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      Coronary Artery Chronic Total Occlusion

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            Abstract

            Coronary artery chronic total occlusion (CTO) is defined as an occluded coronary artery segment without anterograde flow for at least three months. It can be classified as a “true” or “functional” CTO based on flow characteristics. In “true” CTO, there is no anterograde flow. In “functional” CTO, there is minimal anterograde flow through the occluded segment of the coronary artery. CTO is a common finding during coronary angiography and its prevalence may vary depending on the reported literature. Among patients without previous coronary artery bypass grafting (CABG), CTO is found in about 20–30% of the patients. CTO may develop insidiously over a period of time and involve a complex interplay between intracellular and extracellular factors, smooth muscle and foam cells, calcification, and neovascularization. There is a growing body of evidence to support that CTO revascularization may improve clinical outcome when compared to medical management. Both the European and American cardiovascular societies support CTO revascularization with a class 2a recommendation (level of evidence B). Historically, due to low procedural success rate, apparent inefficient resource utilization, potential increase in complication rates and uncertain clinical benefits, only about 10–20% of patients with CTO are treated with percutaneous coronary intervention (PCI). Recent advances using novel and innovative techniques with dedicated equipment have significantly improved the procedural success rate for CTO PCI to about 90% in the hands of experienced operators. With increasing interest in CTO PCI coupled with increased educational effort, CTO PCI likely will become more accessible to patients in need of CTO revascularization. Ongoing advancement in innovative techniques and equipment will continue to improve procedural success rates and reduce procedural complication rate for CTO PCI. Furthermore, there are a number of prospective clinical trials on the horizon which should help define the clinical benefits and limitations of CTO PCI in the near future.

            Main article text

            Abbreviations

            CABG

            coronary artery bypass grafting

            CAD

            coronary artery disease

            CTO

            coronary artery chronic total occlusions

            LAD

            left anterior descending artery

            LM

            left main coronary artery

            LVEF

            left ventricular ejection fraction

            MI

            myocardial infarction

            PCI

            percutaneous coronary intervention

            RCA

            right coronary artery

            TIMI

            Thrombolysis in Myocardial Infarction

            Introduction

            Coronary artery chronic total occlusions (CTO) are defined as occluded coronary artery segments with thrombolysis in myocardial infarction (TIMI) 0 flow for at least three months [1, 2]. Stone et al. in a consensus document published in 2005 proposed that CTO be classified into “true” or “functional” based on the degree of lumen narrowing and anterograde blood flow [3]. A “true” CTO is defined as complete interruption of coronary flow (TIMI 0 flow), whereas occlusions with minimal contrast penetration through the lesion without distal-vessel opacification (TIMI 1 flow) are classed as a “functional” CTO. However, in the literature, the distinction between “true” and “functional” CTO is rarely declared. Moreover, the period of time for which a CTO has been present is often difficult to ascertain. Therefore, the age of the occlusion is often determined based on careful assessment of a patient’s medical history and cardiac symptoms in the previous 3 months [3].

            Pathophysiology

            Percutaneous revascularization of CTO is often complicated by the inability to cross or dilate the lesion. An understanding of the histopathology of these lesions helps provide insight into the development of new revascularization strategies.

            CTO most often arise from thrombotic occlusion of vessels and subsequent thrombus organization and tissue remodeling [4]. This may occur after failed revascularization or subsequent re-occlusion of the vessel in patients who have had a myocardial infarction [5, 6]. However, a majority of patients with CTO (60%) do not have a history of myocardial infarction (MI) and an alternative mechanism must be involved [7]. For example, there could be recruitment of collateral vessels to counterbalance ischemia due to an obstructed vessel, which might gradually progress to complete occlusion. Insufficient blood flow via collateral circulation results in ischemia and angina. However, due to the insidious nature of the disease progress, symptoms may be mild and/or atypical in some patients [8].

            Pathological Considerations

            The typical atherosclerotic plaque of CTO consists of intracellular and extracellular lipids, smooth muscle cells, extracellular matrix, and calcium [9]. Extracellular matrix is rich in collagens [10, 11] with predominance of types I and III (and minor amounts of IV, V, and VI) [12]. The concentration of collagen-rich fibrous tissue is particularly dense at the proximal and distal ends of the lesion, contributing to a column-like lesion with calcified, resistant fibrous tissue surrounding a softer core of organized thrombus and lipids.

            Srivatsa and colleagues demonstrated through an autopsy study that angiographic CTO frequently corresponded to less than 99% stenosis by histology criteria [13]. They demonstrated that key histopathological attributes of CTO are calcification, inflammation, and neovascularization. Thrombotic occlusion progresses over time from a “soft” to a “‘hard” lesion composition. Soft plaque consists of cholesterol-laden cells and foam cells with loose fibrous tissue and neovascular channels which is more common in “new” occlusions (less than 1 year old). “Soft” plaque is more likely to allow wire passage either directly through tissue planes or via neovascular channels into the distal lumen. Conversely, “hard” plaques are characterized by dense fibrous tissue and often contain large fibrocalcific regions without neovascular channels. These occlusions are thus more likely to deflect guidewires into the subintimal space, resulting in dissection planes. “Hard” plaques are more prevalent with “old” CTO (greater than 1 year old). Of note, however, areas of calcification frequently occur even in CTO less than three months of age, although the extent and severity of calcification tend to increase with occlusion duration.

            Another hallmark of CTO is extensive neovascularization, which occurs throughout the extent of the vessel wall and increases with the age of occlusion. In CTO less than 1 year old, new capillary formation is greatest in the adventitia. In CTO greater than 1 year old, the number and size of capillaries in the intima have increased to a similar or greater extent than those present in the adventitia. Lymphocytes and monocytes/macrophages may play an active role in both angiogenesis and atherosclerotic lesion progression by producing a variety of mitogenic and angiogenic factors [14]. A rich neovasculature network often traverses the CTO vessel wall, arising from the adventitial vasa vasorum across the media and into the intima which suggests that the adventitial vessels initiate the formation of intimal neovascular channels [15]. The channels in this neovasculature often are perpendicular to the long axis of the artery and may be a contributing factor in guidewire diversion into the extravascular space. Post-mortem studies support this mechanism. The channels in the neovasculature mostly lead into the adventitia, small side branches, or vasa vasorum. However, they may also extend longitudinally from the proximal to the distal lumen. Such channels may serve as a route for guidewires and hence may have a therapeutic value.

            Epidemiology

            The reported prevalence of CTO among patients undergoing a cardiac catheterization varies widely as illustrated in Table 1 [7, 1619]. In the largest study reported to date (prospective three center Canadian registry) [7], the prevalence of CTO was 18% among patients with coronary artery disease (CAD, defined as greater than 50% stenosis in at least one vessel) without prior coronary artery bypass grafting (CABG) and 54% among patients with prior CABG. Using the same definition of CAD, Kahn [16] identified a CTO in 35% of 287 patients with CAD at a single institution in one year. In a German multicenter prospective registry spanning 64 hospitals, Werner et al. [18] reported a CTO prevalence of 33% in 2002 patients presenting with stable angina and first angiographic diagnosis of CAD. In a study investigating the frequency of CTO in a veteran population, Christofferson et al. [17] reported a CTO prevalence of 52% in patients with CAD (defined as greater than 70% stenosis in at least one vessel) and an overall prevalence of 24.5% in 8004 non-CABG patients undergoing diagnostic angiography over a ten year period. In another study in a veteran population by Jeroudi et al. [20], the prevalence of CTO was 31% among non-CABG patients presenting with CAD, and 89% in patients with prior CABG.

            Table 1

            Prevalence of CTO.

            Country/yearCTO prevalence among patients without prior CABGCTO prevalence among patients with prior CABGMedical therapy onlyAttempted PCICABGLADRCALCXMultivessel CTO
            Kahn [16]USA [1991]101/287 [35%]NRNR51/112 [46%]NR18%58%24%NR
            Christofferson et al. [17]USA [1990–2000]1612/3087 [52%]NR49%177/1612 [11%]40%28%35%64%NR
            Werner et al. [18, 19]Germany [2001–2003]661/2002 [33%]NR34%210/661 [31.8%]33.9%30.1%64.1%26.6%NR
            Fefer et al. [7]Canada [2008–2009]1697/9377 [18.1%]54%64%162/1697 [10%]26%20%47%16%17%
            Jeroudi et al. [20]USA [2011–2012]319/1015 [31%]89%61.6%94/319 [30%]15.8%20%59%21%23.5%

            NR – Not reported.

            It has also been reported that patients with a CTO have more cardiac risk factors than those with CAD without CTO on coronary angiography, including a higher prevalence of diabetes mellitus (34% vs. 26%), hypertension (75% vs. 68%), hyperlipidemia (82% vs. 78%), heart failure (12% vs. 9%), and peripheral artery disease (8% vs. 4%) [7]. Furthermore, patients with CTO are more likely to have a previous history of myocardial infarction and undergo CABG than non-CTO patients [7, 1618, 20]. Moreover, patients with CTO are an undertreated cohort with reports indicating that in general only about 10–20% of patients with CTO are treated with PCI [21].

            Treatment Goals

            Successful CTO revascularization is associated with improved clinical outcomes, and several retrospective studies have shown various beneficial effects (Table 2). Angina relief, improvement in exercise tolerance, reduction in ventricular arrhythmia burden, improvement in left ventricular function; reduced need for CABG surgery, enhanced tolerance for future coronary events, reduced future coronary events and survival benefit have all been associated with successful CTO revascularization procedures [2226, 31].

            Table 2

            Benefits of CTO PCI.

            StudyOutcome after a successful CTO PCI
            Chung et al. [22]Improvement in LVEF and regional wall motion after CTO PCI in patients without prior MI
            Nakamura et al. [23]Improvement in LVEF in CTO patients revascularized with drug eluting stent implantation
            Baks et al. [24]Improvement of left ventricular volumes and LVEF after CTO PCI as assessed by magnetic resonance imaging
            Cheng et al. [25]Successful CTO PCI increases hyperemic myocardial blood flow with a greater and earlier improvement in regional contractility than non-CTO PCI
            Cetin et al. [26]Successful CTO PCI reduces the arrhythmic burden
            Grantham et al. [27]Successful CTO recanalization was associated with angina relief, improved physical function, and enhanced quality of life only in symptomatic patients at baseline
            Safley et al. [28]Baseline ischemic burden of 12.5% as an optimal cut-off to identify patients most likely to have a significant decrease in ischemic burden post-CTO PCI
            Gerber et al. [29]Greater 3-year survival among patients who underwent CTO revascularization (by either PCI or CABG) when compared with medically treated patients when viability was demonstrated
            Kirschbaum et al. [30]Early and late improvements in regional function after revascularization in the CTO distribution were associated with the extent of infarction on baseline cardiac magnetic resonance imaging
            Lee et al. [31]A successful CTO PCI did not yield a mortality benefit but it reduced the need for future CABG

            To date, there is a paucity of prospective, randomized clinical trial data to support the potential benefits of CTO revascularization. The reported benefits of CTO percutaneous coronary intervention (PCI) are mostly derived from registry data where a comparison is made between successful and failed PCI [21].

            Due to accumulating interest in CTO PCI, a record number of studies are being pursued to shed a light on the precise benefits and limitations of CTO PCI. Recently, Henrique et al. presented randomized prospective clinical trial data on non-culprit vessel CTO PCI in STEMI patients at the Transcatheter Cardiovascular Therapeutics (TCT) 2015 meeting. This study revealed that routine CTO PCI did not improve left ventricular ejection fraction (LVEF) when compared to the control group. A subgroup analysis, however, revealed that for the left anterior descending artery CTO cohort, PCI resulted in improved LVEF [32].

            Evidence from additional prospective, randomized trials is needed to confirm the clinical benefits and limitations of CTO revascularization.

            Treatment Indications and Decision Making

            The European and North American guidelines have adopted CTO revascularization with a class 2a recommendation (level of evidence B) [33, 34]. Symptom relief is considered the main indication for the procedure. However, a number of other potential benefits of CTO revascularization have been identified and are reasonable indications for CTO revascularization [35].

            Historically low procedural success rates, technical challenges associated with CTO PCI, lack of operator experience, apparent inefficient resource utilization, potential increase in complication rates, uncertain clinical benefits, and the presence of well-developed collaterals have dissuaded interventional cardiologists from pursuing CTO PCI. Although the presence of collateral circulation has been associated with improved survival [36], the collateral flow may be insufficient to preserve ventricular function and meet the metabolic demand in CTO patients which results in ventricular dysfunction, ischemia and angina [19]. With advances in novel and innovative techniques and equipment, the procedural success rate for CTO PCI is reaching 90% and overall complication rates have decreased in the hands of experienced CTO operators [21, 37].

            The decision to pursue CTO PCI depends on several factors. First, patient selection is critical. Ischemic burden, myocardial viability, severity of symptoms, and patient preferences need to be taken into consideration. Second, suitable anatomy should be identified. Based on lesion and target vessel characteristics – presence of calcification, stents, tortuosity, bifurcation, branch vessels, size, collateral vessels, location and shape of proximal and distal cap, length of the occlusion – the odds of successful revascularization may be estimated. For example, the J-CTO score which is based on lesion characteristics including the shape of proximal cap, calcification, angulation and length, and repeat attempt can help predict the procedural success rate [38]. Third, operator experience is crucial. CTO PCI requires in-depth knowledge, a unique skill set and experience; (e.g., collateral wiring, dissection and re-entry technique, wire externalization, contemporary algorithm) and complication management. In addition, patients need to be informed of the idiosyncrasies associated with CTO PCI. In general, procedures tend to be longer and radiation and contrast exposure tend to be higher when compared to non-CTO PCI, and multiple staged attempts may be required. For an appropriate candidate with suitable anatomy, CTO PCI should be discussed as a treatment option.

            Treatment Options

            Based on the severity of symptoms, concomitant CAD, ischemic burden, and patient risk profile and preferences, treatment options may be tailored to each patient. However, irrespective of the presence of CTO, patients with CAD should be counseled about risk profile modification and receive aggressive medical therapy for CAD. Medical management is a reasonable option for patients with no symptoms or mild symptoms. For patients with large ischemic burden or refractory symptoms despite optimal medical therapy, revascularization should be considered. CABG should be considered for patients with concomitant multi-vessel or left main CAD or in need of cardiac surgery for other reasons; valve surgery, etc. CTO PCI may be considered in patients with isolated CTO or those who are poor candidates for CABG. A number of publications dedicated to CTO PCI technique and strategy have significantly simplified and standardized the procedures for CTO operators [3943]. Since procedural success in CTO PCI is highly dependent on operator experience, a referral to a CTO PCI center should be considered when local treatment options do not favor CTO PCI.

            Salient Features of CTO PCI

            Several salient features unique to CTO PCI are worth highlighting. In general, CTO PCI is a time consuming, labor intensive, and a resource heavy endeavor. As such, patient comfort must be taken into consideration. Conscious sedation with anesthesiology support or even general anesthesia may be required to allow patient comfort during a long procedure. Furthermore, for patients with heart failure, volume status should be carefully monitored during the procedure to avoid heart failure exacerbation due to a large volume of contrast used during the procedure; (e.g., left ventricular end diastolic pressure measurement at the beginning of the procedure may be beneficial). Operator fatigue needs to be considered as well. The duration of the procedure needs to be monitored such that beyond a set time, unless the procedure is near completion, the procedure should be terminated and reattempted at another time. A number of CTO PCI centers practice a team approach to avoid operator fatigue; i.e., two operators working as a team. Additionally, repeat attempts may be required for CTO PCI. Due to the radiation dose, the contrast volume and the duration of the procedure, a procedure may not be completed on the initial attempt. However, with the initial attempt a lot can be gained. For example, CTO lesion characteristics can be better appreciated and understood such that device and equipment selection may be streamlined during future attempts. Plaque modification during the initial attempt may increase the likelihood of success with a subsequent CTO PCI.

            For practitioners interested in developing a CTO PCI program, a discussion regarding resource utilization is imperative. Based on 2015 Medicare physician reimbursement rate, a single vessel CTO PCI is reimbursed at the same rate as a single vessel non-CTO PCI for acute myocardial infarction [44]. A CTO PCI is an elective procedure whereas a non-CTO PCI for acute myocardial infarction is an emergent or urgent procedure. As such, overall resource utilization may be higher for a non-CTO PCI for acute myocardial infarction due to the additional cost associated with hospitalization. However, for the index procedure, resource utilization may be higher for CTO PCI. According to Grantham et al., for CTO PCI, both the duration of the procedure and fluoroscopy are about twice as long when compared to non-CTO PCI, and balloon and stent utilization for CTO PCI is significantly higher than non-CTO PCI [45].

            Traditionally, concerns over potential CTO PCI associated complication risks have deterred cardiologists from pursuing CTO PCI as a treatment option for patients with CTO. Due to recent advances in technique and dedicated CTO PCI equipment, a number of CTO PCI associated complication risks may be comparable to non-CTO PCI. In-hospital death (1.3% vs. 0.8%), Q-wave MI (0.5% vs. 0.6%), and urgent CABG (0.7% vs. 1.1%) have been reported as similar between CTO PCI and non-CTO PCI [45].

            However, other risks have been reported to be higher in CTO PCI compared to non-CTO PCI. Because of greater contrast volume used during CTO PCI, the risk for contrast-induced nephropathy (CIN) is higher with CTO PCI than non-CTO PCI. This is influenced by pre-existing chronic kidney disease and the contrast volume used during the procedure. Renal protective strategies such as pre-hydration and contrast volume minimization during the procedure may mitigate the risk for CIN [45]. Particularly for patients with pre-existing chronic kidney disease, a discussion regarding the risk for CIN is essential. Radiation injury is another dose-dependent risk associated with CTO PCI. Fluoroscopy time and dose are directly proportional to the radiation injury. As in any PCI, a radiation dose minimization strategy should be utilized. For example, collimation use, image intensifier angle changes to avoid prolonged direct exposure to the same area and lower frame rate for fluoroscopy (7.5 frames per second rather than 15 frames per second) during the procedure can mitigate radiation injury to the patient. For the operator, lead shielding, keeping a minimal distance between the patient and the image intensifier, and maintaining a maximal distance from the radiation source can minimize the radiation exposure [45]. For radiation dose greater than 5 Gy, a follow up evaluation is required to check for radiation dermatitis [45]. Coronary artery dissection and perforation are also reported to be more common in CTO PCI than in non-CTO PCI. Coronary artery dissection is significantly higher in CTO PCI than in non-CTO PCI (17.8% vs. 13.3%) [45]. Interestingly, the contemporary CTO PCI algorithm includes intentional dissection and re-entry technique. Coronary artery perforation is significantly higher in CTO PCI than in non-CTO PCI (0.9% vs. 0.2%) [45]. A strategy to minimize the risk for coronary artery perforation should be practiced. For example, appropriate wire selection, use of reversible pharmacotherapy, and prompt recognition and treatment when perforation is identified are key features [45]. Of note, the incidence of CTO PCI associated risks are somewhat variable depending on the data type (observational vs. prospective), operator experience (expert vs. all-comer) and data time frame (contemporary vs. historical). For example, “Outcomes, patient health status and efficiency in CTO hybrid procedures (OPEN CTO)” [ClinicalTrials.gov Identifier: NCT02026466] is an on-going prospective study, and preliminary results presented at TCT 2015 meeting indicate that clinically significant perforation and in-hospital myocardial infarction and death for CTO PCI are 4.9%, 2.4% and 0.9%, respectively. A number of on-going prospective studies will provide a greater insight into the incidence of risks associated with CTO PCI.

            CTO PCI Technique

            A detailed discussion regarding procedural techniques and strategies is beyond the scope of this manuscript. A review of general concepts is presented below. It is crucial to clearly define a CTO segment for a successful PCI. In order to clearly define CTO segment, a bilateral simultaneous coronary angiogram is required. That is, two guides are simultaneously engaged in the right coronary (RCA) and left main coronary arteries (LM), and contrast is injected into both guides (Figure 1). This technique allows clear visualization of the CTO segment and its collaterals, and this is often ambiguous on a single vessel contrast injection. Bilateral contrast injection also allows the operator to set up the coronary guides such that both anterograde and retrograde CTO PCI techniques can be utilized.

            Figure 1

            Bilateral Contrast Injection Shows Left Anterior Descending Artery (LAD), Septal Perforator (SP) and Right Coronary Artery Chronic Total Occlusion (RCA CTO).

            CTO PCI can be approached anterograde and retrograde. With the anterograde approach, a CTO segment is crossed with a coronary wire traversing anterograde from the proximal to the distal segment. Thereafter, PCI is performed in a traditional fashion. With the retrograde approach, a CTO segment is crossed with a coronary wire traversing retrograde from the distal to the proximal segment. The wire reaches the distal segment of CTO through collateral vessels which originate from a contralateral donor vessel. For example, Figure 2 shows RCA CTO which is crossed with a wire that traverses the septal perforator from the left descending artery (LAD). Thereafter, the retrograde wire is advanced into the RCA guide and then externalized (Figure 3). That is, the retrograde wire is advanced through the entire length of the RCA guide and externalized outside the RCA guide. Over the externalized segment of the retrograde wire, PCI can be performed through the RCA guide in an anterograde fashion (Figures 4 and 5).

            Figure 2

            Retrograde Wire from LAD is Advanced Through SP into the Distal Segment of RCA Then Toward the RCA Guide.

            Blue arrows indicate the direction of the retrograde wire movement.

            Figure 3

            Retrograde Wire is Advanced Through the Entire Length of the RCA Guide and Externalized Outside the RCA Guide.

            Figure 4

            Over the Externalized Retrograde Wire (blue arrows), a Balloon is Advanced Anterograde Through the RCA Guide (Red Arrow).

            Figure 5

            Finished RCA CTO PCI via Retrograde Approach.

            Further categorization can be made into true lumen entry and dissection and re-entry. With the true lumen entry, a coronary wire traverses the CTO segment from true lumen on one side of the CTO segment to true lumen on the other side of the CTO segment (Figure 6). With the dissection and re-entry technique, a coronary wire traverses the CTO segment through the sub-intimal space. That is, the wire in true lumen on one side of the CTO segment enters the sub-intimal space adjacent to the CTO segment then re-enters the true lumen on the other side of the CTO segment (Figure 7).

            Figure 6

            True Lumen Entry.

            Coronary wire traverses the CTO segment from true lumen on one side of the CTO segment to true lumen on the other side of the CTO segment. Red area indicates true lumen of the vessel. Black area indicates CTO segment of the vessel. Yellow area indicates vessel wall. Blue arrow indicates coronary wire direction.

            Figure 7

            Dissection and Re-Entry.

            Coronary wire traverses the CTO segment from true lumen on one side of the CTO segment to true lumen on the other side of the CTO segment through sub-intimal space. Red area indicates true lumen of the vessel. Black area indicates CTO segment of the vessel. Yellow area indicates vessel wall. Blue arrow indicates coronary wire direction.

            The decision to pursue either anterograde or retrograde approaches or true lumen entry or dissection and re-entry depends on the anatomical features of CTO, the presence of calcification, stents, tortuosity, bifurcation, branch vessels, size, collateral vessels, location and the shape of the proximal and distal cap, as well as the length of the occlusion. CTO operators need working knowledge of CTO PCI algorithms and techniques, and familiarity with different wire characteristics and dedicated equipment.

            The learning curve for contemporary CTO PCI algorithm and techniques is steep. However, a CTO PCI program may be a worthy pursuit for a dedicated team. Interested readers are encouraged to study dedicated manuscripts for CTO PCI technique [3539], and participate in conferences dedicated to CTO PCI and educational programs such as www.CTOfundamentals.org.

            Future Direction

            Patients with CTO are an underserved cohort in need of a full complement of treatment options. Despite significant strides gained in CTO PCI, the procedure is often viewed by general cardiology community as a “high risk” procedure and often not discussed or offered to patients. In order to change this misconception and overcome this barrier, more educational effort is required. In particular, more prospective, randomized clinical trial data are needed to elucidate the benefits and limitations of CTO PCI. Results from prospective studies such as “A Randomized Multicentre Trial to Evaluate the Utilization of Revascularization or Optimal Medical Therapy for the Treatment of Chronic Total Coronary Occlusions (EuroCTO)” [ClinicalTrials.gov Identifier: NCT01760083], “Drug-Eluting Stent Implantation Versus Optimal Medical Treatment in Patients With Chronic Total Occlusion (DECISION-CTO)” [ClinicalTrials.gov Identifier: NCT01078051], and “Outcomes, patient health status and efficiency in CTO hybrid procedures (OPEN CTO)” [ClinicalTrials.gov Identifier: NCT02026466] will be enlightening. More educational effort is needed to improve the awareness in the general cardiology community regarding CTO such that CTO PCI is considered as a standard treatment option for appropriate candidates. Additional efforts are needed to increase the number of trained CTO operators so that patient care is not limited by the accessibility of an experienced operator. Continued development of dedicated equipment is needed to improve the success rate for CTO PCI. Given time and resource heavy nature of the procedure, policy and administrative support is needed so that CTO PCI is a financially viable endeavor for current and future CTO operators.

            Conclusion

            In the past decade, there has been an exponential growth in novel and innovative techniques, and development of dedicated equipment for CTO PCI which has resulted in a significant improvement in procedural success. Furthermore, due to growing interest in CTO PCI, studies dedicated to understanding the benefits and limitations of CTO PCI are being pursued in record numbers. Collaboration among CTO operators and industry in an effort to improve procedural success and patient care has been a fruitful endeavor. Dedicated CTO conferences and educational effort will increase the number of CTO operators which in turn will improve patient care and accessibility.

            Conflict of Interest

            The authors declare no conflict of interest.

            Disclosures

            Dr. Anderson is a consultant for BioSense Webster, a Johnson & Johnson company.

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            Author and article information

            Journal
            CVIA
            Cardiovascular Innovations and Applications
            CVIA
            Compuscript (Ireland )
            2009-8618
            2009-8618
            May 2016
            July 2016
            : 1
            : 3
            : 325-335
            Affiliations
            [1] 1Division of Cardiovascular Medicine, University of Florida, 1600 SW Archer Road, Gainesville, FL 32610-0277, USA
            Author notes
            Correspondence: Calvin Choi, MD, MS, Division of Cardiovascular Medicine, University of Florida, 1600 SW Archer Rd, Gainesville, FL 32610-0277, USA, E-mail: Calvin.choi@ 123456medicine.ufl.edu
            Article
            cvia20160023
            10.15212/CVIA.2016.0023
            de8ef1c0-f580-49ff-bc44-c0db46ee71bd
            Copyright © 2016 Cardiovascular Innovations and Applications

            This is an open-access article distributed under the terms of the Creative Commons Attribution 4.0 Unported License (CC BY-NC 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. See https://creativecommons.org/licenses/by-nc/4.0/.

            History
            Categories
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            General medicine,Medicine,Geriatric medicine,Transplantation,Cardiovascular Medicine,Anesthesiology & Pain management
            chronic total occlusion,percutaneous coronary intervention,coronary artery disease

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