Introduction
In recent years, there has been a clear trend towards increased mitral bioprosthetic
valve surgery in comparison to mechanical prostheses [1]. According to the ESC Guidelines
mitral bioprostheses are recommended for patients > 70 years old or those with a life
expectancy lower than the presumed durability of the bioprosthesis (class IIa/C).
Importantly, the guidelines also recognize the prominence of quality of life after
cardiosurgery and focus on patients’ preferences (class Ic), especially if long-term
anticoagulation is nonoptimal (class Ic) [2]. Structural deterioration of mitral bioprostheses
(structural valve deterioration – SVD) is the main limitation for their use. The average
lifespan of a bioprosthetic valve is estimated at 16 years and the reoperation due
to SVD affects as many as 75% of patients after a 20-year follow-up [3, 4]. Reoperation
is usually associated with high risk of complications and mortality [5, 6].
The alternative option is transcatheter mitral valve implantation (TMVI), especially
in patients with high surgical risk. TMVI is indicated in patients with a degenerated
mitral bioprosthesis or mitral regurgitation after mitral annuloplasty rings. The
results of TMVI have been reported in registries and single-center or case reports
[7–10]. Technically, TMVI is feasible via a transapical approach or through venous
access and atrial septum puncture. The transapical approach has been dominant in TMVI
as it was well tried in transcatheter aortic valve implantation (TAVI) procedures.
The transseptal approach is technically more demanding yet due to lesser invasiveness
it may lead to superior early and late treatment effects [8]. The latest American
registry STS/ACC/TVT reports similar prevalence of TMVI procedures with both approaches
[7].
Material and methods
We performed 5 TMVI procedures in our center in January to September 2020. All patients
were qualified for the procedure during Heart Team assembly. All but 1 patient were
at a high cardiovascular risk. Baseline characteristics of patients are presented
in Table I.
Table I
Basic characteristics
Patient (age, sex)
Time from first mitral surgery [years]
NYHA
GFR < 50 ml
CABG
PCI
PSAP > 50 mm Hg
AF
EF LK (%)
EuroSCORE II
69/F
7
III
(+)
(+)
(–)
(–)
(–)
60
8.62
80/F
12
II
(–)
(+)
(+)
(–)
(–)
65
12.1
69/F
9
III
(–)
(–)
(–)
(–)
(+)
50
8.47
72/M
9
II
(–)
(+)
(+)
(–)
(–)
25
10.15
77/F
4
II
(–)
(–)
(–)
(+)
(+)
70
3.36
Procedures were performed in the hybrid operating room with cooperation of specialists
from the Department of Cardiosurgery and Invasive Cardiology at the University Hospital
in Bialystok.
All procedures were performed under general anesthesia with fluoroscopic and transesophageal
echocardiographic (TEE) guidance. The right radial artery was cannulated for systemic
pressure monitoring. The right jugular vein served for temporary pacemaker insertion.
The first patient had additional left femoral artery cannulation with a pigtail catheter
introduced to the left ventricle for mitral imaging during ventriculography and pressure
gradient measurement. Due to the equivocal usefulness of such a maneuver (pressure
gradient in the left ventricular outflow tract (LVOT) in TEE proved satisfactory),
we dropped it in subsequent patients. The 6 Fr sheath in the right femoral vein was
exchanged for a 8.5 Fr sheath for transseptal puncture (Swartz Braided Transseptal
Guiding Introducer, Abbott). Transseptal puncture was performed with a transseptal
needle (BRK-1 XS Transseptal Needle, Abbott) under TEE guidance. Half of the heparin
dose was administered before the transseptal puncture; the full dose of 100 IU/kg
was completed after the left atrium was reached with the target ACT 300–350 s during
the procedure. The first patient had a transseptal puncture in the upper-posterior
location. This location did not seem to be favorable in the next 2 patients and the
postero-inferior location appeared to facilitate navigation in the left atrium in
the fourth and fifth patient. With detailed analysis of initial computed tomography
(CT) and TEE images prior the procedure, the choice of optimal location of the puncture
was much easier. Afterwards the diagnostic catheter 6 FR JR or IM was introduced via
the sheath for transseptal puncture (mother and child technique), which allowed direction
at the mitral valve and exchanging the standard guidewire for a stiffer one. Crossing
the mitral valve was performed with a hydrophilic guidewire 0.035’’ (Terumo) which
was exchanged for an Amplatz Super Stiff (Boston Scientific, Marlborough, MA). The
interatrial septum was dilated with a 12–18 mm peripheral balloon of 4 cm length;
14 mm balloon diameter seemed to be optimal. At that time, the sheath for transseptal
puncture was exchanged for the sheath to advance the valve. It is worth emphasizing
that the valve needed to be mounted similarly as in the transapical TAVI (reversely
to transfemoral TAVI). In all cases a Sapien 3 valve was implanted. The alignment
of the valve on the balloon was performed in the vein with the tip of the delivery
system at the level of the right atrium. Having positioned the THV in the mitral valve
area, adequate THV location was confirmed with fluoroscopic and TEE guidance. The
C-arm rotation of 30 degrees (RAO) enabled long-axis mitral valve visualization. Of
key importance in THV positioning was to avoid projection of the mitral bioprosthesis
at the ventricular site (which could cause LVOT obstruction) and coaxial implantation.
The first task was almost effortless to achieve in fluoroscopy with a stented bioprosthesis.
It was far more complicated with a prosthesis which could not be visualized in X-ray
(3 patients). In those cases the absence of any angiographic markers was substituted
with TEE guidance to achieve appropriate THV positioning. TEE was performed with the
Philips Epiq 7 CVx 3D with TEE probe X8-2t with 3D. XPlane Live mode was used for
both transseptal puncture and valve positioning (real-time imaging of two perpendicular
2D images). The THV was deployed with one prolonged balloon inflation under ventricular
pacing at 140–160 bpm. No additional balloon inflation was needed in any patient.
Anchoring, expansion and round diameter of the THV were evaluated in TEE, with the
focus on the LVOT gradient, paravalvular leak and mitral regurgitation. In 1 case,
the LVOT gradient was 23 mm Hg, yet no leakage or mitral valve gradient was found.
The temporary endocavitary pacemaker was removed after the procedure. Venous hemostasis
was achieved with the “figure-of-eight suture”.
Results
Post-procedural heparin infusion was administered in all patients until therapeutic
INR was achieved. Patients were extubated immediately after regaining consciousness,
usually after 6 h. No complications were observed during hospitalization. Patients
were discharged home 5 days after the procedure with a scheduled follow-up visit after
1 month, 3 months and 1 year. Due to epidemiological circumstances complete 1- and
3-month follow-up was impossible (echocardiographic assessment), yet the clinical
condition was established via teleconsultation.
Data concerning the procedure, hospitalization, and initial 30-day follow-up are presented
in Table II.
Table II
Procedural details and early results
Parameter
Result
Complete technical procedural success (according to MVARC)
5 (100%)
Periprocedural death (within 24 h)
0
Procedural duration (skin to skin) [min]
246 (200–300)
Fluoroscopy time [min]
89.9 (56.4–134.8)
Contrast vol. [ml]
70 (0–134)
Valve size:
26 mm
3
29 mm
2
Complications:
Vascular access site bleeding complication
0
Device embolization
0
Need for second valve implantation
0
Cardiac perforation/cardiac tamponade
0
Major stroke
0
New arrhythmia
0
Conversion to open heart surgery
0
Acute kidney injury
0
Significant LVOT obstruction
0
Residual mitral regurgitation after TMVI at hospital discharge:
None
3
Trace or mild (MR grade I)
2
Moderate or severe (MR grade > 2)
0
In-hospital mortality rate
0
In-hospital stay from TMVI to hospital discharge (mean ± SD) [days]
5 (5–7)
Clinical follow-up after hospital discharge 30-day:
Mortality rate (all-cause)
0
NYHA functional class at 30 days:
I
3
II
2
III/IV
0
Discussion
Efficacious anchoring of the valve in the mitral annulus is of key importance during
the TMVI procedure. Fundamental difficulty stems from the high pressure gradient between
the left ventricle and left atrium. An indispensable condition is the absence of perivalvular
leak of the mitral bioprosthesis or tearing of the mitral annulus after annuloplasty.
Properly sutured surgical prostheses and mitral annuli usually constitute sufficient
support for THV implantation.
A degenerated mitral bioprosthesis (valve-in-valve – ViV) is the optimal target for
the transcatheter procedure. The dimensions of the bioprosthesis are known in advance
from the producer’s information, most of them are clearly visible in X-ray imaging
or echo, and the stiff structure allows safe and solid deployment. Moreover, the bioprosthesis
contributes to coaxial positioning of the valve. ViV procedures are generally successful
and are characterized by favorable early and long-term outcome [11–13].
The alternative, less comfortable indication is valve-in-ring implantation (ViR).
Periprocedural complications include difficult sizing, positioning or deployment,
which are more often connected with paravalvular leak, inappropriate sealing, the
necessity of second valve implantation or obstruction of the LVOT. The contact area
between the deployed THV and the annulus is smaller than in the degenerated prosthesis,
which influences the stability of the device. The procedure has a two times greater
early and 1-year mortality than VIV [9].
The transapical approach is convenient for several types of valves (Sapien, Lotus,
Direct flow, Melody) [9]. This approach favors stable procedure controlling and precise,
coaxial orientation and, if needed, repositioning of the device. By contrast, the
transseptal procedure can be done only with one valve type from the Edwards SAPIEN
family. This comes from the unique structure of the prosthesis and primarily the guiding
system, which allows maneuvering in the left atrium.
The choice of appropriate size of the THV is primarily based on the nominal THV values
provided by the manufacturer of the mitral bioprosthesis. Available apps that provide
complete data of the structure and sizing of bioprostheses and mitral rings are also
very helpful [14].
Procedural success applies to almost 90% of cases, and is lower in ViR. Complications
are typical for transcatheter procedures, including most often vascular complications,
followed by atrial or ventricular perforation and cardiac tamponade, acute kidney
injury, the necessity of conversion to open heart surgery, embolization or implantation
of a second THV. In 80% of patients, mitral insufficiency is absent or mild. A unique
complication is LVOT obstruction. It affects 2–13% of cases, and prevails in ViR [7,
9, 11]. It is defined as the increase of LVOT gradient > 30 mm Hg at rest in echocardiographic
imaging. A significant gradient is generally considered to be an LVOT gradient > 50
mm Hg. Small size of the left ventricle, small LVOT diameter, thick intraventricular
septum, acute aortomitral angle, and the size and manner of THV implantation are predisposing
factors. The risk of thrombosis in the THV remains unclear. Hypothetically, enlarged
left atrium, atrial fibrillation, and the combination of a surgical device of foreign
origin and the THV may predispose to thrombosis, yet anticoagulation is routinely
indicated in such cases.
Conflict of interest
The authors declare no conflict of interest.