATs that are
often observed in patients with AF require training that is unique to electrophysiology
fellowships. Trainees who intend to perform AF ablation independently should receive
additional training after the standard fellowship is completed if they performed fewer
than 50 AF ablation procedures during training.
Recognition, Prevention, and Management of Complications
As previously discussed, ablation of AF is associated with substantial risks that
must be recognized. Training programs must emphasize techniques that reduce these
risks. This includes careful manipulation of catheters, appropriate use of anticoagulation,
modification of energy delivered on the posterior wall of the LA, and the risk of
applying energy within the PVs or LAA. Fellows should be trained to suspect cardiac
tamponade or internal bleeding as a common cause of hypotension. Training should also
include management of these complications. The skills to perform an emergent echocardiogram
when cardiac tamponade is suspected are important. It is preferable for fellows to
undergo training in pericardiocentesis. If trainees do not gain proficiency in pericardiocentesis,
they must be able to recognize and diagnose cardiac tamponade and have immediate access
to a physician who can perform an emergency pericardiocentesis. They should understand
the risks of conscious sedation, which include hypoventilation, aspiration, and respiratory
arrest. They should also recognize the delayed time course associated with the development
of AEFs or PV stenosis, as well as the appropriate steps needed to diagnose and manage
these complications.
Appropriate Follow-up and Long-Term Management
Management of patients after hospital discharge can be complex and requires commitment
from the physician (cardiologist or internist) who will be following the patient on
an ongoing basis. Individuals undergoing training in AF ablation should participate
in a longitudinal clinic in which these patients are followed. Experience must be
gained in diagnosis and management of postprocedure complications, including esophageal
injury, PV stenosis, and late tamponade, pseudoaneurysm, or arteriovenous fistula.
Because the prevalence of some of these complications is very low, it is possible
that the trainee will not have first-hand experience with patients. Therefore, supplementation
of clinical experience with didactic presentations on diagnosis and management of
postablation complications is required. Prophylaxis against and management of postprocedure
atrial arrhythmias, including timing of repeat ablation and use of concomitant AADs,
must be taught to trainees. Finally, the training experience must address the risk-benefit
decision-making regarding the use of intermediate and long-term anticoagulation therapy.
Given the complexity of these issues, it would be ill-advised for cardiologists who
are not trained in electrophysiology to consider performing ablation procedures for
AF. Due to these issues and prerequisites for obtaining and maintaining competency,
this statement should also extend to the performance of cryoablation or other balloon
ablation.
Section 12: Surgical and Hybrid AF Ablation
Historical Considerations and Development of the Cox-Maze Procedure
There is a rich history of surgery for AF. Initial procedures were aimed at controlling
the ventricular response rate. Later procedures were directed at converting AF to
a normal sinus rhythm. Following experimental investigation, the Maze procedure was
introduced for the surgical treatment of AF in 1987 by James Cox. This procedure was
designed to interrupt macroreentrant circuits, thereby reducing the ability of the
atrium to fibrillate. Fortuitously, the surgery also isolated all of the PVs and the
posterior LA. In contrast to previous procedures, such as the corridor procedure and
LA transection procedures, the Cox-Maze procedure successfully restored both AV synchrony
and sinus rhythm and decreased the incidence of late stroke.
1287
This effect was attributed to both AF control and amputation of the LAA. The surgery
involved creating multiple strategically placed incisions across both the RA and LA.
The surgical incisions were placed so that the sinus node could “direct” the propagation
of the sinus impulse throughout both atria. It also allowed most of the atrial myocardium
to be activated, resulting in preservation of atrial transport function in most patients.
1288
The final iteration of this procedure, the Cox-Maze III, became the standard for the
surgical treatment of AF.
Long-term outcomes of 198 patients who underwent the Cox-Maze III procedure for treatment
of paroxysmal (n = 113) or persistent or long-standing persistent AF (n = 85) have
been reported.
1289
The mean follow-up was 5.4 ± 2.9 years. Among the 112 patients who underwent surgery
only for AF treatment, 96% were in sinus rhythm with or without AAD therapy and 80%
were in sinus rhythm and free of AAD therapy at the last follow-up. Among the 86 patients
who underwent AF surgery in conjunction with other cardiac surgery, 97% were in sinus
rhythm with or without AAD therapy and 73% were in sinus rhythm free of AAD therapy.
The incidence of major complications among the 112 patients who only underwent AF
surgery was 11%. Among these were two perioperative deaths and two perioperative strokes
or TIAs. Nine patients (8%) required pacemaker placement. The incidence of major complications
among the 86 patients who underwent AF surgery at the time of other cardiac surgical
procedures was 14%. Among these were one perioperative death and one perioperative
stroke. Twenty patients (23%) required pacemaker placement.
In considering the results of these early reports of cardiac surgery for treatment
of AF, it is now recognized that these patients did not undergo rigorous follow-up
by present standards. Rhythms were documented by means of a mailed questionnaire,
telephone interview, and/or an ECG for documentation. It is clear that the pioneering
work of Cox and his team paved the way for the current, less invasive Cox-Maze IV
surgery and other surgical approaches for AF ablation, as well as the field of endocardial
catheter ablation of AF.
The term lone AF holds different meanings in EP jargon compared with surgical jargon.
Electrophysiologists refer to lone AF when there is no other structural heart disease
present. Surgeons often refer to a lone AF procedure as one in which the only surgical
procedure performed is the ablation as opposed to a concomitant procedure. To eliminate
confusion, we recommend that surgeons avoid using lone AF to describe populations
of AF patients, and furthermore, we recommend the term stand-alone ablation when no
other concomitant procedure is performed at the same operative encounter. As noted
earlier in the document, the writing group recommends that the term lone AF not be
used in any context related to AF or AF ablation.
Surgical Ablation Technology
Despite its efficacy, the Cox-Maze procedure did not gain widespread application due
to its complexity, technical difficulty, and morbidity. The development and subsequent
availability of technology to perform atrial ablation allowed surgeons to replace
some of the traditional cut-and-sew lesions with ablation lines using this technology.
The simplified Cox-Maze procedure lessened procedural morbidity, thus leading to wider
adoption and extending its benefits to more patients. Although a variety of energy
sources for ablation were initially developed, only cryothermy and RF energy delivery
have emerged as practical and efficacious. The only surgical ablation system approved
and specifically labeled for surgical AF ablation is the Atricure Ablation System,
which includes a number of ablation tools, including a bipolar RF clamp.
1290
Cryothermy can be thought of as nondirectional (although shielding mechanisms can
be employed), whereas RF is a directional source. The RF technologies can be organized
into two major groups: unipolar and bipolar. Bipolar RF can be directional bipolar
or constrained bipolar. The directional bipolar devices have two side-by-side poles
that are applied to the tissue surface, with the energy passing through the tissue
between them. As the tissue between the poles desiccates and the impedance rises,
the energy passes deeper into healthy tissue, with the goal of tissue transmurality.
The constrained bipolar devices consist of a clamp with two jaws, which are applied
on opposite sides of the atrial tissue. The energy passes through the tissue between
the two jaws. When conductance falls, transmurality is inferred. The unipolar devices
do not provide the surgeon with a transmurality indicator. Since most of these ablation
systems were released clinically without dose-response studies, their use has led
to occasional collateral cardiac and extracardiac damage.
1162
,
1291
,
1292
Moreover, both unipolar and directional bipolar energy sources have had difficulty
creating transmural lesions when used from the epicardial surface on the beating heart.
1293
,
1294
,
1295
,
1296
,
1297
,
1298
This difficulty occurs because the circulating intracavitary blood pool produces convective
cooling, which makes transmural lesions difficult to achieve.
1299
In an attempt to obviate this problem, one device provides suction to pull two walls
of atrial tissue into apposition in a shallow trough, thus excluding the circulating
heat sink of intracavitary blood while the energy is applied. All of these energy
sources have a fixed depth of penetration, which makes their use in pathologically
thickened atria problematic.
Bipolar RF ablation has overcome some of these shortcomings. Because energy is delivered
between two closely approximated electrodes embedded in the jaw of a clamp device,
the energy is focused and results in discrete lesions. The energy is confined to between
the jaws of the clamp, reducing the possibility of collateral cardiac or extracardiac
damage. By measuring the tissue conductance between the two electrodes, algorithms
have been developed that help predict lesion transmurality in the experimental laboratory.
The weakness of these devices is that they can only ablate tissue that can be clamped
within the jaws of the device. This problem has limited the potential lesion sets,
particularly in the beating heart. Moreover, in the clinical situation, multiple ablations
have often been required to achieve entrance and exit block. These devices have been
incapable of fully ablating the RA and LA isthmus and have required adjunctive cryothermy,
or unipolar or directional bipolar RF ablation to perform a complete Cox-Maze III
lesion set.
Nevertheless, the development of these new ablation technologies has benefited the
surgical treatment of AF by making a technically difficult and time-consuming surgery
easier for all cardiac surgeons to perform. At present, more than 50% of the patients
undergoing open-heart surgery who have AF are offered concomitant AF surgery.
1300
Replicating the full Cox-Maze lesion set with linear lines of ablation has been shown
to be both feasible and clinically effective. A number of groups have reported excellent
results with ablation-assisted Cox-Maze procedures.
1301
,
1302
,
1303
,
1304
,
1305
,
1306
The largest of these experiences included 282 patients who underwent the Cox-Maze
IV procedure over a 7-year period with either paroxysmal (n = 118), persistent (n = 28),
or long-standing persistent AF (n = 135).
1301
A total of 124 patients (44%) underwent surgery only for AF treatment, and 158 patients
(56%) had other cardiac surgery performed, which included mitral valve surgery in
approximately 50% of patients. Among the entire patient cohort, 89% of the patients
were in sinus rhythm with or without AAD therapy, and 78% were in sinus rhythm and
free of AAD therapy at 12 months of follow-up. In contrast to early studies on surgical
AF ablation, more intensive monitoring was performed with Holter monitors every 3 months
in 70% of the patients. The incidence of major complications was 11%, including an
operative mortality of 2% and a 1.7% incidence of stroke. Pacemakers were implanted
in 9% postoperatively. A propensity analysis, matching patients who underwent an ablation-assisted
Cox-Maze with those having had a traditional cut-and-sew Cox-Maze III, showed no differences
in freedom from AF at 3, 6, and 12 months of follow-up.
1307
Further recent work has shown significantly improved results when the entire posterior
LA is excluded by the so-called box lesion.
1306
,
1308
A long-term study followed 576 patients from 2002 to 2014 with long-term monitoring.
1306
At 5 years, freedom from ATAs was 73% (102 of 139) and freedom from ATAs off AADs
was 61% (80 of 135). There was no difference in outcomes between patients with PAF
or the more persistent forms. There was also no difference between outcomes for those
patients who had stand-alone procedures and those who had concomitant procedures.
Because outcomes were significantly better at 12 months of follow-up (92% freedom
from ATAs overall and 88% freedom from ATAs off AADs), this paper highlights the importance
of long-term follow-up. Currently, the limitations of the energy delivery devices
and the attempt to deploy them through minimal access incisions or ports place constraints
on the location and number of ablation lesions that can be performed. The impact on
results of these alternative lesion patterns and the less invasive surgical approaches
requires further observational prospective analysis and randomized trials.
There has only been one completed trial of concomitant surgical AF ablation that has
resulted in specific FDA labeling for clinical treatment of AF.
1290
This was the Atricure Synergy Ablation System trial intended for the ablation of persistent
and long-standing persistent AF in patients who are undergoing open concomitant coronary
artery bypass grafting (CABG) and/or valve replacement or repair. The principal device
used in this trial was an Atricure Synergy Ablation clamp. This system had originally
been approved by the FDA for soft tissue ablation without specifically labeling for
AF ablation. This prospective nonrandomized clinical trial, using a Bayesian adaptive
design with prespecified early stopping rules, enrolled 55 patients between February
2008 and June 2009. Along with concomitant cardiac surgery, investigators performed
the Cox-Maze IV lesion set. The median patient age was 72 years, the median EF was
50%, and the median LA size was 6 cm. 56% of patients underwent valve surgery alone
or in conjunction with CABG. The incidence of major adverse events was 9%, including
death in 2 patients (3.6%), major bleeding in 2 patients (3.6%), and stroke in one
patient (1.8%). In addition to these major complications, 25% of the patients required
implantation of a permanent pacemaker for AV node dysfunction (8.3%) or sinus node
dysfunction (17%). The effectiveness of the procedure was assessed in 50 evaluable
patients, excluding four patients who died and one withdrawal. At 6 months of follow-up,
74% of the patients were AF-free and off AAD therapy, and 84% of the patients were
free of AF on or off AAD therapy. The freedom from AF at 12 months of follow-up was
also 75%. The results of this study were reviewed at an FDA panel meeting, leading
to approval for clinical use in 2011. This surgical ablation system is currently the
only system specifically labeled for treatment of AF.
We recommend that the term Maze procedure is appropriately used only to refer to the
biatrial lesion set of the Cox-Maze surgery. It requires ablation of the RA isthmus
and the LA isthmus. Less extensive lesion sets should not be referred to as a Maze
procedure, but rather as a surgical AF ablation procedure. In general, surgical ablation
procedures for AF can be grouped into three different groups: (1) a full biatrial
Cox-Maze procedure, (2) PVI alone, and (3) PVI combined with LA lesion sets.
Surgical Technology for Appendage Ligation or Removal and Outcomes of These Procedures
The LAA is a site of thrombus formation in patients with AF. Retrospective evaluation
has suggested that the LAA is responsible for up to 90% of the strokes in patients
with AF and nonrheumatic heart disease.
1309
Accordingly, it has been the target of elimination in the original Cox-Maze, as well
as in the majority of its modifications. Early evaluation of the cut-and-sew Cox-Maze
suggested a reduction of stroke late after surgery.
1287
Other small, retrospective series subsequently suggested a lower-than-expected incidence
of late neurological event (stroke or TIA) after a Maze, possibly independent of CHA2DS2-VASc
score.
1287
,
1310
,
1311
The reduction in stroke has been attributed to a combination of sinus restoration
and LAA elimination. The role of the LAA has been clouded by small numbers of patients
and the continuation of anticoagulation in a minority of postoperative patients, as
well as a retrospective series suggesting a persistent stroke risk in postoperative
patients who are in sinus rhythm, with large atria, and poor atrial contraction leading
to effective LA asystole.
1312
The strongest evidence that LAA elimination decreases stroke comes from the WATCHMAN
Left Atrial Appendage System for Embolic Protection in Patients With Atrial Fibrillation
(PROTECT AF) and WATCHMAN LAA Closure Device in Patients With Atrial Fibrillation
Versus Long Term Warfarin Therapy (PREVAIL) trials that randomized patients to either
anticoagulation or implantation of a WATCHMAN device in the LAA. The 4-year results
of the PROTECT AF trial suggested that elimination of the LAA was superior to anticoagulation
for the composite endpoint of cardiovascular death, all stroke, and systemic embolization.
1313
,
1314
An important concern for surgical excision has been the complication of bleeding.
This complication is especially important in older patients and those with enlarged
atria in whom the tissue may be more friable. This has led to several different techniques
for LAA elimination at the time of surgery. The most common have been internal ligation
(e.g., sewing the LAA orifice closed from the inside) and stapled excision. There
is a paucity of data that examines effectiveness of any surgical technique. However,
with stapled excision, reported rates of tears requiring repair have been approximately
10%.
1315
,
1316
Another issue is the potential for arrhythmia generation from the LAA. One study demonstrated
LAA firing in 29% of patients and the only site of recurrence in 8.7% of patients
who had undergone catheter ablation of paroxysmal or persistent AF; additional LAA
isolation could increase the freedom from AF.
532
,
533
Thus, the isolation or surgical excision of the LAA could influence procedure efficacy
and reduce the risk of thromboembolic events.
However, a randomized study including 176 patients with persistent AF who were undergoing
surgical ablation via thoracoscopic approach reported that additional LAA amputation
did not reduce the rate of any atrial arrhythmias compared with the standard surgical
ablation set. The follow-up period of this study was 18 months and the results cannot
be extrapolated to the long-term maintenance of sinus rhythm or thromboembolic events
prevention.
1317
An emerging concern is the effectiveness of these alternative techniques. Most evidence
is anecdotal and revolves around case reports because the LAA is not routinely evaluated
late after surgery unless there is a clinical indication. In a series of 137 such
patients, the LAA was incompletely ligated (either leaving a stump greater than 1 cm
or a gap with flow) in 27% of patients after surgical excision. In internally ligated
patients, the failure rate was 77%. There were no successes when the LAA was stapled
without amputation of the distal remnant.
1318
One limitation of this small series is that it only looked at the 5% of patients who
received intervention who had an indication for late TEE, which included only 12 in
the stapled group. A more recent small, randomized trial of internal ligation, surgical
excision, and stapled excision reported that, at TEE evaluation in follow-up of 5 months,
all three of these techniques left either a stump or a gap at least 50 percent of
the time.
1319
Epicardial LAA ligation with a LARIAT device has been developed through the combined
transseptal and subxiphoid approach.
1320
The results from the multicenter registry demonstrated a high acute closure rate,
but procedural success was limited by bleeding.
1321
More recent results showed that LARIAT device implantation was associated with a lower
rate of leaks at 1 year of follow-up and a 1.1% rate of TIA or stroke.
1322
Newer techniques include an external clip (Atriclip) that was approved by the FDA
in 2011 for the occlusion of the LAA under direct visualization in patients undergoing
other open cardiac surgical procedures, as indicated in the approved Indication statement
of the AtriClip device. This study reported 98% success in 60 of 71 patients available
for follow-up.
1323
A longer-term study followed 36 patients with annual CT scans.
1324
At 3.5 years of follow-up, all the clips were stable with no thrombi, no LAA perfused,
no neck >1 cm, and no neurological events. The use of an endoloop has been described,
as well as a silicone fastener, which is not currently available (Tiger paw). The
true efficacy of any single technique is unknown and will require more investigation
before any recommendations can be made.
There are data that suggest that despite the limitations of all these techniques,
a reduction in strokes might occur. One series of 773 patients undergoing surgery
for AF compared surgical excision with alternative techniques. The annual rates of
late neurological events was approximately 1% using alternative techniques, and only
one event was fatal.
1325
This suggested at least a reduction of clot burden even in incompletely successful
techniques. Our understanding of surgical elimination continues to rapidly evolve,
and current studies are inadequate to make a distinction between LAA excision or exclusion
techniques. It is reasonable and probably helpful to eliminate the LAA with any technique
at the time of AF surgery, but late evaluation should be performed prior to cessation
of anticoagulation. We have elected not to make recommendations regarding appendage
occlusion, resection, or ligation in this document, because this is beyond the scope
of this document and available data.
Concomitant Surgical Ablation
Historical Considerations
Surgical ablation is most commonly applied as a concomitant procedure during valve
or CABG surgeries. Prior consensus recommendations referred to cardiac surgery as
a whole, grouping data from multiple studies to derive IIa LOE C recommendations.
2
However, that document went on to say, “It is advisable that all patients with documented
AF referred for other cardiac surgeries undergo a left or biatrial procedure for AF
at an experienced center, unless it… will add significant risk….”
2
More recent AHA/ACC/HRS Guidelines continued this procedural grouping but included
more recent randomized comparisons to determine that surgical ablation at the time
of another surgery is a IIa LOE B recommendation. The frequencies of surgical ablation
performance and durable rhythm success have steadily increased. Furthermore, as noted
above, the FDA has now approved an ablation system for treatment of persistent AF
in patients undergoing concomitant cardiac surgical procedures.
1290
Recently, more information has become available on AF mechanisms and the potential
influence of specific structural heart abnormalities on outcome. Therefore, this surgical
section provides updated recommendations for three operation categories for which
more data are now available: primary open atrial operations, primary closed atrial
operations, and stand-alone operations for AF.
Concomitant Surgical Ablation
Open concomitant cardiac surgical operations, in which a left atriotomy is being performed
for the primary procedure, commonly include patients receiving mitral valve repair
or replacement (MVRR), with or without concomitant tricuspid valve repair or replacement,
or closure of an ASD. Closed concomitant surgical ablation operations, in which a
left atriotomy is not otherwise performed, commonly include patients undergoing prosthetic
AVR, CABG, or AVR+CABG.
The prevalence of preoperative AF and frequency of concomitant cardiac surgical operations
varies between these procedure classes. AF is found in one-third of patients presenting
for mitral valve surgery, but in only 6% of patients undergoing isolated CABG, and
in 14% of patients at the time of AVR. Mitral valve repair for primary regurgitation
has largely supplanted mitral valve replacement and does not require lifelong anticoagulation.
Thus, successful surgical ablation concomitant to mitral repair can mitigate the need
for long-term anticoagulation or medicinal therapy for AF. The performance rate of
concomitant cardiac surgery in patients with AF at the time of mitral operations has
risen from 52% to 62%. In an analysis of operations performed in the early 2000s,
the likelihood of surgical ablation performed for AF at the time of AVR was 31%, and
only 26% at the time of CABG. Although differential application of surgical AF ablation
exists among operative procedures, more recent information suggests an acceleration
of surgical AF ablation, especially in the mitral subgroup.
Surgical Ablation at the Time of Concomitant Open Atrial Operations
At the time of a primary atriotomy, AF surgery can be performed during concomitant
MVRR with or without tricuspid surgery, with or without closure of ASD, and with or
without other concomitant procedures such as CABG.
1326
The results of the only prospective study performed to achieve FDA labeling for AF
ablation reported a 9% major complication rate, a 25% rate of pacemaker implantation,
and a 75% freedom from AF at 12 months of follow-up among 54 consecutive patients
with persistent AF undergoing other types of cardiac surgery who were enrolled in
this clinical trial.
1290
Several other RCTs and meta-analyses are available to evaluate AF surgery at the time
of concomitant mitral procedures.
1327
,
1328
,
1329
,
1330
,
1331
,
1332
,
1333
,
1334
Large LA, AF duration, advanced age, and failure to isolate the entire posterior LA
are common predictors of reduced long-term efficacy. High baseline comorbid risk is
a common reason cited for not performing surgical ablation, though many institutional
studies note that this is not a contraindication to surgical ablation. The safety
of concomitant surgical ablation has been established in the literature and in updated
valve risk models from the STS database.
A multivariable regression and propensity matched cohort, composed of 52% mitral procedures
from the STS database, demonstrated no impact on 30-day mortality with surgical AF
ablation.
1300
However, patients undergoing surgical AF ablation had a 26% higher chance of requiring
a permanent pacemaker (OR 1.26). In a recent randomized trial of mitral valve operations,
there was no increase in major complications associated with the addition of surgical
ablation other than a doubling of pacemaker risk.
1331
,
1333
Conversely, recent large meta-analyses confirmed the safety of concomitant surgical
ablation, but did not find a significant increase in pacemaker use. The incidence
and outcome relevance of pacemaker implantation remains a point of controversy. In
analyses of more recent STS data, risk-adjusted mortality was either not impacted
or actually decreased with surgical AF ablation in the mitral and multiple valve populations.
1335
A longitudinal study (up to 120 months) demonstrated that restoration of sinus rhythm
by a Cox-Maze procedure combined with heart surgery markedly increased long-term survival.
1336
Despite previously published variability of efficacy of surgical ablation in heterogeneous
populations, the longitudinal benefits of concomitant surgical AF ablation at the
time of MVRR are now becoming clearer. Several recent RCTs and meta-analyses indicate
that concomitant surgical ablation at the time of MVRR reduces the longitudinal incidence
of postoperative AF greater than 50% for at least 1 year, with results ranging from
60%–90%.
1327
,
1328
,
1329
,
1330
,
1331
,
1333
,
1334
,
1337
,
1338
In addition to LA size and preoperative AF duration, there is a procedural learning
curve that can impact efficacy, and thus surgeons should seek appropriate training
prior to performing surgical ablation.
Therefore, based on the literature and the experience of the writing group members,
surgical ablation for AF is recommended at the time of concomitant open atrial procedures,
such as mitral valve surgery in patients with symptomatic AF (Class I, LOE B-NR) (Table
2
, Figure 8
).
Surgical Ablation at the Time of Concomitant Closed Atrial Operation
Concomitant surgical ablation of AF at the time of primary nonatriotomy operations
includes patients undergoing isolated AVR, isolated CABG, or AVR+CABG. The presence
of AF at the time of these operations, especially if left untreated, is associated
with increased risk of early and late mortality and morbidity. When no intracardiac
pathology exists in the setting of AF, further surgical decision-making is required.
Although full open Cox-Maze IV has been shown to be safe and effective in these cases,
surgeons are reluctant to add a left atriotomy to address AF. If less aggressive approaches,
such as epicardial PVI or the Dallas lesion set are to be applied, care should be
taken to note the mechanism and type of AF being treated.
1339
,
1340
,
1341
Recent randomized and matched cohort studies of surgical ablation and concomitant
AVR, AVR+CABG, and isolated CABG all consistently show no differences in 30-day or
in-hospital morbidity or mortality.
1342
,
1343
,
1344
We have known that at the time of isolated CABG operations, the open atrial Cox-Maze
procedure is effective upwards of 90% at 5 years of follow-up.
1345
The application of bipolar RF clamps to perform PVI has shown variable 50%-89% 1-year
success superior to AAD alone in patients with paroxysmal and persistent AF.
1346
,
1347
,
1348
,
1349
,
1350
A recent meta-analysis of 16 RCTs of surgical ablation and concomitant operations
evaluated predominantly mitral operations, but included both AVR and CABG operations.
1333
There were no significant differences in mortality, stroke, or pacemaker requirement
between surgical ablation compared with no ablation; however, the surgical ablation
groups demonstrated superior 1-year freedom from AF in AVR and AVR+CABG.
Therefore, based on the literature and the experience of the writing group members,
surgical ablation for AF is recommended at the time of concomitant closed atrial procedures
such as isolated AVR, isolated CABG, and AVR+CABG in patients with symptomatic AF
refractory or intolerant to at least one Class I or III antiarrhythmic medication
(Class I, LOE B-NR) (Table 2
, Figure 8
). For symptomatic patients with AF who have not previously been treated with antiarrhythmic
therapy, concomitant closed AF surgery is recommended with a Class IIa indication,
LOE B-NR (Table 2
, Figure 8
).
At the time of a planned cardiac operation for symptomatic structural pathology, it
should be noted that interpreting symptoms of concomitant AF as distinct might or
might not be feasible because these could be masked by symptoms prompting the primary
cardiac operation (i.e., valvular or coronary disease). Therefore, in the setting
of existing symptomatic surgical pathology, the presence or absence of AF symptoms
should not be the only factor involved in surgical decision making on the concomitant
performance of surgical ablation. It should be noted that the surgeon members of the
writing committee, as well as other surgeon reviewers, felt that the evidence might
warrant a Class I indication for this patient subgroup; however, among the larger
group, consensus was attained for a level IIA recommendation.
Stand-Alone Surgical Ablation of AF
Stand-Alone Operations for AF and Their Outcomes
The primary indication for stand-alone surgery that was described in the 2012 Consensus
Document was the presence of symptomatic AF, refractory or intolerant to at least
one Class I or Class III AAD.
2
In current practice, most patients also have experienced at least one unsuccessful
catheter ablation before referral, unless the patient has a strong preference for
a cure with a single procedure.
There has been over two decades of experience with operations performed solely for
treatment of AF (stand-alone operations). The wide use of these procedures has been
limited by a reluctance to refer patients to surgery for AF, procedural complexity,
and limited data regarding outcomes. Moreover, the types of procedures and the technologies
used to perform them have multiplied and are variable between operators. This has
led to relatively modest-sized single-site case series, or at best multicenter series
without comparison groups. In addition, the rigor and methodology of follow-up have
changed dramatically over time and have further limited comparisons of outcomes. Lastly,
the development of hybrid procedures, especially when staged, make comparisons even
more difficult. This section will focus only on single-stage surgeries as sole AF
therapies. A discussion of hybrid procedures will follow. Perhaps the best way to
distinguish the types of surgeries is by those that require cardiopulmonary bypass
and cardiac arrest and those that do not. In order to effectively create a lesion
down to the mitral annulus, an open heart is required.
The earliest—and one of the largest—reported study of stand-alone operations for AF
has been the 112 patients who underwent the cut-and-sew Cox-Maze III procedure by
James Cox.
1351
This procedure is performed through a sternotomy on cardiopulmonary bypass on an arrested
heart and physically cuts and re-sews the atria to create a collection of lines of
block. Cryothermia is used to destroy the tissue down to the mitral annulus. Among
the 112 patients, 96% were in sinus rhythm with or without AAD therapy, and 80% were
in sinus rhythm and free of AAD therapy at last follow-up. There was one late stroke
in this group, and 88% of the patients were off chronic anticoagulation at last follow-up.
The only risk factor for late recurrence was the preoperative duration of AF.
1351
There have been several other published series with similar results that combine both
stand-alone and concomitant patients with smaller numbers of patients. This procedure
requires a sophisticated level of training and skill. As such, it is performed rarely,
and only by experienced surgeons. Ideal patients for stand-alone AF ablation have
failed other therapies, want definitive cures, or have clots in the LAA, making other
approaches not using cardiopulmonary bypass risk prohibitive.
With the introduction of new ablation technology, including bipolar RF energy and
new cryoablation systems, there has been renewed interest in less invasive procedures
for stand-alone AF ablation. These new tools can be used in the open chest or through
small incisions between the ribs. When used in the open chest with a full biatrial
Cox-Maze lesion set performed, the procedure has been termed the Cox-Maze IV procedure.
Techniques for a Cox-Maze IV procedure through a small, right inframammary incision
have also been perfected. As noted in the earlier section on new surgical ablation
technology, the outcomes achieved with the Cox-Maze IV procedure are similar to those
achieved with the earlier Cox-Maze procedure. Importantly, the cross-clamp times are
shorter with the Cox-Maze IV procedure.
1301
The advantage of these approaches includes the ability to reliably create the endocardial
lesions of the Maze, down to the mitral annulus. Late evaluation of this procedure
in 146 stand-alone patients has shown a 72% freedom from AF at 5 years of follow-up
and a 59% freedom from AF off antiarrhythmic medications.
1306
Cryothermia alone has been used and described in a series of 77 patients, with a 6-month
result of 88% freedom from AF, antiarrhythmic medications, and anticoagulants, but
late follow-up is lacking.
1306
,
1352
Other approaches have limited the lesions to only those that can be created from the
epicardium without the need to open the heart, and use both cardiopulmonary bypass
and cardiac arrest. This approach has limited the extent of lesions from the Maze
that can be created, because the mitral line is buried by an epicardial fat pad that
makes destruction of tissue in this area unreliable. The minimally invasive surgical
approach using video-assisted PV ablation and exclusion of the LAA was first described
in 2005.
1353
A bipolar RF clamp was used for PVI on the beating heart in 27 patients, among whom
18 had PAF. Among the 23 patients followed for more than 3 months, 21 (91%) were free
of AF and 65% were off all AADs. There were four major complications, but no deaths,
and no pacemakers were implanted. An additional ablation strategy that has been reported
is minimally invasive PVI and partial autonomic denervation.
1354
In a study of 74 patients undergoing this approach, 84% of the patients with PAF were
free of AF and 57% of patients with persistent or long-standing persistent AF were
free of AF at 6 months. There was one death, one hemothorax, one case of transient
renal insufficiency, and one patient with a transient brachial plexopathy. A second,
larger report from this group in 114 patients reported that 72%, 46.9%, and 32% of
patients with paroxysmal, persistent, and long-standing persistent AF, respectively,
were free of AF and off antiarrhythmic medications at 195 days of follow-up.
1355
Another multi-center series of 100 patients with a similar approach and mean follow-up
of 13.6 months reported a sinus restoration rate of 87%, with 64% of patients free
from AADs.
1356
The results of these and other trials cited earlier in this section have made it clear
that a more extensive lesion set than PVI alone is required for successful surgical
treatment of persistent and long-standing persistent AF. Most surgeons who still perform
this type of procedure have moved toward a hybrid approach in either a single or staged
operation. However, a PVI alone remains a reasonable approach for patients with PAF.
The Dallas Lesion Set was developed to create a complete approach, which can be performed
on a beating heart without cardiopulmonary bypass.
1339
,
1340
,
1341
The set replicates the LA lesions of the Cox-Maze III, but changes the connection
of the PVI to the aortic annulus in continuity with the mitral. Early results have
been published on 30 patients.
1339
,
1340
The group included 10 patients with persistent AF and 20 patients with long-standing
persistent AF. Electrocardiographic long-term monitoring and the use of AAD data were
collected 6 months postprocedure, and follow-up was 100%. Procedure-related complications
did not occur during follow-up, nor were there any deaths. At 6 months of follow-up,
90% of the patients with persistent AF and 75% of the patients with long-standing
persistent AF were in sinus rhythm. AAD therapy was continued in 22% of the patients
with persistent AF and 53% of the patients with long-standing persistent AF. In a
series of 100 paroxysmal patients randomized to include the Dallas Lesion Set or not,
the additional lesion, as expected in a paroxysmal population, did not impact success
at 16 months of follow-up.
520
Much like the results of catheter ablation, this suggests that the type of AF will
influence the success of the procedure. Persistent AF is likely to require a more
extensive lesion set. An important area of interest is the decision to offer a patient
surgery or catheter ablation.
The AF Catheter Ablation Versus Surgical Ablation Treatment (FAST) trial sought to
compare catheter ablation with minimally invasive surgery.
601
A total of 124 patients who had drug-refractory AF with dilated atria or failed catheter
ablation were randomized to either catheter ablation or minimally invasive surgery
using bipolar clamps, with or without additional connecting lesions. At 1 year of
follow-up, freedom from AF was 37% in the catheter ablation group and 66% in the surgical
group. Although this was somewhat offset by the increased adverse events in the surgical
group (34% vs 16%), the only death was in the catheter ablation group.
601
A different analysis of 7 studies, including two RCTs, suggested superior freedom
from AF in the surgical group, with similar complication rates, except for an increase
in pacemaker implantation in surgical patients.
1357
However, the technologies and groups were fairly heterogeneous.
Other approaches, such as epicardial box lesions with suction-assisted unidirectional
uni- and bipolar RF and a complete box lesion with bipolar clamps, have been described
in numbers insufficient to draw any conclusion. As the new techniques have been introduced,
there has been appropriate concern regarding the safety of minimally invasive stand-alone
surgery. Although safety is dependent on procedure and site, it has been examined
in a systematic review that compiled results from 23 observational studies with 752
patients who underwent minimally invasive stand-alone procedures.
1349
Operative mortality was 0.4%. Complication rates attributed to surgery were only 3.2%.
Reports from the STS National Database showed an operative mortality rate of 0.74%.
The complication rate was considerably higher at 16.43%, although major morbidities
such as stroke (0.72%), renal failure (2.45%), and bleeding (0.99%) were low. Pacemakers
were implanted in 1.03% of patients.
The outcomes of stand-alone AF ablation from the STS database were recently reported.
1358
Between 2005 and 2010, a total of
91
,
801
surgical AF ablations were performed, of which 4893 (5.3%) were stand-alone. During
this period of time, the number of stand-alone AF surgeries increased from 552 cases
in 2005 to 1041 cases in 2010. The mean age of the stand-alone group was 60 years,
and 71% were men. Some 80% of the stand-alone procedures were off pump. The overall
operative mortality was 0.74% (1.7% on pump vs 0.5% off pump), the rate of pacemaker
implantation was 1%, and the overall complication rate was 16% (28% on pump vs 13%
off pump).
1358
The Atrial Fibrillation Ablation and Autonomic Modulation via Thoracoscopic Surgery
(AFACT) study compared the outcomes of thoracoscopic surgical AF ablation in 240 patients
with advanced AF at a single European center.
123
A total of 59% of the patients had persistent AF and 68% had an enlarged LA. One-fourth
of these patients had previously failed catheter AF ablation. Patients were randomized
to undergo surgical AF ablation alone or combined with epicardial ablation of the
four major GP. At 12 months follow-up, no recurrences of AF were observed in 71% and
68% in the GP and control groups, respectively; the incidence of major complications
was greater in the group that underwent GP ablation (19% vs 8%, respectively). Major
bleeding occurred in nine patients in the GP group, one of whom required sternotomy.
Sinus node dysfunction occurred in 12 patients in the GP group and in 4 controls.
The authors concluded that GP ablation during thoracoscopic surgery for advanced AF
is associated with higher risk and no appreciable improvement in AF control. This
center also recently examined the 5-year outcomes of thoracoscopic surgery for AF
in 66 patients. A total of 50% of patients experienced no AF recurrences and discontinued
AAD therapy at the 5-year follow-up, and 88% of the patients were in sinus rhythm.
In this cohort, persistent AF and previous failure of catheter ablation were independently
associated with AF recurrence.
1359
Superior efficacy of a single approach has also been difficult to establish. A systematic
review of 48 studies including 3832 patients suggested that the efficacy of bipolar
RF was equivalent to the cut-and-sew Maze III technique for stand-alone surgical ablation,
as long as both were applied meticulously.
1360
Another meta-analysis of 16 published randomized trials indicated that the cut-and-sew
Maze III produced slightly better recovery of SR and stroke prevention, but with increased
perioperative risk.
1361
Definitive recommendations for a surgical approach with or without cardiopulmonary
bypass await more data.
Using a surgical approach with or without cardiopulmonary bypass that creates all,
some, or a modification of the maze is reasonable, especially in patients in whom
catheter ablation has failed or who are at high risk for an unsuccessful catheter-based
result. However, a stand-alone operation should have the ability to create the complete
full Maze lesion set, whether it is in a single operation or staged. This approach
is especially important for those patients who have persistent AF.
Therefore, based on the literature and the experience of the writing group members,
stand-alone surgical ablation of paroxysmal AAD-refractory AF can be considered for
patients who have failed one or more attempts at catheter ablation, and after review
of the relative safely and efficacy of catheter ablation vs a stand-alone surgical
approach for those who are intolerant or refractory to AAD therapy and prefer a surgical
approach (Class IIb, LOE B-NR). For patients with persistent and long-standing persistent
AF, stand-alone surgical ablation is reasonable for patients who have failed one or
more attempts at catheter ablation, and after review of the relative safely and efficacy
of catheter ablation vs a stand-alone surgical approach for those who are intolerant
or refractory to AAD therapy and prefer a surgical approach (Class IIa, LOE B-NR,
Figure 8
). Stand-alone surgical AF ablation is not recommended for patients who have not failed
a trial of at least one antiarrhythmic medication.
Catheter Ablation After AF Surgery
The idea of a “touch-up” ablation for AF recurrence is not new to catheter ablation.
It is, however, relatively new to the treatment algorithms of failure after cardiac
surgery for AF, which has historically been considered the end of the road for sinus
restoration. Now, catheter ablation can be a critical adjuvant for patients who undergo
surgical AF ablation yet still suffer from residual AF. The potpourri of surgical
AF treatment—ranging from PVI through complete LA to complete biatrial lesions and
combinations in between—makes standardized conclusions difficult in this area. This
endpoint is further obscured by the myriad of technologies used to create the lines
of block, as well as the underlying type of fibrillation treated and the limited number
of patients in published series. However, there are several publications that offer
some guidance, which will be reviewed below. What has become clear over time is that,
as with redo-catheter AF ablation procedures, finding a reconnection of the PVs is
also to be expected in a patient undergoing a catheter-based AF ablation procedure
following a surgical AF ablation procedure.
Because the cut-and-sew Maze was the earliest described procedure, initial reports
focused on patients who underwent that specific procedure. One of the earliest studies
reported on 23 patients who presented a mean 14 months after a cut-and-sew Maze. In
this report, 8 patients had only undergone a Maze, and 15 had undergone a concomitant
procedure.
1361
The most common site of failure was around the PVs, which occurred in eight (35%)
patients. Five patients had focal tachycardia (3 in the CS and 1 each in the posterior
lateral RA and LA septum). Four patients had RA incisional flutter and six had left
AFL, which mapped around the mitral valve annulus in four patients and around the
PVs in two. One year after ablation, 19 of the 23 patients were both arrhythmia-free
and off AADs.
The vulnerability of PVI was supported by another study that followed 20 patients
with arrhythmias after surgical ablation.
1362
This group, however, was much more heterogeneous: alternative energy sources were
used to create the initial lines of block, including microwave, RF, cryothermy, and
laser; most patients had only LA lesion sets at the time of initial surgery, and nearly
half the patients had more than one mechanism of tachycardia. This report also highlighted
the involvement of the mitral isthmus, including the CS and the LAA. The vulnerability
of the mitral isthmus, especially at the CS, was also highlighted in a series of 22
patients failing after the Cox-Maze III.
1363
Of note, this outcome represented a 15% failure rate among a total of 143 patients
in whom lesions were created using a combination of cut-and-sew and cryothermy. Frequently,
out of concern for injury to the circumflex, cryothermy is used at the mitral annulus
and is often used to connect the PVs in a small area so that reapproximation of the
tissue is easier.
In a series of patients with five different surgical types, various rates of failure
were identified.
1364
High-intensity focused ultrasound was associated with a 37.5% need for touch-up catheter
ablation, which was much more frequent than the other groups. This group had failures
primarily around the PVs, suggesting an incomplete lesion creation at initial operation.
The other groups—consisting of cut-and-sew Maze, biatrial Maze using primarily RF,
LA maze alone, and PVI alone—had no significant difference in success, ranging from
90% for the cut-and-sew to 69% for PVI alone. When the RA was not addressed at the
time of initial operation, it was the site of failure in 75% of those who had recurrent
AF. In the other groups, the mitral isthmus was again identified as an area for failure.
Successful ablation was achieved in approximately 70% of patients.
These findings have relevance as new paradigms for treatment evolve. Using hybrid
strategies with technology that replaces cut-and-sew and new lesion sets might require
a more individualized approach to each patient. New technology can introduce an area
of vulnerability around the PVs. In one series of 154 patients undergoing minimally
invasive PVI, eight failures were studied. Half had gaps in the lesions created with
new enabling technology.
1365
The remainder had flutters around the mitral isthmus. In a series that compared a
cut-and-sew Maze to a hybrid approach, only 8% of the patients needed ablation after
a cut-and-sew Maze.
1366
However, after PVI using bipolar RF, 7 of 25 (29%) patients needed a second-stage
catheter ablation. All seven had at least one failure around the PVs, for a total
of 15 veins. Reconnection was most common in the RI region. Interestingly, there were
no RA failures in this group.
These reports suggest that there are many factors for surgical failures after AF treatment.
It is likely that catheter ablation can help selected patients restore sinus rhythm
after failures. These treatments should be performed at experienced centers by experienced
individuals who will tailor the procedure to the individual patient based on initial
lesion set, the ablation technology and strategy used during initial AF surgery, and
the results of extensive mapping and provocative testing at the time of the redo ablation
procedure. As the experience with new hybrid approaches evolve, more definitive conclusions
should arise.
Hybrid Epicardial and Endocardial AF Ablation Procedures
Background
Forward-thinking practitioners view catheter AF ablation and minimal access surgical
ablation as complementary rather than competitive techniques, having found that patients
who fail a surgical ablation usually fail as paroxysmal with a relatively low burden
of AF. Whereas they might not have been candidates for catheter AF ablation preoperatively,
they are now ideal candidates for a “touch-up” catheter AF ablation. The electrophysiologist
will frequently find a single small break in a line, which is easily completed with
a catheter; thus, the procedure is converted to a success. This realization of the
complementary nature of these disciplines has led some to believe that perhaps combining
these approaches could lead to better outcomes than either approach alone.
There are other reasons why surgical (epicardial) and catheter (endocardial) ablation
can be viewed as complementary. Surgical devices can fail to penetrate the endocardium;
catheter devices can fail to penetrate to the epicardium. Surgeons are skilled at
making lines; the tools are designed for it, the smooth epicardial surface is ideal
for it, and visual imaging can reveal breaks in a line. Electrophysiologists excel
at “spot welding.” The catheter tip is punctuated by design, so it can slip off of
endocardial ridges or trabeculations, resulting in breaks, and nonvisual imaging does
not show continuity of burns. Surgeons might have difficulty mapping for completeness;
they are constrained by pericardial reflections, they might lack formal training,
and their tools are first- or second-generation. Electrophysiologists excel at mapping
for success; they have full access to the entire endocardial surface, they are formally
trained in the techniques, and they have mature enabling technology. In addition,
each specialty has its own unique contributions. Surgeons can fully divide the ligament
of Marshall, eliminate the atrial appendage, perform targeted ablation of GP, and
isolate the SVC with little risk of injury to the PN. Electrophysiologists can easily
make a cavotricuspid isthmus line, map for flutters, ablate within the CS, and map
and ablate focal triggers.
1367
,
1368
Recognition of the complementary nature of these techniques has led some centers to
explore “hybrid” procedures (combined surgical and catheter ablation), with early
promising results.
606
The advent of minimal access surgical ablation laid the groundwork for hybrid ablation.
Seeking to advance the success of the Cox-Maze III yet lessen the morbidity, surgeons
began exploring minimal-access approaches. Three things led to the expansion of minimal-access
techniques: First was the focus on the PVs as the seminal goal of ablation; second,
advances in enabling technology allowed lesion creation using RF energy and cryothermy;
and third was the published data revealing modest success for catheter ablation of
the persistent forms of AF.
2
,
931
Thus, with the focus on the PV triggers, surgeons began performing an increasing number
of minimal-access PVI procedures.
197
,
1369
,
1370
,
1371
However, investigators showed that this treatment was inadequate for patients with
persistent and long-standing persistent AF.
1355
This led to the belief that the persistent forms of AF needed both substrate modification
and trigger isolation, and this provided the impetus to develop the Dallas lesion
set, which replicated all the LA lesions of the Cox-Maze III, yet allowed them to
be placed on the surface of the full-beating LA. Although it was a major step forward,
with a success rate of 79%, this approach failed to reach the success rates of the
Cox-Maze III.
1339
,
1340
To enhance the robustness of lesion formation, the complementary processes of performing
a catheter-based endocardial ablation in combination with surgical epicardial ablation
were contemplated, and this led to hybrid approaches.
1372
,
1373
,
1374
Though these hybrid techniques are under active investigation, the published literature
is limited to a few early feasibility studies. Early investigators used a unilateral
right thoracoscopic approach to isolate the PVs with a single encircling box lesion.
The energy source for the surgical ablation was monopolar RF (Cobra Adhere, Estech,
San Ramon, CA). Nineteen consecutive patients underwent a right unilateral minimally
invasive hybrid procedure. Ten patients (52.6%) had long-standing persistent AF, whereas
four (21.1%) had persistent and five (26.3%) PAF.
1375
In 17 patients, one or more PVs (mostly the LSPV) were not isolated, and an endocardial
touch-up was needed. It was possible to complete all the procedures as planned, without
any conversion to cardiopulmonary bypass. No patient died during the follow-up. At
1 year, 7 of 19 (36.8%) patients were in sinus rhythm with no episode of AF and off
AADs. Among the patients with long-standing persistent AF, 20% (2 of 10) were in sinus
rhythm and off AAD, 50% (2 of 4) in persistent and 60% (3 of 5) in PAF. Disappointing
1-year results were attributed to an inadequate energy source. Thus, the surgical
portion of the procedure was converted to use a bipolar RF clamp (AtriCure Inc., West
Chester, OH), which had been shown to be more effective.
1376
This approach provided improved results, and in most cases, gaps in surgical lesions
could be completed by endocardial catheter ablation during the same procedure.
608
A sequential hybrid approach was subsequently developed.
606
There are advantages and disadvantages to simultaneous and staged hybrid procedures.
An important concern of single-stage hybrid is that edema and stunning induced by
surgical ablation might produce block on testing, but these areas might recover later,
when edema has subsided. This presence of an incomplete block at delayed catheter
mapping was reported by an investigator who performed bilateral PVI box lesion and
an additional roofline and LAA exclusion with clips in 30 patients with persistent
AF. At staged catheter hybrid 3 months later, they found gaps in 77%–87% of the PVI
lesions, nearly 70% of the rooflines, and 40% of the floor lines, requiring endocardial
touch-up ablation. Nevertheless, they were able to obtain a 1-year freedom from AF
and AAD by 7-day Holter of 90% (27 of 30). Other surgeons compared 25 staged hybrid
procedures using bipolar RF with 38 classic cut-and-sew Maze III procedures.
1366
At 1 year of follow-up, freedom from AF and antiarrhythmic medication was 52% for
the staged hybrid and 87.5% for the Maze III (P = .004). Other approaches included
a unilateral thoracoscopic approach using the monopolar RF suction Estech Cobra Adhere
XL device (AtriCure Inc., West Chester, OH) without atrial appendage occlusion, applied
to 19 patients.
1375
At immediate hybrid catheter ablation, every lesion required touch-up and 1-year freedom
from AF and AAD was 36%.
An innovative approach has been the passage of a scope from the subxiphoid, transperitoneal
and transdiaphragmatic region to approach the posterior LA (the convergent procedure).
The surgeon uses the nContact monopolar RF coagulation system to produce a comprehensive
biatrial lesion pattern on the outside of a beating heart while eliminating chest
incisions. Then, the electrophysiologist uses an ablation catheter endocardially to
finish the lesion pattern and ensure that all reentrant circuits are interrupted.
Reported success rates have varied, from 16.7% to 100%; however, there has been an
elevated adverse event rate in most published series, with an associated mortality
of up to 12.5%, mostly related to AEF and sudden death.
607
,
609
,
613
,
1368
,
1377
,
1378
,
1379
,
1380
,
1381
,
1382
,
1383
This procedure has been largely redesigned to prevent these adverse results, and two
papers have reported no mortality and no AEF.
613
,
1381
A recent meta-analysis compared the Cox-Maze to hybrid procedures. The overall freedom
from AF and freedom from AF off AAD at 1-year of follow-up was 87% vs 71%, respectively,
but the complication rates were higher with hybrid procedures.
1384
Based on current literature, the hybrid approach with the most effective outcomes
and safety profile appears to be the bilateral PVI procedures with LAA management.
Available published data on the monopolar convergent procedure do not indicate an
adequate safety and efficacy profile.
Currently, there is investigation into both simultaneous and staged hybrid procedures,
with no clinical trials showing one strategy superior to the other. The Dual Epicardial
Endocardial Persistent Atrial Fibrillation trial is a prospective randomized staged
hybrid study using bipolar RF. The CONVERGE trial is a set of prospective randomized
simultaneous hybrid trials using monopolar RF. These trials also use different operative
approaches. There are a number of other ongoing multicenter trials that are likely
to define the roles and lesion sets for treatment of patients with persistent AF using
these strategies.
The hybrid approach could hold significant promise for those patients with persistent
or long-standing persistent, drug-resistant AF to offer improved results over minimal
access surgical ablation or catheter ablation alone. Based on the literature and the
experience of the writing group members, we believe that it might be reasonable to
apply the indications for stand-alone surgical ablation described above to patients
being considered for hybrid surgical ablation (Class IIb, LOE C-EO, Table 2
).
The Future
The most successful programs in the future might be those that employ an interdisciplinary,
collaborative team approach to the treatment of AF, resulting in higher success rates
for patients. Many of these patients are well read and mobile and will seek out such
centers, thus increasing both catheter and surgical volumes. Practitioners in the
future will likely find value to working as part of a multidisciplinary team. The
precedent is set for this type of collaboration. The STS, the ACC, the FDA, and the
Centers for Medicare and Medicaid Services have joined together to collaboratively
introduce transcatheter AVR as a mandatory multidisciplinary team approach with mandatory
long-term follow-up. More work is needed in the area of collaborative ablation of
AF.
Section 13: Clinical Trial Design
Overview
Although there have been many advances made in the field of catheter and surgical
ablation of AF, there is still much to be learned about the mechanisms of initiation
and maintenance of AF and how to apply this knowledge to the still-evolving techniques
of AF ablation. Although single-center, observational reports have dominated the early
days of this field, we are quickly moving into an era in which hypotheses are put
through the rigor of testing in well-designed, randomized, multicenter clinical trials.
It is as a result of these trials that conventional thinking about the best techniques,
success rates, complication rates, and long-term outcomes beyond AF recurrence—such
as thromboembolism and mortality—is being put to the test. The ablation literature
has also seen a proliferation of meta-analyses and other aggregate analyses, which
reinforce the need for consistency in the approach to reporting the results of clinical
trials. This section will review the minimum requirements for reporting on AF ablation
trials. It will also acknowledge the potential limitations of using specific primary
outcomes and emphasize the need for broad and consistent reporting of secondary outcomes
to assist the end-user in determining not only the scientific, but also the clinical
relevance of the results.
Types of Clinical Trials, Strengths, and Weaknesses
Mortality Trials
Large, randomized, controlled multicenter trials are considered the “gold standard”
for many therapies in cardiovascular medicine. They are most likely to provide an
unbiased understanding of the outcomes of specific aspects of ablative intervention.
Although AF is associated with increased mortality and morbidity from stroke, HF,
and recurrent hospitalization, most of the AF ablation literature is focused on AF
recurrence and symptomatic improvement. It remains unclear whether ablation can affect
AF burden sufficiently to have a positive outcome with respect to mortality and stroke
endpoints. Trials powered to demonstrate a benefit for ablation with regard to these
“hard” endpoints require large numbers of patients with extensive follow-up and its
accompanying expense; however, the need for such trials cannot be understated. The
CABANA trial was powered to examine stroke and mortality outcomes of AF ablation compared
with pharmacological rate and rhythm control strategies. CABANA, which recently completed
enrollment, requires a minimum of 5 years of follow-up; thus, results will not be
available until 2018. In the meantime, EAST is a study that is currently enrolling
and is designed to compare standard care vs a strategy of early rhythm control with
ablation and/or AADs with endpoints including a composite outcome of cardiovascular
death, stroke, and hospitalization due to worsening of HF or acute coronary syndrome.
Although it is unclear whether these trials will demonstrate a mortality benefit of
AF ablation, both are designed to examine a host of prespecified secondary endpoints.
Secondary endpoints such as HF hospitalizations are especially important for patients
with uncontrolled rates and HF with preserved EF or tachycardia-induced cardiomyopathy.
Finally, because both trials will include larger numbers of patient ablations with
more novel technologies such as cryoablation and CFS than have been available in any
other study to date, significant advances in the understanding of ablation procedure
with these systems should be possible. Nevertheless, it remains imperative to continue
with designs of large mortality trials that reflect shifting global ablation techniques,
technologies, and patient selection. There are currently 45 trials that meet the search
criteria of “ablation mortality AF” on ClinicalTrials.gov; however, fewer than 10
have mortality as part of the primary endpoint.
Stroke and Thromboembolism Trials
Reductions in stroke and thromboembolism remain the most important goals of AF treatment.
It is unclear, however, if elimination of or reductions in AF will necessarily reduce
the associated risk of stroke, and whether such outcomes exceed those possible with
NOAC agents. Although an increased risk of stroke appears to be associated with brief
episodes of AF detected by implanted cardiac devices, multiple large randomized trials
have demonstrated that there might be no temporal relationship between AF episodes
and AF thromboembolic events. This possibility has cast significant doubt regarding
the direct causal role that AF plays in stroke. On the other hand, some cohort studies
of AF ablation have reported a lower risk of stroke postablation compared with matched,
nonablated AF populations. The impact of AF ablation on stroke and thromboembolism
is an important topic of future study and will likely require a combination of very
large studies with long durations of follow-up akin to CABANA and EAST. The OCEAN
study is currently getting started, and will examine the optimal strategy for ongoing
antithrombotic therapy 1 year after successful ablation in a moderate-risk profile
population with a primary endpoint of overt and covert stroke. It is important to
stress that until the results of these trials are known, the current recommendations
are to continue anticoagulation indefinitely in patients with CHA2DS2-VASc ≥2, regardless
of the success of the ablation procedure.
Periprocedural stroke reduction is an important topic that is actively being studied,
with various strategies of anticoagulation, particularly continuous administration
of VKA and non-VKA oral anticoagulants through the ablation procedure.
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In addition, concomitant LAA occlusion is being tested. In percutaneous procedures,
there are few if any studies powered for stroke alone; most primarily evaluate AF
recurrence.
Finally, multiple studies have demonstrated small ACE on MR brain imaging after ablation.
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The clinical significance of such ACE lesions is not known, and many will resolve
to the point of being undetectable after weeks or months. The impact on cognitive
function, if any, is not clear. At this point, there are no mandates for performing
periprocedural brain imaging for novel technologies to evaluate the incidence of silent
cerebral embolism, in large part because of its unknown clinical significance and
the cost and burden of MRI on patients. However, further evaluation of the significance
of such findings remains an important area of study.
Screening substudies could be reasonable for high-risk devices and should be combined
with clinical neurological and cognitive assessments. These silent cerebral emboli
are to be distinguished from covert embolic strokes secondary to long-term AF, which
have been linked with long-term cognitive decline, and are much larger than the silent
emboli seen periprocedurally.
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Multicenter Outcome Studies
There has been a proliferation of multicenter, randomized studies primarily geared
toward the outcome of AF recurrence in the last several years. Many of these studies
have had the appropriate size and power to make some important statements on the appropriate
techniques for AF ablation. Because of the endpoint of AF recurrence, these studies
can be performed with smaller sample sizes and shorter follow-up periods compared
with mortality- or stroke-driven trials. A number of randomized trials have demonstrated
the superiority of AF ablation over AADs in drug-refractory patients. First-line catheter
ablation has shown mixed results over first-line drug therapy in the MANTRA-PAF and
RAAFT-2 studies.
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STAR AF 2, Adenosine Following Pulmonary Vein Isolation to Target Dormant Conduction
Elimination (ADVICE), FIRE AND ICE, and TOCCASTAR are just a few examples of multicenter
randomized studies that have included hundreds of patients per study and added important
contributions to the daily practice of AF ablation.
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STAR AF 2, for example, challenged the long-held belief that additional ablation beyond
PVI is important for ablation of persistent AF and has launched a new search for alternative
targets to CFAE and empiric lines. It remains possible that incomplete ablation in
these arenas is more problematic than the ablation format itself. As reported recently,
the FIRE AND ICE trial has shown an equivalence of evolving cryoablation technologies
to traditional RF. The ADVICE trial showed that systematic use of adenosine to search
for dormant conduction can improve durability of PVI and associated 1-year outcome,
although studies reported earlier in this document raise questions about the overall
utility of adenosine or isoproterenol. There are many more studies planned to examine
various aspects of AF ablation, primarily around the comparison of techniques in certain
patient populations to improve ablation outcomes. As expected, a criticism of all
such trials is that the technology and techniques are outdated prior to trial completion.
STAR AF 2 did not use CFS and FIRE AND ICE used a mixture of first- and second-generation
CB technologies. Therefore, ongoing trials comparing the most up-to-date technologies
will always be required. Larger-scale surgical ablation trials are lacking, and the
consensus group believes that the development of well designed, highly agile, large-scale
multicenter surgical trials with similar monitoring regimens need to be encouraged
and performed. As with catheter-based studies and registries, the use of patient-reported
outcome measures as part of the study endpoints is highly recommended.
Industry-Sponsored Device Approval Studies
There have been a number of prospective randomized studies performed to evaluate the
safety and efficacy of investigational devices used for AF ablation. These studies,
such as THERMOCOOL IDE and STOP AF, have all provided important, high-quality data
demonstrating the superiority of catheter ablation over drug therapy in drug refractory
patients.
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Now that the utility of ablation over drug therapy in such patients has been accepted,
many of the current studies are focused on comparing new technologies against approved
devices in a noninferiority design. Although these studies are important from a safety
and efficacy perspective and are often mandated by health approval bodies such as
the FDA, the incremental yield in knowledge could be limited. Prespecified subgroup
analyses, or the use of novel endpoints. could therefore be important to determine
whether incremental value is added by the newer technology. TOCCASTAR, for example,
demonstrated statistical noninferiority of CF-driven RF ablation to traditional RF.
However, only in a post-hoc analysis did the trial show that optimal CF was associated
with better outcomes, findings which should be viewed with caution due to the limitations
of post hoc analyses. Testing of the durability of lesion sets such as PVI either
after delayed waiting, drug (adenosine) challenge, or repeat electrophysiology study
after 3 months might also help assess comparative efficacy more accurately. Industry
must also look to see whether safety and efficacy parameters demonstrated in PAF also
apply to nonparoxysmal populations. Several industry-sponsored studies are either
being planned or are in progress to assess outcomes in this challenging population.
Registry Studies
AF ablation registries offer a unique opportunity to collect data from large numbers
of patients to examine outcomes. In particular, registries might help assess how ablation
is being performed in the “real world” compared with controlled clinical trials that
are often performed on a highly selected patient population in very experienced centers.
The definition of real world remains problematic, however, because recent studies
have shown reasonable congruence between the outcomes of RCTs and registries. Registries
are well suited to determining early complication rates of ablation, particularly
for less common ones such as PV stenosis, esophageal injury, or mortality. Appropriateness
of patient selection and outcomes in patient subgroups that are underrepresented in
studies, such as women or patients with underlying structural heart disease, can also
be assessed in sizable registries. The collection of this kind of information, by
itself, makes registries worthwhile if they can be performed with sufficient representation
of a majority of centers. Still, well-controlled efforts such as the STS database
have shown an even-handed approach to collecting this kind of material. Worldwide
surveys of AF ablation have been published, and ongoing efforts are being made to
harmonize various centers or national databases to pool ablation information. Many
countries are now setting up provincial or national registries to examine the use
and outcomes of AF ablation. In the United States, for example, the older Safety of
Atrial Fibrillation Ablation Registry Initiative registry project was discontinued,
but another started by the National Cardiovascular Data Registry (NCDR) has been launched
nationally, with voluntary participation. The HRS is also collaborating with the AHA
to develop an additional AF ablation registry. Surgical data are currently being collected
in the STS database; however, although data on safety and outcome are available, lesion-specific
information for surgical ablation remains preliminary. Collection of longitudinal
data, particularly longer-term outcomes, can be limited by a lack of patient follow-up
at the same center and a lack of consistent monitoring protocols. The need for informed
consent to collect follow-up data also remains an obstacle to obtaining outcome data.
The burden of data entry can also lead to inadequate reporting, and the cost of auditing
data can be very expensive and tedious. The purpose of establishing a registry and
the realistic goals of data collection must be stated outright upon establishment,
because the opportunity and financial costs could be alternatively spent on well-designed
clinical trials. Comparison of performance among sites, for example, must be based
on the stated purposes and strengths of the registry. If the main purpose is to report
acute complications, then long-term outcomes cannot be compared. Comparisons must
also be corrected for patient characteristics, referral patterns to the institution,
and community-based versus advanced academic practices. Finally, once the stated goals
of the registry are accomplished, there should be specific timeframes for termination
of the registry to avoid indefinite data collection with no specific stated purpose.
Clinical Endpoint Considerations
Early data in the field of AF ablation were limited by the multitude of different
endpoints used in the trials, including multiple definitions of success, complications,
and minimum monitoring postablation. Prior consensus statements sought to create consistency
in the reporting of clinical trials by adopting standardized definitions for AF type,
blanking periods, definitions of success, recommendations for minimal monitoring postablation,
major complications, and device-related complications.
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,
2
Again, this document outlines the definitions of various types of AF (Table 1
), definitions of efficacy (Table 10
), QOL measures (Table 11
), non-AF recurrence endpoints (Table 12
), and definitions of complications (Table 8
).
Table 10
Definitions for use when reporting outcomes of AF ablation and in designing clinical
trials of catheter or surgical ablation of AF
Acute procedural success(pulmonary vein isolation)
Acute procedural success is defined as electrical isolation of all pulmonary veins.
A minimal assessment of electrical isolation of the PVs should consist of an assessment
of entrance block. If other methods are used to assess PVI, including exit block and/or
the use of provocative agents such as adenosine or isoproterenol, they should be prespecified.
Furthermore, it is recommended that the wait time used to screen for early recurrence
of PV conduction once initial electrical isolation is documented be specified in all
prospective clinical trials.
Acute procedural success (not related by pulmonary vein isolation)
Typically, this would apply to substrate ablation performed in addition to PVI for
persistent AF. Although some have proposed AF termination as a surrogate for acute
procedural success, its relationship to long-term success is controversial. Complete
elimination of the additional substrate (localized rotational activation, scar region,
non-PV trigger, or other target) and/or demonstration of bidirectional conduction
block across a linear ablation lesion would typically be considered the appropriate
endpoint.
One-year success∗
One-year success is defined as freedom from AF/AFL/AT after removal from antiarrhythmic
drug therapy as assessed from the end of the 3month blanking period to 12 months following
the ablation procedure. Because cavotricuspid isthmus-dependent atrial flutter is
easily treated with cavotricuspid isthmus ablation and is not an iatrogenic arrhythmia
following a left atrial ablation procedure for AF, it is reasonable for clinical trials
to choose to prespecify that occurrence of isthmus-dependent atrial flutter, if confirmed
by entrainment maneuvers during electrophysiology testing, should not be considered
an ablation failure or primary effectiveness endpoint.
Alternative one-year success
Although the one-year success definition provided above remains the recommended end
point that should be reported in all AF ablation trials, and the endpoint for which
the objective performance criteria listed below were developed, the Task Force recognizes
that alternative definitions for success can be used if the main goal of therapy in
the study is to relieve AF-related symptoms and to improve patient QOL. In particular,
it is appropriate for clinical trials to define success as freedom from only symptomatic
AF/AFL/AT after removal from antiarrhythmic drug therapy as assessed from the end
of the 3-month blanking period to 12 months following the ablation procedure if the
main goal of therapy in the study is to relieve AF-related symptoms and to improve
patient QOL. However, because symptoms of AF can resolve over time, and because studies
have shown that asymptomatic AF represents a greater proportion of all AF postablation
than prior to ablation, clinical trials need to continue to report freedom from both
symptomatic and asymptomatic AF even if this alternative one year success definition
is used as the primary trial endpoint.
Clinical/partial success∗
It is reasonable for clinical trials to define and incorporate one or more secondary
definitions of success that can be referred to as “clinical success” or “partial success.”
If these alternative definitions of success are included, they should be defined prospectively.
In prior Consensus Documents the Task Force has proposed that clinical/partial success
be defined as a “75% or greater reduction in the number of AF episodes, the duration
of AF episodes, or the % time a patient is in AF as assessed with a device capable
of measuring AF burden in the presence or absence of previously ineffective antiarrhythmic
drug therapy.” Because there is no firm scientific basis for selecting the cutoff
of 75% rather than a different cutoff, this prior recommendation is provided only
as an example of what future clinical trials may choose to use as a definition of
clinical/partial success.
Long-term success∗
Long-term success is defined as freedom from AF/AFL/AT recurrences following the 3-month
blanking period through a minimum of 36-month follow-up from the date of the ablation
procedure in the absence of Class I and III antiarrhythmic drug therapy.
Recurrent AF/AFL/AT
Recurrent AF/AFL/AT is defined as AF/AFL/AT of at least 30 seconds' duration that
is documented by an ECG or device recording system and occurs following catheter ablation.
Recurrent AF/AFL/AT may occur within or following the post ablation blanking period.
Recurrent AF/AFL/AT that occurs within the postablation blanking period is not considered
a failure of AF ablation.
Early recurrence of AF/AFL/AT
Early recurrence of AF/AFL/AT is defined as a recurrence of atrial fibrillation within
three months of ablation. Episodes of atrial tachycardia or atrial flutter should
also be classified as a “recurrence.” These are not counted toward the success rate
if a blanking period is specified.
Recurrence of AF/AFL/AT
Recurrence of AF/AFL/AT postablation is defined as a recurrence of atrial fibrillation
more than 3 months following AF ablation. Episodes of atrial tachycardia or atrial
flutter should also be classified as a “recurrence.”
Late recurrence of AF/AFL/AT
Late recurrence of AF/AFL/AT is defined as a recurrence of atrial fibrillation 12 months
or more after AF ablation. Episodes of atrial tachycardia or atrial flutter should
also be classified as a “recurrence.”
Blanking period
A blanking period of three months should be employed after ablation when reporting
efficacy outcomes. Thus, early recurrences of AF/AFL/AT within the first 3 months
should not be classified as treatment failure. If a blanking period of less than 3 months
is chosen, it should be prespecified and included in the Methods section.
Stroke screening
A risk-based approach to determine the level of postablation stroke screening in clinical
trials is recommended by the Task Force. For ablation devices with a lower risk of
stroke and for which a stroke signal has not been reported, a minimum standardized
neurological assessment of stroke should be conducted by a physician at baseline and
at hospital discharge or 24 hours after the procedure, whichever is later. If this
neurological assessment demonstrates new abnormal findings, the patient should have
a formal neurological consult and examination with appropriate imaging (i.e., DW-MRI),
used to confirm any suspected diagnosis of stroke. For devices in which a higher risk
of stroke is suspected or revealed in prior trials, a formal neurological examination
by a neurologist at discharge or 24 hours after the procedure, whichever is later,
is recommended. Appropriate imaging should be obtained if this evaluation reveals
a new neurological finding. In some studies in which delayed stroke is a concern,
repeat neurological screening at 30 days postablation might be appropriate.
Detectable AF/AFL/AT
Detectable AF is defined as AF/AFL/AT of at least 30 seconds' duration when assessed
with ECG monitoring. If other monitoring systems are used, including implantable pacemakers,
implantable defibrillators, and subcutaneous ECG monitoring devices, the definition
of detectable AF needs to be prespecified in the clinical trial based on the sensitivity
and specificity of AF detection with the particular device. We recommend that episodes
of atrial flutter and atrial tachycardia be included within the broader definition
of a detectable AF/AFL/AT episode.
AF/AFL/AT burden
It is reasonable for clinical trials to incorporate AF/AFL/AT burden as a secondary
endpoint in a clinical trial of AF ablation. In stating this it is recognized that
there are no conclusive data that have validated a rate of AF burden reduction as
a predictor of patient benefit (i.e. reduction in mortality and major morbidities
such as stroke, CHF, QOL, or hospitalization). If AF burden is included, it is important
to predefine and standardize the monitoring technique that will be used to measure
AF burden. Available monitoring techniques have been discussed in this document. Should
AF burden be selected as an endpoint in a clinical trial, the chosen monitoring technique
should be employed at least a month prior to ablation to establish a baseline burden
of AF.
Entrance block
Entrance block is defined as the absence, or if present, the dissociation, of electrical
activity within the PV antrum. Entrance block is most commonly evaluated using a circular
multielectrode mapping catheter positioned at the PV antrum. Entrance block can also
be assessed using detailed point-by-point mapping of the PV antrum guided by an electroanatomical
mapping system. The particular method used to assess entrance block should be specified
in all clinical trials. Entrance block of the left PVs should be assessed during distal
coronary sinus or left atrial appendage pacing in order to distinguish far-field atrial
potentials from PV potentials. It is recommended that reassessment of entrance block
be performed a minimum of 20 minutes after initial establishment of PV isolation.
Procedural endpoints for AF ablation strategies not targeting the PVs
Procedural endpoints for AF ablation strategies not targeting the PVs: The acute procedural
endpoints for ablation strategies not targeting the PVs vary depending on the specific
ablation strategy and tool. It is important that they be prespecified in all clinical
trials. For example, if a linear ablation strategy is used, documentation of bidirectional
block across the ablation line must be shown. For ablation of CFAEs, rotational activity,
or non-PV triggers, the acute endpoint should at a minimum be elimination of CFAEs,
rotational activity, or non-PV triggers. Demonstration of AF slowing or termination
is an appropriate procedural endpoint, but it is not required as a procedural endpoint
for AF ablation strategies not targeting the PVs.
Esophageal temperature monitoring
Esophageal temperature monitoring should be performed in all clinical trials of AF
ablation. At a minimum, a single thermocouple should be used. The location of the
probe should be adjusted during the procedure to reflect the location of energy delivery.
Although this document does not provide formal recommendations regarding the specific
temperature or temperature change at which energy delivery should be terminated, the
Task Force does recommend that all trials prespecify temperature guidelines for termination
of energy delivery.
Enrolled subject
An enrolled subject is defined as a subject who has signed written informed consent
to participate in the trial in question.
Exit block
Exit block is defined as the inability to capture the atrium during pacing at multiple
sites within the PV antrum. Local capture of musculature within the pulmonary veins
and/or antrum must be documented to be present to make this assessment. Exit block
is demonstrated by a dissociated spontaneous pulmonary vein rhythm.
Nonablative strategies
The optimal nonablative therapy for patients with persistent and long-standing persistent
AF who are randomized to the control arm of an AF ablation trial is a trial of a new
Class I or III antiarrhythmic agent or a higher dose of a previously failed antiarrhythmic
agent. For patients with persistent or long-standing persistent AF, performance of
a direct-current cardioversion while taking the new or dose adjusted antiarrhythmic
agent should be performed, if restoration of sinus rhythm is not achieved following
initiation and/or dose adjustment of antiarrhythmic drug therapy. Failure of pharmacological
cardioversion alone is not adequate to declare this pharmacological strategy unsuccessful.
Noninducibility of atrial fibrillation
Noninducibility of atrial fibrillation is defined as the inability to induce atrial
fibrillation with a standardized prespecified pharmacological or electrical stimulation
protocol. The stimulation protocol should be prespecified in the specific clinical
trial. Common stimulation approaches include a high-dose isoproterenol infusion protocol
or repeated atrial burst pacing at progressively more rapid rates.
Patient populations for inclusion in clinical trials
It is considered optimal for clinical trials to enroll patients with only one type
of AF: paroxysmal, persistent, or long-standing persistent. If more than one type
of AF patient is enrolled, the results of the trial should also be reported separately
for each of the AF types. It is recognized that “early persistent” AF responds to
AF ablation to a similar degree as patients with paroxysmal AF and that the response
of patients with “late persistent AF” is more similar to that in those with long-standing
persistent AF.
Therapy consolidation period
Following a 3-month blanking period, it is reasonable for clinical trials to incorporate
an additional 1- to 3-month therapy consolidation period. During this time, adjustment
of antiarrhythmic medications and/or cardioversion can be performed. Should a consolidation
period be incorporated into a clinical trial design, the minimum follow-up duration
should be 9 months following the therapy consolidation period. Performance of a repeat
ablation procedure during the blanking or therapy consolidation period would “reset”
the endpoint of the study and trigger a new 3-month blanking period. Incorporation
of a therapy consolidation period can be especially appropriate for clinical trials
evaluating the efficacy of AF ablation for persistent or long-standing persistent
AF. The challenge of this approach is that it prolongs the overall study duration.
Because of this concern regarding overall study duration, we suggest that the therapy
consolidation period be no more than 3 months in duration following the 3-month blanking
period.
Recommendations regarding repeat ablation procedures
It is recommended that all clinical trials report the single procedure efficacy of
catheter ablation. Success is defined as freedom from symptomatic or asymptomatic
AF/AFL/AT of 30 seconds or longer at 12 months postablation. Recurrences of AF/AFL/AT
during the first 3-month blanking period post-AF ablation are not considered a failure.
Performance of a repeat ablation procedure at any point after the initial ablation
procedure should be considered a failure of a single procedure strategy. It is acceptable
for a clinical trial to choose to prespecify and use a multiprocedure success rate
as the primary endpoint of a clinical trial. When a multiprocedure success is selected
as the primary endpoint, efficacy should be defined as freedom from AF/flutter or
tachycardia at 12 months after the final ablation procedure. In the case of multiple
procedures, repeat ablation procedures can be performed at any time following the
initial ablation procedure. All ablation procedures are subject to a 3-month post
blanking window, and all ablation trials should report efficacy at 12 months after
the final ablation procedure.
Cardioversion definitions
Failed electrical cardioversion
Failed electrical cardioversion is defined as the inability to restore sinus rhythm
for 30 seconds or longer following electrical cardioversion.
Successful electrical cardioversion
Successful electrical cardioversion is defined as the ability to restore sinus rhythm
for at least 30 seconds following cardioversion.
Immediate AF recurrence postcardioversion
Immediate AF recurrence postcardioversion is defined as a recurrence of AF within
24 hours following cardioversion. The most common time for an immediate recurrence
is within 30–60 minutes postcardioversion.
Early AF recurrence postcardioversion
Early AF recurrence postcardioversion is defined as a recurrence of AF within 30 days
of a successful cardioversion.
Late AF recurrence postcardioversion
Late AF recurrence postcardioversion is defined as recurrence of AF more than 30 days
following a successful cardioversion.
Surgical ablation definitions
Hybrid AF surgical ablation procedure
Hybrid AF surgical ablation procedure is defined as a joint AF ablation procedure
performed by electrophysiologists and cardiac surgeons either as part of a single
“joint” procedure or performed as two preplanned separate ablation procedures separated
by no more than 6 months.
Surgical Maze ablation procedure
Surgical Maze ablation procedure is defined as a surgical ablation procedure for AF
that includes, at a minimum, the following components: (1) line from SVC to IVC; (2) line
from IVC to the tricuspid valve; (3) isolation of the PVs; (4) isolation of the posterior
left atrium; (5) line from MV to the PVs; (6) management of the LA appendage.
Stand-alone surgical AF ablation
A surgical AF ablation procedure during which other cardiac surgical procedures are
not performed such as CABG, valve replacement, or valve repair.
Nomenclature for types of surgical AF ablation procedures
We recommend that the term “Maze” procedure is appropriately used only to refer to
the biatrial lesion set of the Cox-Maze operation. It requires ablation of the RA
and LA isthmuses. Less extensive lesion sets should not be referred to as a “Maze”
procedure, but rather as a surgical AF ablation procedure. In general, surgical ablation
procedures for AF can be grouped into three different groups: (1) a full biatrial
Cox-Maze procedure; (2) PVI alone; and (3) PVI combined with left atrial lesion sets.
Hybrid epicardial and endocardial AF ablation
This term refers to a combined AF ablation procedure involving an off-pump minimally
invasive surgical AF ablation as well as a catheter-based AF ablation procedure designed
to complement the surgical lesion set. Hybrid ablation procedures may be performed
in a single-procedure setting in a hybrid operating room or a cardiac catheterization
laboratory environment, or it can be staged. When staged, it is most typical to have
the patient undergo the minimally invasive surgical ablation procedure first following
by a catheter ablation procedure 1 to 3 months later. This latter approach is referred
to as a “staged Hybrid AF ablation procedure.”
Minimum AF documentation, endpoints, TEE performance, and success rates in clinical
trials
Minimum documentation for paroxysmal AF
The minimum AF documentation requirement for paroxysmal AF is (1) physician's note
indicating recurrent self-terminating AF and (2) one electrocardiographically documented
AF episode within 6 months prior to the ablation procedure.
Minimum documentation for persistent AF
The minimum AF documentation requirement for persistent AF is (1) physician's note
indicating continuous AF > 7 days but no more than 1 year and (2) a 24-hour Holter
within 90 days of the ablation procedure showing continuous AF.
Minimum documentation for early persistent AF
The minimum AF documentation requirement for persistent AF is (1) physician's note
indicating continuous AF > 7 days but no more than 3 months and (2) a 24-hour Holter
showing continuous AF within 90 days of the ablation procedure.
Minimum documentation for long-standing persistent AF
The minimum AF documentation requirement for long-standing persistent AF is as follows:
physician's note indicating at least 1 year of continuous AF plus a 24-hour Holter
within 90 days of the ablation procedure showing continuous AF. The performance of
a successful cardioversion (sinus rhythm >30 seconds) within 12 months of an ablation
procedure with documented early recurrence of AF within 30 days should not alter the
classification of AF as long-standing persistent.
Symptomatic AF/AFL/AT
AF/AFL/AT that results in symptoms that are experienced by the patient. These symptoms
can include but are not limited to palpitations, presyncope, syncope, fatigue, and
shortness of breath. For patients in continuous AF, reassessment of symptoms after
restoration of sinus rhythm is recommended to establish the relationship between symptoms
and AF.
Documentation of AF-related symptoms
Documentation by a physician evaluating the patient that the patient experiences symptoms
that could be attributable to AF. This does not require a time-stamped ECG, Holter,
or event monitor at the precise time of symptoms. For patients with persistent AF
who initially report no symptoms, it is reasonable to reassess symptom status after
restoration of sinus rhythm with cardioversion.
Minimum effectiveness endpoint for patients with symptomatic and asymptomatic AF
The minimum effectiveness endpoint is freedom from symptomatic and asymptomatic episodes
of AF/AFL/AT recurrences at 12 months following ablation, free from antiarrhythmic
drug therapy, and including a prespecified blanking period.
Minimum chronic acceptable success rate: paroxysmal AF at 12-month follow-up
If a minimum chronic success rate is selected as an objective effectiveness endpoint
for a clinical trial, we recommend that the minimum chronic acceptable success rate
for paroxysmal AF at 12-month follow-up is 50%.
Minimum chronic acceptable success rate: persistent AF at 12-month follow-up
If a minimum chronic success rate is selected as an objective effectiveness endpoint
for a clinical trial, we recommend that the minimum chronic acceptable success rate
for persistent AF at 12-month follow-up is 40%.
Minimum chronic acceptable success rate: long-standing persistent AF at 12-month follow-up
If a minimum chronic success rate is selected as an objective effectiveness endpoint
for a clinical trial, we recommend that the minimum chronic acceptable success rate
for long-standing persistent AF at 12-month follow-up is 30%.
Minimum follow-up screening for paroxysmal AF recurrence
For paroxysmal AF, the minimum follow-up screening should include (1) 12-lead ECG
at each follow-up visit; (2) 24-hour Holter at the end of the follow-up period (e.g.,
12 months); and (3) event recording with an event monitor regularly and when symptoms
occur from the end of the 3-month blanking period to the end of follow-up (e.g., 12 months).
Minimum follow-up screening for persistent or long-standing AF recurrence
For persistent and long-standing persistent AF, the minimum follow-up screening should
include (1) 12-lead ECG at each follow-up visit; (2) 24-hour Holter every 6 months;
and (3) symptom-driven event monitoring.
Requirements for transesophageal echocardiogram
It is recommended that the minimum requirement for performance of a TEE in a clinical
trial should be those requirements set forth in ACC/AHA/HRS 2014 Guidelines for AF
Management pertaining to anticoagulation at the time of cardioversion. Prior to undergoing
an AF ablation procedure a TEE should be performed in all patients with AF of > 48 hours'
duration or of unknown duration if adequate systemic anticoagulation has not been
maintained for at least 3 weeks prior to AF ablation. If a TEE is performed for this
indication, it should be performed within 24 hours of the ablation procedure.
AF, atrial fibrillation; DW-MRI, diffusion-weighted magnetic resonance imaging; CHF,
congestive heart failure; QOL, quality of life; ECG, electrocardiogram; CABG, coronary
artery bypass grafting; PV, pulmonary vein; SVC, superior vena cava; IVC, inferior
vena cava; CFAE, complex fractionated atrial electrogram; PVI, pulmonary vein isolation;
AFL, atrial flutter; AT, atrial tachycardia; ACC, American College of Cardiology;
AHA, American Heart Association; HRS, Heart Rhythm Society.
∗
When reporting outcomes of AF ablation, the development of atrial tachycardia or atrial
flutter should be included in the broad definition of recurrence following AF ablation.
All studies should report freedom from AF, atrial tachycardia, and atrial flutter.
These endpoints can also be reported separately. All studies should also clearly specify
the type and frequency of ECG monitoring as well as the degree of compliance with
the prespecified monitoring protocol.
Table 11
Quality-of-life scales, definitions, and strengths
Scale
Definition/Details
Strengths/Weaknesses
Short Form (36) Health Survey (SF36)38
Consists of 8 equally weighted, scaled scores in the following sections: vitality,
physical functioning, bodily pain, general health perceptions, physical role functioning,
emotional role functioning, social role functioning, mental health. Each section receives
a scale score from 0 to 100.
Advantages: extensively validated in a number of disease and health states. Might
have more resolution than EQ-50 for AF QOL.
(General)
Physical component summary (PCS) and mental component summary (MCS) is an average
of all the physically and mentally relevant questions, respectively.
Disadvantages: not specific for AF, so might not have resolution to detect AF-specific
changes in QOL.
The Short Form (12) Health Survey (SF12) is a shorter version of the SF-36, which
uses just 12 questions and still provides scores that can be compared with SF-36 norms,
especially for summary physical and mental functioning.
Gives more precision in measuring QOL than EQ-5D but can be harder to transform into
cost utility analysis.
EuroQol Five Dimensions Questionnaire (EQ-5D)39 (General)
Two components: Health state description is measured in five dimensions: mobility,
self-care, usual activities, pain/discomfort, anxiety/depression. Answers may be provided
on a three-level (3L) or five-level (5L) scale. In the Evaluation section, respondents
evaluate their overall health status using a visual analogue scale (EQ-VAS). Results
can easily be converted to quality-adjusted life years for cost utility analysis.
Advantages: extensively validated in a number of disease and health states. Can easily
be converted into quality-adjusted life years for cost-effectiveness analysis.
Disadvantages: might not be specific enough to detect AF-specific changes in QOL.
Might be less specific than SF-36.
AF effect on Quality of Life Survey (AFEQT)40 (AF specific)
20 questions: 4 targeting AF-related symptoms, 8 evaluating daily function, and 6
assessing AF treatment concerns. Each item scored on a 7-point Likert scale.
Advantages: brief, simple, very responsive to AF interventions. Good internal validity
and well validated against a number of other global and AF-specific QOL scales. Used
in CABANA.
Disadvantages: validation in only two published studies (approximately 219 patients).
Quality of Life Questionnaire for Patients with AF
18-item self-administered questionnaire with three domains: psychological, physical,
and sexual activity. Each item scores on a 5-point Likert scale.
Advantages: brief, simple, responsive to AF interventions; good internal validity;
used in SARA trial.
(AF-QoL)41
Disadvantages: external validity compared only to SF-36; formal validation in 1 study
(approximately 400 patients).
(AF specific)
Arrhythmia-Related Symptom Checklist (SCL)42 (AF specific)
16 items covering AF symptom frequency and symptom severity.
Advantages: most extensively validated in a number of arrhythmia cohorts and clinical
trials.
Disadvantages: time-consuming and uncertain generalizability.
Mayo AF Specific Symptom Inventory (MAFSI)43 (AF specific)
10 items covering AF symptom frequency and severity. Combination of 5- point and 3-point
Likert scale responses.
Advantages: validated in an AF ablation population and responsive to ablation outcome;
used in CABANA trial.
Used in CABANA trial.
Disadvantages: external validity compared only to SF-36; 1 validation study (approximately
300 patients).
University of Toronto Atrial Fibrillation Severity Scale (AFSS) (AF specific)44
10 items covering frequency, duration, and severity. 7-point Likert scale responses.
Advantages: validated and reproducible; used in CTAF trial.
Disadvantages: time-consuming and uncertain generalizability.
Arrhythmia Specific Questionnaire in Tachycardia and Arrhythmia (ASTA)45 (AF specific)
Records number of AF episodes and average episode duration during last 3 months. 8
symptoms and 2 disabling symptoms are recorded with scores from 1–4 for each.
Advantages: validated in various arrhythmia groups; external validity compared with
SCL, EQ5D, and SF-36; used in MANTRA-PAF; brief; simple.
Disadvantages: one validation study (approximately 300 patients).
European Heart Rhythm Association (EHRA)46 (AF specific)
Like NYHA scale. I, no symptoms, II, mild symptoms not affecting daily activity, III,
severe symptoms affecting daily activity, and IV, disabling symptoms terminating daily
activities.
Advantage: very simple, like NYHA.Disadvantages: not used in studies and not well
validated; not very specific; unknown generalizability.
Canadian Cardiovascular Society Severity of Atrial Fibrillation Scale (CCS-SAF)47
(AF specific)
Like NYHA scale. O, asymptomatic, I, AF symptoms have minimal effect on patient's
QOL, II, AF symptoms have minor effect on patient QOL, III, symptoms have moderate
effect on patient QOL, IV= AF symptoms have severe effect on patient QOL.
Advantages: very simple, like NYHA; validated against SF-36 and University of Toronto
AFSS.
Disadvantages: poor correlation with subjective
AF burden; not very specific.
AF, atrial fibrillation; QOL, quality of life; CABANA, Catheter Ablation vs Anti-arrhythmic
Drug Therapy for Atrial Fibrillation; SARA, Study of Ablation Versus antiaRrhythmic
Drugs in Persistent Atrial Fibrillation; CTAF, Canadian Trial of Atrial Fibrillation;
MANTRA-PAF, Medical ANtiarrhythmic Treatment or Radiofrequency Ablation in Paroxysmal
Atrial Fibrillation; NYHA, New York Heart Association; AFSS, atrial fibrillation severity
scale.
Table 12
Non-AF recurrence–related endpoints for reporting in AF ablation trials
Stroke and bleeding endpoints
Definitions/Details
Stroke (2014 ACC/AHA Key Data Elements)
An acute episode of focal or global neurological dysfunction caused by brain, spinal
cord, or retinal vascular injury as a result of hemorrhage or infarction. Symptoms
or signs must persist ≥24 hours, or if documented by CT, MRI or autopsy, the duration
of symptoms/signs may be less than 24 hours. Stroke may be classified as ischemic
(including hemorrhagic transformation of ischemic stroke), hemorrhagic, or undetermined.
Stroke disability measurement is typically performed using the modified Rankin Scale
(mRS).
Transient ischemic attack (2014 ACC/AHA Key Data Elements)
Transient episode of focal neurological dysfunction caused by brain, spinal cord,
or retinal ischemia without acute infarction and with signs and symptoms lasting less
than 24 hours.
Major bleeding (ISTH definition)
Fatal bleeding AND/OR symptomatic bleeding in a critical area or organ, such as intracranial,
intraspinal, intraocular, retroperitoneal, intraarticular, pericardial, or intramuscular
with compartment syndrome AND/OR bleeding causing a fall in hemoglobin level of 2 g/dL
(1.24 mmol/L) or more, or leading to transfusion of two or more units of blood.
Clinically relevant nonmajor bleed (ISTH definition)
An acute or subacute clinically overt bleed that does not meet the criteria for a
major bleed but prompts a clinical response such that it leads to one of the following:
hospital admission for bleeding; physician-guided medical or surgical treatment for
bleeding; change in antithrombotic therapy (including interruption or discontinuation).
Minor bleeding (ISTH definition)
All nonmajor bleeds. Minor bleeds are further divided into clinically relevant and
not.
Incidence and discontinuation of oral anticoagulation
The number of patients receiving oral anticoagulation and the type of oral anticoagulation
should be documented at the end of follow-up. If patients have their oral anticoagulation
discontinued, the number of patients discontinuing, the timing of discontinuation,
and the reasons for discontinuation of oral anticoagulation, as well as the clinical
characteristics and stroke risk profile of the patients should be reported.
AF, atrial fibrillation; CT, computed tomography; MRI, magnetic resonance imaging.
Clinical endpoints for AF ablation trials may either consist of clinical events like
mortality, stroke, re-initiation of AAD treatment, need for cardioversion, reablation
and rehospitalization, or of patient-reported outcomes such as symptom severity or
QOL. AF recurrence or change in AF behavior is a very important endpoint to report
in trials targeting AF elimination. The following section will focus on recommendations
and definitions for AF-related measurements used in clinical ablation trials.
Blanking Period
It has long been recognized that in the weeks immediately following AF ablation, early
recurrences of atrial arrhythmia can occur that subsequently subside over time.
253
,
254
,
255
,
436
Whether this is due to an early “inflammatory” response in the atrium or pericardium
remains hypothetical. Based on these observations, prior consensus statements, and
the present consensus document, the writing group recommends the use of a 3-month
blanking period immediately postablation, during which arrhythmia recurrences are
not counted toward the primary recurrence endpoint (Table 10
). The use of a blanking period is not without limitations. Although half of all early
recurrences might subside, early recurrence remains a very significant predictor of
late recurrence of AF.
141
,
142
,
143
,
255
Furthermore, some studies have shown that recurrences occurring early in the blanking
period (within 1–2 months) are less predictive of late recurrence, whereas those occurring
in the third month have a very high predictive value for later recurrence.
933
,
977
,
1389
Blanking periods can also be applied inconsistently, typically after the initial ablation,
but not typically after repeat procedures, particularly when there is only a limited
duration of follow-up. Despite these limitations, the writing group consensus continues
to recommend the use of a 3-month blanking period for atrial arrhythmia recurrences
post-initial ablation for AF. If alternate durations of blanking are employed, they
should be prespecified in the trial methodology. Clinical trials should also consider
routine discontinuation of AADs after the blanking period to determine off-drug success
rates of ablation. Large clinical trials such as CABANA have also employed extensive
ongoing monitoring, which could shed light on more robust blanking period definitions.
The currently recommended definitions of the blanking periods, monitoring standards,
complications, and other AF ablation clinical trial definitions are provided in Tables
8 and 10.
AF Recurrence Endpoints
The selection of a primary endpoint depends on the objectives of the trial. As mentioned
earlier in this section, trials with mortality, stroke, or hospitalization outcomes
are of particular interest in advancing the field of AF ablation. However, now and
in the foreseeable future, recurrence of AF will remain of primary interest for most
clinical trials. A summary of AF-related endpoints is listed in Table 13
, along with the advantages and disadvantages of each endpoint.
Table 13
Advantages and disadvantages of AF-related endpoints in AF ablation trials
Endpoint
Advantages
Disadvantages
Relevance and Comments
Freedom from AF/AFL/AT recurrence “gold standard” is 30 seconds
Has been in use for many years
Can be used to compare results of new trials with historical trials
Sets a high bar for AF elimination
Can systematically underestimate the efficacy of AF ablation, particularly for persistent
AF, if 30-second cutoff is used
Particularly well suited for paroxysmal AF outcomes
Reporting of cutoffs other than 30 seconds encouraged as secondary endpoints to better
contextualize results
May be reported as proportion of patients free from arrhythmia or time to recurrence
Freedom from stroke-relevant AF/AFL/AT-duration cutoff of 1 hour
Useful for trials in which interest is more for prognostic change conferred by ablation
rather than elimination of all arrhythmias
No consistent definition of what a stroke-relevant duration of AF is: ranges from
6 minutes to 24 hours in literature
More than 1 hour could be a useful cutoff based on results of 505 trial
May be reported as proportion of patients free from arrhythmia or time to recurrence
Freedom from AF/AFL/AT requiring intervention (emergency visits, cardioversion, urgent
care visit, reablation, etc.)
Can provide an endpoint more relevant to systemic costs of AF recurrence
Clinically relevant
Will overestimate efficacy of ablation by ignoring shorter episodes not requiring
intervention that still might be important to quality of life or stroke
Determination of what is an “intervention” must be prespecified in protocol and biases
mitigated to avoid over- or underintervention in the trial
Freedom from persistent AF/AFL/AT-duration cutoff of 7 days
Useful for trials assessing additional substrate modification in persistent AF
Can systematically overestimate the efficacy of AF ablation, particularly for persistent
AF
Can require continuous monitoring to definitively assess if episode is > 7 days
Freedom from AF/AFL/AT on previously ineffective antiarrhythmic therapy
If patient maintains sinus rhythm on previously ineffective drug therapy, this may
be considered a clinically relevant, successful outcome
Will increase the success rate compared with off-drug success
May not be relevant to patients hoping to discontinue drug therapy
Postablation drug and dosage of drug should be identical to preablation drug and dosage
Significant reduction in AF burden: >75% reduction from pre- to postablation and/or
total postablation burden <12%
Can be useful in persistent AF studies, but might not be suited for early, paroxysmal
AF studies
Ideally requires continuous monitoring using an implantable device
No scientific basic exists showing that a 75% reduction in AF burden impacts hard
endpoints, including heart failure, stroke, and mortality
AF burden can be estimated by intermittent monitoring and reporting of patient symptoms
and recurrences like a “time in therapeutic range” report for oral anticoagulation;
see text
Could also see 75% reduction in number and duration of AF episodes
Because there is no firm scientific basis for selecting the cutoff of 75%, this prior
recommendation is provided only as an example of what future clinical trials may choose
to use as a definition of clinical/partial success
Prevention in AF progression: time to first episode of persistent AF (>7 days)
Does not assume that total elimination of AF is required
Well suited for paroxysmal or “early” AF studies in which goal is to prevent progression
to persistent AF
Prevention in progression might be irrelevant for stroke or thromboembolic outcomes
Long follow-up time might be required unless population is “enriched”
Can ideally require continuous implantable monitoring
Might be useful for specific populations such as heart failure or hypertrophic cardiomyopathy,
in which progression to persistent AF can lead to increased hospitalization
Regression of AF: reduction in burden to a given threshold or conversion of persistent
to paroxysmal AF
Does not assume that total elimination of AF is required
Well suited for persistent “late” AF studies in which goal is to regress to paroxysmal
AF, which might be easier to control with drug therapy
Regression endpoint will overestimate efficacy of AF ablation
Might ideally require continuous implantable monitoring
Patients will require ongoing drug therapy
Could be particularly useful for long-standing persistent AF populations with structural
heart disease, heart failure, etc.
Acute AF termination during ablation procedure
Could provide indication of successful modification of substrate responsible for maintaining
AF, most relevant to persistent or long-standing persistent AF
Limited studies have linked acute AF termination to long-term success
Relevance of acute AF termination has not consistently been shown to correlate to
long-term success
Endpoint might not be relevant to paroxysmal AF patients in whom AF might terminate
spontaneously
Some studies employ administration of intravenous or oral antiarrhythmics during ablation
that could cause spontaneous termination
Studies consider termination as reversion to sinus rhythm, whereas others consider
reversion to any regular tachycardia as termination
Intraprocedural administration of preprocedural oral antiarrhythmics or intraprocedural
intravenous antiarrhythmics are discouraged
If antiarrhythmics are used, their use and dosage before and during the ablation should
be clearly documented
Termination to sinus rhythm and termination to another regular tachycardia (AT or
AFL) should be separately reported
AF, atrial fibrillation; AFL, atrial flutter; AT, atrial tachycardia.
The consensus statement reaffirms the use of freedom from any atrial arrhythmia (e.g.,
AF, AT, or AFL) greater than 30 seconds off antiarrhythmic therapy as the gold standard
for reporting the efficacy of AF ablation (Table 10
). The writing group also believes that all trials should report single-procedure,
off AAD therapy efficacy for ablation with a minimum of 12 months follow-up. Slight
variations in this endpoint have been used in several clinical trials, but ideally,
all categories of recurrence should be reported transparently, such as freedom from
AF separately from other atrial arrhythmia, one- and multiple-procedure success rates,
and success on and off antiarrhythmic therapy. By reporting all of these variations,
the reader can determine the most relevant outcome for themselves and can also easily
compare results between clinical trials. A recent study that reported outcomes using
a wide variety of endpoints can serve as an excellent example of this approach to
reporting outcomes.
245
The inclusion of all atrial arrhythmias compared with AF in isolation recognizes the
fact that ablation can result in iatrogenic macro- and microreentrant tachycardias
caused by incomplete scar formation from the procedure itself. Furthermore, patients
might present with mixed pictures of both AFL and fibrillation, and elimination of
one but not the other will not improve patient outcomes.
The consensus statement recognizes that the 30-second cutoff for arrhythmia recurrence
is stringent and might not accurately reflect more clinically relevant endpoints,
such as reduction in total AF burden, symptom abatement, and improvement in QOL. A
strict cutoff might also underestimate the true benefit of ablation, especially when
presented in the format of a Kaplan-Meier analysis. Isolated, brief recurrences can
result in a patient being considered a “procedural failure,” although the overall
reduction in AF burden has been substantial. Patients with preablation high-burden
PAF might continue to experience AF episodes, but with a reduced frequency and duration
and a significant improvement in QOL. More liberal cutoff points have been suggested
based on implantable monitoring technology detection limits (>2 minutes) or based
on hypothesized thresholds for stroke risk (>6 minutes or > 5–6 hours). However, selection
of any other cutoff would be as arbitrary as the initial selection of 30 seconds,
which has now been in place since 2007. Keeping the same endpoint threshold will therefore
allow for comparison of future studies against those performed in the past. It also
remains unclear whether the selection of a somewhat more generous threshold would
actually significantly alter reported success rates in a time to event analysis.
Arrhythmia recurrence is often reported as time to first AF episode of a particular
type, such as any episode of an ATA lasting more than 30 seconds, verified by surface
ECG (loop recorder) or an intracardiac electrogram. This parameter might best reflect
differences in lesion quality around PVs for electrical isolation. Ineffective ablation
and early gap formation could result in an earlier time to first recurrent AF. Even
the time to the second or third AF recurrence might further allow insights into such
ablation effects and could therefore be used as a secondary outcome measurement.
Cutoffs of more than 30 seconds can be reported in addition to the 30-second primary
endpoint to show how procedural success might change. In fact, the consensus group
encourages such reporting routinely in all clinical trials to better assess the most
clinically relevant outcomes for future clinical trials. In particular, higher cutoffs
can be used for patients with persistent or long-standing persistent AF because of
the very high burden of preablation AF and the lower likelihood that ablation will
result in a full “cure” of the arrhythmia. It is strongly suggested that other cutoffs
be prespecified and reported in secondary outcomes of trials so the true effects of
catheter ablation on various types of AF can be put into proper context outside of
the 30-second cutoff.
A cutoff that can be used in addition to 30 seconds would be the time to first clinical
or stroke-relevant AF duration (e.g., more than 1 hour or 5.5 hours). As already described,
the SOS trial revealed AF activity of more than 1 hour per day as a cutoff for an
increased risk of stroke, whereas other investigation revealed various AF burden levels,
such as a marker of an increased risk for thromboembolism. This parameter might be
used preferentially in studies in which the potential of ablation to reduce outcomes
such as thromboembolism might be the primary interest. “Time to first persistent AF”
could be considered for trials of persistent AF ablation in which time to the first
episode of more than 7 days might be a relevant parameter while investigating substrate
modifying ablation therapies such as atrial lines or localized rotational activity
elimination.
AF Burden Endpoints
Rather than report time to an AF recurrence of a specific duration, many feel that
AF burden is a more optimal endpoint for assessing ablation efficacy. AF burden can
be estimated based on serial long-term monitoring results and patient symptom reporting,
but only continuous monitoring through a cardiac implantable electronic device (loop,
pacemaker, ICD) can truly define the burden. Furthermore, placement of such an implantable
recording device should ideally be performed preablation so that pre- and postablation
outcomes can be compared. Use of such devices, however, can be quite costly and impose
undue difficulty in performing clinical trials. AF burden can be used in various ways
in AF ablation trials. Freedom from relevant AF—classically defined as an absence
of any ATA of more than 30 seconds—might be defined, for example, as a low daily AF
burden less than 1%–2%. This approach would recognize the fact that occasional and
short-lasting atrial arrhythmias over a few minutes might be an acceptable outcome.
It should be noted, however, that there is a substantial difference between long-term,
daily monitoring of AF burden versus a detection period of 3 months, as in the Asymptomatic
Atrial Fibrillation and Stroke Evaluation in Pacemaker Patients and the Atrial Fibrillation
Reduction Atrial Pacing Trial, in which short-lasting AF was likely a marker for future
long-lasting AF outside the monitoring period.
1390
Reduction in AF burden more than 75% could be considered as clinical success just
as much as reduction in both the number and duration of AF episodes. However, the
number and duration of episodes are significantly more sensitive to under- or oversensing
with subcutaneous devices but also implanted pacemakers or defibrillators for various
technical reasons. In contrast, the number of episodes necessitating urgent or emergency
care visits might not only be clinically relevant, but might also help demonstrate
the cost-effectiveness of the procedure. Furthermore, because there is no firm scientific
basis for selecting the cutoff of 75%, this prior recommendation is provided only
as an example of what future clinical trials might choose to use as a definition of
clinical or partial success.
In recognition that AF ablation may not be curative, particularly for patients with
persistent or long-standing persistent AF, the concepts of AF progression and regression,
while unproven, could be of interest. Many patients might initially present with very
infrequent episodes of PAF that could be quite manageable with minimal drug therapy.
Ablation in this setting might help delay progression to higher burden paroxysmal
or persistent AF, which could be associated with decreased functioning but also increased
risks of stroke, HF, or death. On the other hand, patients with persistent AF who
can be converted into infrequent, paroxysmal forms of AF (so-called AF regression)
might experience not only QOL benefits but also a potential reduction in morbidity
and mortality. In order for these endpoints to be widely implemented, thresholds of
AF must be established under which patient QOL and risk of adverse outcomes are reliably
improved, which has yet to be done. For example, one substudy of the STAR AF 1 trial
showed that patients with very high-burden paroxysmal or persistent AF could continue
to experience up to 2 or more hours of AF per month postablation and still report
an improvement in QOL.
1391
The patient-reported symptoms did not deteriorate until they experienced more than
27 hours of AF per month. This outcome remains an important focus for ongoing clinical
investigation.
When an implanted device is not used, many trials have attempted to estimate changes
in AF burden by using various methods. If careful recording of patient symptoms and
clinically apparent recurrences is performed, including duration and frequency of
episodes over a specific period of time, then these could be used to estimate AF burden
pre- and postablation.
1391
Total AF detected on intermittent continuous monitoring (like intermittent 7 day Holters)
could be used, although the accuracy is somewhat limited depending on the duration
and frequency of monitoring.
378
Intermittent, but frequent, transtelephonic or other portable monitors can provide
brief strips of rhythm status. Time in sinus rhythm could be estimated by the number
of weeks (for example), with sinus transmissions divided by the total number of weeks
of the monitoring period, akin to a time in therapeutic range for OAC with VKA.
245
A combination of symptom reporting and ECG status at various time points can also
be used to calculate estimated time in sinus rhythm, as was employed in a substudy
of the Atrial Fibrillation and Congestive Heart Failure study.
1392
Endpoint Differences for Paroxysmal vs Nonparoxysmal AF Ablation Studies
Important consideration should be given to differences in AF recurrence endpoint reporting
in trials of paroxysmal versus persistent AF. For patients with PAF, the burden might
not be well suited for determining the outcome of ablation. Because the preablation
burden can be relatively low in the months preceding ablation, with a large range
in the burden, it might be hard to realize a statistically significant change postablation
or between treatment arms. This was demonstrated in the MANTRA-PAF trial, in which
total AF burden (measured on 7-day Holters) did not differ between drug and ablation
therapy, but the total number of patients free from any AF recurrence was significantly
higher in the ablation arm.
378
For these patients, a time to recurrence or proportion free from arrhythmia endpoint
might be a better option. Other statistical concerns that need to be considered for
AF burden as an outcome measure for ablation in PAF patients include regression to
the mean and the clustered, nonrandom pattern of PAF episodes. For persistent AF,
reduction in burden can be much more relevant because the preablation burden will
be high (close to 100%), with little standard deviation, making a statistical reduction
postablation easier to define. On the other hand, the use of freedom from 30-second
endpoints could underestimate the true clinical effect of ablation in the persistent
population. The consensus group still maintains that the 30-second endpoint should
be reported, but secondary endpoints such as changes in AF burden and/or AF progression
or regression should also be described. Both CABANA and EAST, with more extensive
monitoring, should both shed additional light on these issues.
The writing group members encourage reporting of other secondary endpoints that might
better represent clinically relevant outcomes of the ablation procedure. Improvements
in patient QOL are very important to assessing the clinical success of AF ablation,
but as with any intervention, the magnitude of the improvements might be confounded
by expectancy bias (“placebo effect”). A detailed discussion of QOL measurements and
potential benefits and limitations appears later in this section.
Symptomatic vs Asymptomatic Recurrence
Even in patients with highly symptomatic AF, as many as half of all episodes can occur
without associated symptoms.
56
The ratio of asymptomatic to symptomatic episodes increases up to 4-fold postablation,
perhaps due to shorter durations, slower rates, or autonomic modulation after the
procedure.
58
In highly symptomatic AF patients, asymptomatic episodes often coexist with the symptomatic;
thus, patient reporting of symptoms can still serve as a rough surrogate for procedural
success. For clinical trial purposes, however, reporting of only symptomatic AF recurrences
could overestimate procedural success by 20% or more by missing asymptomatic recurrences.
The importance of asymptomatic AF detection depends in part on the purpose of the
clinical trial. If patient QOL and symptom abatement is the primary goal of therapy
in the study, then underdetection of asymptomatic AF could be of little relevance.
However, if the study goal is to reduce the associated risks of AF (stroke, HF) and
to change potential therapy, including OAC, then the detection of asymptomatic AF
is much more critical. Typically, the detection of asymptomatic AF recurrence is accomplished
by longer-term, frequent, or implantable monitoring approaches.
AF Monitoring Postablation
Arrhythmia monitoring can be performed with the use of noncontinuous or continuous
ECG monitoring tools. The choice of either method depends on individual need and consequence
of arrhythmia detection. Basically, more intensive monitoring is associated with a
greater likelihood of detecting both symptomatic and asymptomatic AF.
56
,
58
,
937
Identification of patients with AF and assessment of AF burden with intermittent monitoring
have been shown to depend on a patient's actual AF burden, and improve with an increasing
frequency or duration of intermittent monitoring. Conversely, the more complex and
longer the method of monitoring that is used, the lower the patient compliance.
Available noncontinuous detection tools include scheduled or symptom-initiated standard
ECGs, Holter (24 hours to 7 days), transtelephonic recordings, patient- and automatically
activated devices, and external loop recorders (Table 6
). Scheduled 7-day Holter ECG recordings or daily plus symptom-activated event recordings
are estimated to document approximately 70% of AF recurrences, with an estimated negative
predictive value for absence of AF between 25% and 40%.
947
,
1393
Continuous ECG monitoring is permanent monitoring for a long time period (1, 2, or
more years). Continuous ECG monitoring can be facilitated with the use of implantable
devices. Implantable pacemakers or defibrillators with atrial leads allow the burden
of AF to be assessed by tracking the number and duration of mode switch episodes,
particularly when an arrhythmia duration of ≥5 minutes is used as the cutoff value.
1394
More recently, a long-term subcutaneous implantable loop monitor has become available
to facilitate continuous AF monitoring based on R-R interval analysis over a period
of 2 years.
58
,
952
These types of continuous ECG monitoring devices can be used to evaluate the results
of AF ablation. Although implantable subcutaneous monitors hold promise for determination
of AF burden long term, important limitations include less than 100% specificity due
to myopotentials, atrial and ventricular premature beats, as well as limited memory
resulting in electrograms not being retrievable to verify the correct rhythm diagnosis.
Another major limitation for the performance of clinical trials is cost. If the consensus
mandated ILR monitoring for all clinical trials, the cost of performing such trials
would likely become prohibitive. There are also a number of patients who might refuse
long-term devices.
Again, the purpose of the trial should be married to the type of monitoring performed.
If the ultimate goal is to improve patients’ QOL, then excessive monitoring for asymptomatic
AF might not be worth the effort. However, if the goal is to reduce AF burden, or
change prognosis, particularly from a stroke point of view, then continuous monitoring
should be required.
In the past, the consensus statement has provided minimum clinical requirements for
postablation monitoring for clinical trials. Initially, these were quite stringent,
and in the last consensus statement, the requirements were made more flexible. The
current consensus recommends the following minimum monitoring requirements: For PAF,
follow-up screening should include a minimum of three visits (e.g., at 3, 6, and 12 months),
with a 12-lead ECG at each visit, a 24-hour Holter at the end of the follow-up period
(e.g., 12 months), and more limited event recording from the end of the 3-month blanking
period to the end of follow-up (e.g., 12 months), both at regular periods and with
patient activated recordings obtained at the time of symptoms (or equivalent). Follow-up
beyond 1 year is encouraged and might occur every 6 months with Holter and ECG (or
equivalent). For persistent and long-standing persistent AF, follow-up screening should
include a minimum of three visits (e.g., at 3, 6, and 12 months), with a 12-lead ECG
at each visit, a 24-hour Holter every 6 months, and event recording from the end of
the 3-month blanking period to the end of follow-up (e.g., 12 months), as well as
at the time of symptoms (or equivalent). Follow-up beyond 1 year is encouraged and
might occur every 6 months with Holter and ECG (or equivalent) (Table 10
). In making these recommendations, it is important to recognize that the writing
group views these as minimal monitoring recommendations. More intensive follow-up
with more frequent Holters and/or extended ECG monitoring is encouraged. Similarly,
follow-up beyond 1 year is encouraged and might occur every 6 months with Holter and
ECG (or equivalent). It is acknowledged that this recommendation falls short of continuous
monitoring and will largely detect symptomatic recurrences with only a limited ability
to detect asymptomatic recurrences. However, this minimum standard will at least provide
some consistency in trial reporting, and trials are encouraged to exceed this standard
where possible. Details are specified in Table 10
.
QOL Measurement
QOL should remain an important endpoint for AF ablation studies, but not necessarily
the primary endpoint. QOL is limited by treatment expectancy bias. Although sham procedures
have not been performed to assess the true magnitude of this bias, it is unlikely
that such studies will be performed because they would be extremely challenging.
QOL can be measured both using well-established scales like the SF-36 and EQ5D, but
also using more specific scales like the Atrial Fibrillation Effect on QualiTy-of-Life
(AFEQT), University of Toronto Atrial Fibrillation Severity Scale, Mayo AF-Specific
Symptom Inventory, or Symptom Severity Score. The advantages of the generalized scales
is their wide usage in medicine, the ability to compare improvements in QOL with other
medical interventions, and in the case of the EQ5D, converts QOL changes to cost-effectiveness
measures through the use of QALYs; however, these scales can lack sensitivity to changes
with reductions in AF burden. AF-specific scales, on the other hand, might improve
sensitivity and discriminate more effectively between patients with successful and
failed ablation. At present, the true value of AF-specific scales requires validation
through randomized studies using standard of care therapy as a control arm, given
the comorbidity associated with AF can impact the same symptoms that affect the EHRA
score and the Canadian Cardiovascular Society Severity in Atrial Fibrillation scale.
Finally, we still need to know how these changes compare with other medical interventions
and if the changes would result in substantial reductions in health care cost or patient
morbidity.
The consensus group recommends that all clinical trials incorporate some measure of
patient-reported outcomes and preferably measure them using both a general and an
AF-specific measurement scale. A summary of QOL scales is provided in Table 11
.
Other Endpoint Reporting
There are important subgroups of patients and clinical outcomes that need to be studied,
but are unlikely to be addressed by any one study alone. To facilitate pooled data
analysis, the consensus recommends routine reporting of additional subgroup analyses,
particularly around modifiable lifestyle risk factors. BMI and OSA should be reported
in the baseline characteristics and subgroup analysis, comparing high vs average BMI
and those with and without sleep apnea, which should be ideally reported in recognition
that modifiable risk factors are an important contributor to AF progression and ablation
outcome.
The need for a better understanding of the most appropriate postablation anticoagulation
strategy is particularly recognized by the consensus group. Due to the rarity of stroke,
TIA, and peripheral thromboembolism, it is unlikely that sufficiently powered studies
will ever be conducted to conclusively resolve this relevant aspect of clinical practice.
In the absence of a clear strategy, it is possible that postablation patients are
exposed to an excess stroke risk if untreated, or to an excess bleeding risk if treated
with no real need. As a reasonable surrogate to an evidence-based demonstration, the
consensus group recognizes the value of careful reporting of secondary outcomes in
which individual data are made available for (1) baseline risk factors; (2) postablation
anticoagulation strategy (e.g., if continued, and if so, which drug, or discontinued);
and (3) postablation thromboembolic and/or bleeding events. An effort of this type
would not only enhance the quality of the single studies, but it would also allow
for pooled analyses in the future. Examples of specific secondary outcomes that could
be reported are summarized in Tables 10 and 12.
Unanswered Questions in AF Ablation
There is still much to be learned about the mechanisms of AF, techniques of AF ablation,
and long-term outcomes. The following are unanswered questions for future investigation:
AF ablation and modification of stroke risk and need for ongoing OAC: The CHA2DS2-VASc
score was developed for patients with clinical AF. If a patient has received a successful
ablation such that he/she no longer has clinical AF (subclinical, or no AF), then
what is the need for ongoing OAC? Are there any patients in whom successful ablation
could lead to discontinuation of OAC?
Substrate modification in catheter-based management of AF—particularly for persistent
AF: What is the proper lesion set required beyond PVI? Do lines and CFAE have any
remaining role? Are these approaches ill-advised or simply discouraged?
What is the role of targeting localized rotational activations? How do we ablate a
localized rotational activation? How can scar be characterized and targeted for ablation?
Do we need to replicate the MAZE procedure? Does the RA need to be targeted as well
as the LA?
(3) Autonomic influence in AF: Is clinical AF really an autonomic mediated arrhythmia?
Is elimination of GP required? Is there a role for autonomic modulation, for example,
spinal cord or vagal stimulation?
(4) Contribution and modulation of risk factors on outcomes of AF ablation: Obesity
reduction has been shown to reduce AF burden and recurrence in patients undergoing
ablation. What is the role of bariatric surgery?
Does the modulation of other risk factors influence outcome such as hypertension,
sleep apnea, and diabetes?
(5) Outcomes in ablation of high-risk populations: Do high-risk populations benefit
from AF ablation?
Congestive HF has been assessed in smaller trials, but larger trials are required.
Outcome data are needed in patients with very enlarged LAs, HCM, patients with renal
failure on dialysis, and the very elderly.
(6) Surgical vs catheter-based vs hybrid ablation: There should be more comparative
work between percutaneous and minimally invasive surgical approaches. Both report
similar outcomes, but there is a dearth of comparative data. Is there any patient
benefit to hybrid procedures?
(7) How do we characterize patients who are optimal candidates for ablation? Preablation
LGE-MRI might identify patients with heavy burdens of scar who are unlikely to respond
to ablation. These techniques must become reproducible and reliable and must be assessed
in multicenter trials. Other markers need to be investigated, including genetic markers,
biochemical markers, and clinical markers based on aggregated risk scores.
(8) The incremental role of new technologies: As newer and often more expensive technologies
are produced for AF ablation, their definitive incremental value must be determined
in order to justify change in practice or case cost. These technologies include global
(basket) mapping techniques, newer ablation indices for assessing lesion durability,
advanced imaging for viewing lesions in the myocardium, etc. New energy sources, including
laser, low-intensity ultrasound, photonic particle therapy, external beam ablation,
and MRI-guided ablation, must be assessed in comparative fashion.
(9) Outcomes of AF ablation: We need to better understand the clinical relevance of
ablation outcomes. What is the significance of time to recurrence of 30 seconds of
arrhythmia? How do we best quantify AF burden?
How do these outcomes relate to QOL and stroke risk?
(10) What is the role of surgical LA reduction? Does LAA occlusion or obliteration
improve outcome of persistent AF ablation with an accompanying reduction in stroke?
Does ablation work through atrial size reduction? What is the incidence of “stiff
atrial” syndrome and does this mitigate the clinical impact of ablation?
(11) Working in teams: What is the role of the entire heart team in AF ablation? Does
a team approach achieve better outcomes than a “silo” approach?
(12) Improving the safety of catheter ablation: As ablation extends to more operators
and less experienced operators, the statistical occurrence of complications will increase.
We need newer techniques to minimize complications and institute standards for operators
to improve the reproducibility of ablation results and safety profiles at a variety
of centers worldwide.
(13) How does catheter ablation affect mortality, stroke, and hospitalization in broad
and selected patient populations receiving catheter ablation for AF?
(14) Management of patients who fail initial attempts at catheter ablation: Should
there be specific criteria for repeat ablations (e.g., atrial size, BMI)? Should patients
be referred for surgery for repeat ablation?
In order to address these and other important questions in the field of catheter and
surgical AF ablation, we urge investigators to create and participate in multisite
collaborations and electrophysiology research networks with involvement of senior
and junior investigators on the steering committees to push forward the next phase
of AF research. We also urge funding bodies to support these important initiatives.
Section 14: Conclusion
Catheter ablation of AF is a very commonly performed procedure in hospitals throughout
the world. Surgical ablation of AF, although less widely available than catheter-based
AF ablation, is also an important therapeutic option for patients with AF at many
major medical centers. This document provides an up-to-date review of the indications,
techniques, and outcomes of catheter and surgical ablation of AF. Areas for which
a consensus can be reached concerning AF ablation are identified, and a series of
consensus definitions have been developed for use in future clinical trials of AF
ablation. Also included within this document are recommendations concerning indications
for AF ablation, technical performance of this procedure, and training. It is our
hope to improve patient care by providing a foundation for those involved with care
of patients with AF as well as those who perform AF ablation. It is recognized that
this field continues to evolve rapidly and that this document will need to be updated.
Successful AF ablation programs optimally should consist of a cooperative team of
cardiologists, electrophysiologists, and surgeons to ensure appropriate indications,
procedure selection, and follow-up.
Related collections
Most cited references1,199
- Record: found
- Abstract: found
- Article: not found
A comparison of rate control and rhythm control in patients with atrial fibrillation.
- Record: found
- Abstract: found
- Article: not found
Independent risk factors for atrial fibrillation in a population-based cohort. The Framingham Heart Study.
E Benjamin, D. Levy, S Vaziri … (1994)
- Record: found
- Abstract: found
- Article: not found
Rivaroxaban in patients with a recent acute coronary syndrome.
Jessica Mega, Eugene Braunwald, Stephen Wiviott … (2012)