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Retrograde CTO-PCI of Native Coronary Arteries Via Left Internal Mammary Artery Grafts: Insights From a Multicenter U.S. Registry
Abstract: Background. Retrograde percutaneous coronary intervention (PCI) of native coronary artery chronic total occlusion (CTO) via left internal mammary artery (LIMA) graft has received limited study. Methods and Results. We compared the clinical and procedural characteristics and outcomes of retrograde CTO-PCI through LIMA grafts vs other conduits in a contemporary multicenter CTO registry. The LIMA was used as the collateral channel in 20 of 990 retrograde CTO-PCIs (2.02%) performed at 18 United States centers. The mean age of the study patients was 69 ± 7 years and 95% were men. The most common CTO target vessel was the right coronary artery (55%). The mean J-CTO score in the LIMA group was high (3.45 ± 0.76). The technical success rates were 70% for retrograde PCI via LIMA graft vs 81.05% for retrograde via other conduits (P=.25), while procedural success rates were 70% for retrograde PCI via LIMA graft and 78.19% for retrograde via other conduits (P=.41). The incidence of major in-hospital complications was also similar between the LIMA and non-LIMA retrograde groups (5% vs 6%; P>.99). Use of guide-catheter extensions (40% vs 28%; P=.22), intravascular ultrasound (45% vs 31%; P=.20), and left ventricular assist devices (24% vs 10%; P=.08) was numerically higher in retrograde CTO-PCIs via LIMA grafts. Conclusions. Retrograde CTO-PCI is infrequently performed via LIMA grafts and is associated with similar success and major in-hospital complication rates as retrograde CTO-PCI performed via other conduits.
J INVASIVE CARDIOL 2018;30(3):89-96. Epub 2017 November 15.
Key words: left internal mammary artery graft, LIMA, retrograde PCI, chronic total occlusion
The retrograde approach is essential for contemporary chronic total occlusion (CTO) percutaneous coronary intervention (PCI) and involves advancement of a guidewire through a collateral vessel or a bypass graft distal to the occlusion, followed by crossing against the former direction of blood flow.1-5 Septal collaterals are the most commonly used vessels for retrograde CTO-PCI, whereas epicardial collaterals are used less commonly, as they can be more challenging to cross and carry higher risk for tamponade in case of perforation.6 Saphenous vein grafts (both patent and occluded) are also commonly used for retrograde CTO-PCI,7,8 although they carry risk for perforation and other complications as well.9-13 Left internal mammary artery (LIMA) grafts are the least preferred retrograde channels due to the large area of myocardium they supply with the concomitant risk for severe ischemia.14-18 Moreover, LIMA grafts are often highly tortuous, and straightening with guidewires and/or microcatheters may result in pseudolesions and compromised flow.19 We examined a contemporary multicenter registry to determine the frequency and outcomes of retrograde CTO-PCI via LIMA grafts.
Methods
We analyzed the clinical, angiographic, and procedural characteristics of retrograde CTO-PCI via LIMA grafts among 990 retrograde cases in 976 patients included in the PROGRESS CTO (Prospective Global Registry for the Study of Chronic Total Occlusion Intervention) registry (NCT02061436) between January 2012 and April 2017 at 18 United States centers. Some centers only enrolled patients during part of the study period due to participation in other studies. The study was approved by the Institutional Review Board of each center.
Definitions. Coronary CTOs were defined as coronary lesions with Thrombolysis in Myocardial Infarction (TIMI) grade 0 flow of at least 3-month duration. Estimation of the duration of occlusion was clinical, based on the first onset of angina, prior history of myocardial infarction in the target-vessel territory, or comparison with a prior angiogram. Calcification was assessed by angiography as mild (spots), moderate (involving ≤50% of the reference lesion diameter), or severe (involving >50% of the reference lesion diameter). Moderate proximal vessel tortuosity was defined as the presence of at least 2 bends >70° or 1 bend >90°, while severe tortuosity was defined as 2 bends >90° or 1 bend >120° in the CTO vessel. Blunt or no stump was defined as lack of tapering or lack of a funnel shape at the proximal cap. Interventional collaterals were defined as collaterals considered amenable to crossing by a guidewire and a microcatheter by the operator. A procedure was defined “retrograde” if an attempt was made to cross the lesion through a collateral vessel or bypass graft supplying the target vessel distal to the lesion. Retrograde PCI via LIMA was defined as interventions that used the LIMA as retrograde pathway, while retrograde PCI via non-LIMA described any retrograde interventions through other collateral vessels or saphenous vein grafts. Antegrade dissection/re-entry was defined as antegrade PCI during which a guidewire was intentionally introduced into the subintimal space proximal to the lesion, or re-entry into the distal true lumen was attempted following intentional or inadvertent subintimal guidewire crossing.
Technical success was defined as successful CTO revascularization with achievement of <30% residual diameter stenosis within the treated segment and restoration of TIMI grade 3 antegrade flow. Procedural success was defined as the achievement of technical success without any in-hospital complications. In-hospital major adverse cardiac events (MACE) included any of the following adverse events prior to hospital discharge: death, myocardial infarction, recurrent symptoms requiring urgent repeat target-vessel revascularization with PCI or coronary artery bypass graft (CABG) surgery, tamponade requiring either pericardiocentesis or surgery, and stroke. Myocardial infarction was defined using the Third Universal Definition of Myocardial Infarction (type 4 myocardial infarction).20Major bleeding was defined as bleeding causing reduction in hemoglobin >3 g/dL or bleeding requiring transfusion or surgical intervention. The J-CTO score was calculated as described by Morino et al,21 the PROGRESS-CTO score as described by Christopoulos et al,22 and the PROGRESS-CTO complications score as described by Danek et al.23
Statistical analysis. Categorical variables were expressed as percentages and were compared using Pearson’s Chi-square test or Fisher’s exact test. Continuous variables were presented as mean ± standard deviation or median with interquartile range (IQR) unless otherwise specified, and were compared using the t-test or Wilcoxon rank-sum test, as appropriate. All statistical analyses were performed with JMP 13.0 (SAS Institute). A two-sided P-value of .05 was considered statistically significant.
Results
Clinical and angiographic characteristics. The retrograde approach was used in 990 of 2465 cases (40.16%) performed during the study period and the LIMA graft was used as retrograde channel in 20 cases (2.02% of all retrograde cases). The baseline clinical and angiographic features are summarized in Table 1 and Table 2. Mean age was higher in the LIMA group (69 ± 7 years vs 65 ± 10 years; P=.05) and most patients were men in both groups (94.7% vs 85.0%; P=.50).
The CTO target vessel in the LIMA group was the right coronary artery (55%), left circumflex (15%), left main (10%), and left anterior descending artery (20%). Median occlusion length was 40 mm (IQR, 30-60 mm) and median target vessel diameter was 3 mm (IQR, 2.5-3.75 mm). Patients undergoing retrograde CTO-PCI via LIMA grafts vs non-LIMA conduits were likely to have proximal cap ambiguity (63.2% vs 50.4%; P=.35) and blunt or no stump at the proximal cap (84.2% vs 70.9%; P=.30). The mean J-CTO scores (3.45 ± 0.76 vs 3.15 ± 1.05; P=.10), PROGRESS CTO scores (2.00 ± 0.84 vs 1.86 ± 0.91; P=.52), and PROGRESS CTO complications scores (4.73 ± 1.44 vs 4.25 ± 1.68; P=.22) were similar.
Interventional techniques. The CTO crossing techniques used in patients in whom retrograde crossing via LIMA grafts was attempted are shown in Figure 1, and the overall technical characteristics are listed in Table 3. An initial antegrade crossing attempt was used in 12 patients (60%) and a primary retrograde approach was used in the remaining 8 cases (40%). The success rate of the initially applied crossing technique was low (only 2 cases in the primary retrograde group). After failure of antegrade-wire escalation, retrograde crossing was attempted in all cases except 1 case in which antegrade dissection/re-entry was used. In 5 cases, three or more crossing strategies were used, with success in 4 cases.
Overall, antegrade-wire escalation was attempted in 14 cases (70%), but was only successful in 1 case, after multiple failed retrograde or antegrade dissection re-entry crossing attempts. Antegrade dissection re-entry was used in 5 cases (25%) – in most cases after a failed retrograde crossing attempt – and was successful in 2 cases (10%) using Stingray-based re-entry (Boston Scientific) in 1 case and wire-based re-entry in the other. Retrograde crossing through a LIMA graft was attempted in every case and the CTO was successfully crossed in 12 patients (60%). In 11 cases, the lesion crossings were carried out via the LIMA graft, while 1 of them was crossed through a saphenous vein graft and an epicardial collateral. Among the successful retrograde cases, the following crossing techniques were applied: reverse controlled antegrade and retrograde tracking (CART) in 6 cases, GuideLiner reverse CART in 1 case (Figure 2), and true retrograde lumen puncture in 5 cases. Intravascular ultrasound tended to be used more commonly in the LIMA group (45.0% vs 31.4%; P=.20), as were guide-catheter extensions (40.0% vs 27.9%; P=.22).
Bifemoral approach was used in 9 cases (45%) and biradial approach was used in 2 cases. Use of left radial access was significantly higher in the LIMA group (55.0% vs 22.2%; P=.02). In 6 cases, triple arterial access was used, including the left radial approach in 5 cases (in 1 patient, brachial access was attempted for providing appropriate IMA guide-catheter support).
Procedural outcomes and complications. The procedural outcomes are shown in Table 4. Technical and procedural success in the retrograde via LIMA grafts was 70% and 70%, respectively, and was similar with other retrograde cases (81% and 78%; P=.25 and P=.41, respectively). Median contrast volumes (300 mL [IQR, 250-346 mL] vs 300 mL [IQR, 222.5-420 mL]; P=.70), patient air-kerma doses (3.54 Gy [IQR, 2.91-5.23 Gy] vs 3.85 Gy [IQR, 1.50-5.78 Gy]; P=.92), and fluoroscopy times (89.4 min [IQR, 61-126 min] vs 76.9 min [IQR, 54.9-103 min]; P=.14) were also similar in the two study groups, whereas procedural time (222.5 min [IQR, 174-311.5 min] vs 189 min [IQR, 134-245 min]; P=.03) was longer in the LIMA group.
Use of mechanical circulatory support was numerically higher in the LIMA vs non-LIMA group (23.5% vs 9.5%; P=.08). Mechanical circulatory support was used in 4 retrograde via LIMA cases (prophylactic in 3 and elective in 1); both Impella (Abiomed) and veno-arterial extracorporeal membrane oxygenator (VA-ECMO) were used. One patient initially had an Impella device that was changed to VA-ECMO due to progressive cardiogenic shock.
The incidence of in-hospital MACE was similar in the LIMA and control retrograde groups (5.0% vs 5.5%; P>.99). One patient in the LIMA group had a complication; the CTO was successfully crossed using the reverse-CART technique. The CTO was balloon uncrossable, requiring laser atherectomy that led to coronary perforation of the target vessel (left main), which necessitated placement of a covered stent that jailed the circumflex and led to periprocedural myocardial infarction.
Other complications were common in both the LIMA and non-LIMA retrograde groups (25.0% vs 16.7%; P=.36). Five complications occurred in the LIMA group. LIMA dissection occurred in 1 patient, but did not compromise flow and no additional treatment was required. Three patients had a vascular access complication (1 patient who was supported by ECMO required surgical correction of a pseudoaneurysm and 2 patients developed groin hematoma without need for surgical correction). One patient developed acute kidney failure requiring hemodialysis.
Procedural outcomes among patients with prior CABG. The procedural outcomes of patients with prior CABG who underwent retrograde CTO intervention are listed in Table 5. Prior CABG was common among retrograde CTO-PCI (46.0%) and the overall technical and procedural success rates were 79.4% and 77.6%, respectively, which was comparable with the retrograde LIMA group (P=.27). The overall procedural complications were high in CABG patients (19.7%), as they were in retrograde PCIs via LIMA (25.0% vs 19.4%; P=.56), and in-hospital major complications remained similarly low (5.0% vs 5.1%; P>.99).
Discussion
To the best of our knowledge, this is the first systematic study of retrograde CTO-PCI via LIMA grafts. LIMA grafts were infrequently used for retrograde CTO-PCI, but were associated with similar technical and procedural success rates. Use of LIMA grafts was associated with higher risk for vascular access complications and a trend for more frequent use of mechanical circulatory support devices.
The retrograde approach is critical to the success of CTO PCI, as demonstrated in several studies from around the world.3,24,25 However, it carries higher risk for complications as compared with antegrade-only crossing strategies, especially in older patients, longer lesions,23 and prior CABG patients.26,27 The availability of “interventional” collaterals, ie, collaterals that appear amenable to retrograde crossing with guidewires and microcatheters, is necessary to perform retrograde CTO-PCI. Several patterns of septal and epicardial collaterals were recently described,28 along with a collateral scoring system for predicting their crossability. Septal collaterals are preferred over epicardial collaterals for retrograde CTO-PCI, as they carry low risk for complications.29,30 Saphenous vein grafts are also appealing for retrograde CTO-PCI, even when they are occluded.7,8 LIMA grafts are rarely used for retrograde CTO-PCI, because they carry higher intrinsic risk for complications for several reasons. First, LIMA grafts are often tortuous and advancing guidewires and microcatheters may result in straightening of the graft and an “accordion” effect, leading to compromised flow and ischemia. Second, dissection of the LIMA graft origin can occur; hence, large guide catheters (such as 7 Fr or 8 Fr) are not usually used in these cases. Third, LIMA grafts are usually anastomosed to the left anterior descending artery, and compromising their flow can lead to severe ischemia. Fourth, LIMA grafts have excellent long-term patency, so attempts to prevent vessel injury are critical.
Given the potentially catastrophic risks associated with their use, LIMA grafts should only be used for retrograde CTO-PCI when no other options exist and the potential benefits of the procedure are substantial. Our study demonstrates that LIMA grafts can be successfully used in such cases with good success and acceptable complication rates. Donor-vessel dissection occurred in just 1 case; there was no flow limitation, and the procedure was carried out uneventfully without any additional treatment of the LIMA. To prevent LIMA graft injury, guide catheters should be selected carefully, with softer tips and small diameters (usually 6 Fr or smaller) to avoid pressure dampening. Guide-catheter extensions should be used infrequently, as they may predispose to LIMA dissection.31 Given the potential for severe ischemia with retrograde CTO-PCI via LIMA grafts, such procedures may more often need to be performed using hemodynamic support devices, which at least in part explains the higher rate of vascular access complications. An alternative to using LIMA grafts and septal collaterals for retrograde PCI or right coronary artery CTOs is to perform left main and/or left anterior descending CTO intervention as a first step, followed by retrograde CTO-PCI via septal collaterals.
Study limitations. Our study has several limitations. The number of patients included was relatively small and we did not have long-term follow-up. The power of the study is low given the small number of cases with PCI via the LIMA graft, and further evaluation is needed with large patient cohorts. There was no core laboratory assessment of the study angiograms or clinical events committee adjudication. The procedures were performed by experienced CTO operators in dedicated, high-volume centers, limiting extrapolation to less experienced operators and centers.
Conclusion
LIMA grafts are infrequently used for retrograde CTO-PCI; however, their use is associated with similar technical and procedural success when compared with other retrograde procedures. In the hands of experienced operators and when performed with great caution, retrograde CTO-PCI via LIMA graft can be a valuable tool for highly complex CTO-PCI cases.
Acknowledgments. Study data were collected and managed using Research Electronic Data Capture (REDCap) electronic data capture tools hosted at the University of Texas Southwestern Medical Center. REDCap is a secure, web-based application designed to support data capture for research studies, providing: (1) an intuitive interface for validated data entry; (2) audit trails for tracking data manipulation and export procedures; (3) automated export procedures for seamless data downloads to common statistical packages; and (4) procedures for importing data from external sources.
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From the 1Minneapolis Heart Institute, Abbott Northwestern Hospital, Minneapolis, Minnesota; 2University of Szeged, Department of Invasive Cardiology, Department of Second Internal Medicine and Cardiology Center, Szeged, Hungary; 3VA North Texas Health Care System and University of Texas Southwestern Medical Center. Dallas, Texas; 4Columbia University, New York, New York; 5Henry Ford Hospital, Detroit, Michigan; 6Massachusetts General Hospital, Boston, Massachusetts; 7Beth Israel Deaconess Medical Center, Boston, Massachusetts; 8VA San Diego Healthcare System and University of California San Diego, La Jolla, California; 9Baylor Heart and Vascular Hospital, Dallas, Texas; 10Medical Center of the Rockies, Loveland, Colorado; 11University of Pittsburgh Medical Center, Pittsburgh, Pennsylvania; 12VA Central Arkansas Healthcare System, Little Rock, Arkansas; and 13VA Minneapolis Healthcare System and University of Minnesota, Minneapolis, Minnesota.
Clinical Trial Registration: NCT02061436, Prospective Global Registry for the Study of Chronic Total Occlusion Intervention (PROGRESS CTO)
Funding: The Progress CTO registry has received support from the Abbott Northwestern Hospital Foundation. Research reported in this publication was supported by the Clinical and Translational Science Awards Program of the National Institutes of Health (Bethesda, MD, USA) under grant number UL1-RR024982. The content is solely the responsibility of the authors and does not necessarily represent the official views of the NIH.
Disclosure: The authors have completed and returned the ICMJE Form for Disclosure of Potential Conflicts of Interest. Drs Tajti and Karatasakis report no disclosures. Dr Karmpaliotis reports speaker honoraria from Abbott Vascular, Boston Scientific, Medtronic, and Vascular Solutions. Dr Alaswad reports consulting fees from Terumo and Boston Scientific; consultancy (non-financial) to Abbott Laboratories. Dr Jaffer reports consulting for Abbott Vascular and Boston Scientific; research grants from Canon, Siemens, National Institutes of Health. Dr Yeh reports a Career Development Award (1K23HL118138) from the National Heart, Lung, and Blood Institute. Dr Patel reports speakers’ bureau fees from Astra Zeneca. Dr Mahmud reports consulting fees from Medtronic and Corindus; speaker’s fees from Medtronic, Corindus, and Abbott Vascular; educational program fees from Abbott Vascular; and clinical events committee fees from St. Jude. Drs Choi, Doing, Toma, and Uretsky report no disclosures. Dr Garcia reports consulting fees from Medtronic. Dr Moses reports consultancy to Boston Scientific and Abiomed. Dr Parikh reports speakers’ bureau fees from Abbott Vascular, Medtronic, CSI, BSC, Trireme; advisory boards for Medtronic, Abbott Vascular, and Philips. Dr Kirtane reports institutional research grants to Columbia University from Boston Scientific, Medtronic, Abbott Vascular, Abiomed, St. Jude Medical, Vascular Dynamics, Glaxo SmithKline, and Eli Lilly. Dr Ali reports consultant fees/honoraria from St. Jude Medical and AstraZeneca Pharmaceuticals; ownership interest/partnership/principal in Shockwave Medical and VitaBx, Inc; and research grants from Medtronic and St. Jude Medical. Drs Hatem, Karacsonyi, and Danek report no disclosures. Dr Rangan reports research grants from InfraReDx, Inc and Spectranetics. Dr Banerjee reports research grants from Gilead and the Medicines Company; consultant/speaker honoraria from Covidien and Medtronic; ownership in MDCare Global (spouse); intellectual property in HygeiaTel. Dr Brilakis reports personal fees from Abbott Vascular, Acist, Amgen, Asahi Intecc, CSI, Elsevier, GE Healthcare, Medicure, and Nitiloop; grants from Boston Scientific and Osprey; he serves on the Board of Directors for the Cardiovascular Innovations Foundation and the Board of Trustees of the Society of Cardiovascular Angiography and Interventions.
Manuscript submitted June 9, 2017, final version accepted July 3, 2017.
Address for correspondence: Emmanouil S. Brilakis, MD, PhD, Minneapolis Heart Institute, 920 E. 28th Street #300, Minneapolis, MN 55407. Email: esbrilakis@gmail.com
