Korean Multicenter Registry Study of EPIC Stents for the Treatment of Iliac Artery Disease: K-EPIC Registry

- ¹Division of Cardiology, Department of Internal Medicine, Severance Cardiovascular Hospital, Yonsei University College of Medicine, Seoul, Korea.
- ²Cardiovascular Center, Korea University Guro Hospital, Seoul, Korea.
- ³Division of Cardiology, Department of Internal Medicine, National Health Insurance Service Ilsan Hospital, Goyang, Korea.
- ⁴Division of Cardiology, Department of Internal Medicine, Seoul National University Bundang Hospital, Seoungnam, Korea.
- ⁵Division of Cardiology, Department of Medicine, Samsung Medical Center, Sungkyunkwan University School of Medicine, Seoul, Korea.
- ⁶Division of Cardiology, Department of Internal Medicine, Gangnam Severance Hospital, Yonsei University College of Medicine, Seoul, Korea.
- ⁷Department of Internal Medicine, Chungbuk National University Hospital, Cheongju, Chungbuk National University College of Medicine, Korea.
- ⁸Department of Internal Medicine, Cardiovascular Center, Seoul National University Hospital, Seoul, Korea.
- ⁹Cardiology Department, Soonchunhyang University Cheonan Hospital, Cheonan, Korea.
- ¹⁰Division of Cardiology, Department of Internal Medicine, Yongin Severance Hospital, Yonsei University College of Medicine, Yongin, Korea.
Correspondence to Donghoon Choi, MD, PhD. Division of Cardiology, Department of Internal Medicine, Yongin Severance Hospital, Yonsei University College of Medicine, 363 Dongbaekjukjeon-daero, Yongin 16995, Korea. Email: cdhlyj@yuhs.ac

^*Drs. Dae-Young Kim and Young-Guk Ko contributed equally to this work.

Received September 25, 2020; Revised November 02, 2020; Accepted November 25, 2020.

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (https://creativecommons.org/licenses/by-nc/4.0) which permits unrestricted noncommercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Background and Objectives

The EPIC™ stent is a self-expanding, nitinol stent that has been designed to enhance flexibility and provide expansion within vessels. The aim of the present study was to investigate the clinical efficacy and safety of the EPIC™ stent when used to treat iliac artery diseases in a prospective Korean multicenter registry.

Methods

A total of 138 patients with iliac artery diseases who received endovascular treatment with EPIC™ stents at 9 Korean sites were enrolled in a prospective cohort and followed for 1 year. The primary endpoint was the 1-year freedom from target lesion revascularization (TLR). The secondary endpoints were 1-year clinical patency and freedom from major adverse events (MAEs).

Results

The mean age of the study subjects was 66.8±8.5 years and most subjects were male (86.2%). The most frequent lesion type was Trans-Atlantic Inter-Society Consensus B (43.5%) and the majority (56.5%) of the target lesions were located in the common iliac artery. Procedural success was obtained in 99.3% of patients. The freedom from TLR and the clinical patency at 1-year follow-up were 94.9% and 92.3%, respectively. The 1-year rate of MAEs was 5.1%. Combined coronary artery disease (hazard ratio [HR], 5.91; 95% confidence interval [CI], 1.13–30.89; p=0.035) and smaller stent diameter (HR, 0.38; 95% CI, 0.17–0.88; p=0.023) were identified as independent risk factors of TLR after EPIC™ stent implantation.

Conclusions

The EPIC™ stents demonstrated excellent immediate and 1-year efficacy and safety outcomes in iliac artery lesions in this multicenter, prospective, registry-based study.

Keywords

Iliac artery; Nitinol; Self expandable metallic stent; Vascular patency; Peripheral artery disease

INTRODUCTION

Endovascular therapy (EVT) has been widely applied in the treatment of peripheral artery diseases (PADs) due to its minimal invasiveness and lower perioperative morbidity compared with surgical treatment.1), 2), 3) Atherosclerotic aortoiliac disease is commonly observed in patients undergoing EVT for symptomatic lower extremity artery disease.4) In a recent guideline, EVT was recommended as a first-line treatment strategy not only for short aortoiliac lesions but also for extensive lesions in patients with severe comorbidities.3) Although both primary and provisional stenting may achieve similar results in patients with limited aortoiliac lesions, primary stenting may provide superior outcomes for complex aortoiliac lesions.3), 5) Currently, several different types of stents such as self-expanding, balloon-expanding, and covered stents are available for the treatment of aortoiliac lesions. However, there is limited information comparing the effectiveness of these devices.6) Iliac artery lesions tend to be tortuous and calcified. In particular, distal external iliac artery lesions are exposed to forces related to the movement of the hip joint.7) The EPIC™ stent (Boston Scientific, Natick, MA, USA) is a self-expanding nitinol stent with a hybrid design of open and closed cell structures that may enhance its flexibility and conformational dilation capability.8) The purpose of the present study was to investigate the clinical efficacy and safety of the EPIC™ stent in the treatment of iliac artery diseases using a Korean multicenter prospective registry (K-EPIC Registry).

METHODS

Study population and enrollment

This study was a single-arm, prospective, multicenter trial evaluating the EPIC™ self-expanding nitinol stent in the treatment of atherosclerotic iliac artery diseases. The trial was conducted in 9 sites in South Korea following the Declaration of Helsinki 2013. The study protocol was approved by the Institutional Review Board (IRB) of Yonsei University Health System (IRB number: 1-2015-0075). All patients provided written informed consent before enrollment.

Patients were eligible if all following inclusion criteria were met, such as age ≥19 years, clinical presentation of Rutherford category 2 to 4, stenotic (≥50% diameter stenosis) or occlusive iliac artery lesions, and an ankle-brachial index (ABI) <0.9. Exclusion criteria included acute severe limb ischemia, severe critical limb ischemia of Rutherford category 5 or 6, age >85 years, known allergic reactions to heparin, aspirin, clopidogrel, or contrast agent, in-stent restenosis, previous bypass surgery in the targeted vessel, uncontrolled congestive heart failure or left ventricular ejection fraction ≤40%, severe hepatic dysfunction (aspartate transaminase or alanine aminotransferase ≥3-fold higher than the normal reference value), significant leukopenia, neutropenia, thrombocytopenia, anemia, or risk of bleeding, pregnant or fertile women, life expectancy under 1 year, and non-treated significant inflow disease. Before enrollment, each patient's medical history, baseline medications, Rutherford classification, Korean-Peripheral Artery Questionnaire (K-PAQ)9) for the investigation of quality of life, ABI, at least one imaging study such as computed tomography (CT), magnetic resonance imaging, duplex ultrasound, or catheter angiography and Trans-Atlantic Inter-Society Consensus (TASC) II type assessment, laboratory tests including blood cell count, routine chemistry, lipid profile, and C-reactive protein were performed.

K-PAQ is the Korean version of the Peripheral Artery Questionnaire of 20-item health status used for patients with PAD. Each question asks about symptoms related to PAD over the previous 4 weeks. The questionnaire consists of 6 domains (symptoms, symptom stability, physical limitations, treatment satisfaction, social functioning, and quality of life) with scored responses. A summary score represents the average score for symptoms, physical limitation, social functioning, and quality of life. The scores range from 0 to 100, where higher scores represent better control of symptoms, reduced physical limitation, better treatment satisfaction and social functioning, and better quality of life.

Endovascular and therapy

Before the procedure, patients were pre-medicated with aspirin (300 mg, at least 24 hours prior) and clopidogrel (300 mg, at least 12 hours prior) if patients had not taken aspirin and clopidogrel for at least 5 days before the procedure. After the insertion of the introducer sheath, a bolus of 5,000 units of unfractionated heparin was administrated and activated coagulation time was maintained above 250 seconds.

Vascular access to the target lesion was obtained by either the ipsilateral retrograde or the contralateral cross-over approach from the common femoral artery, using a percutaneous method. An antegrade approach via a brachial or radial artery was also permitted if necessary. A 6–7 F sheath (TERUMO Inc., Tokyo, Japan) was used on the ipsilateral approach and a 6–7 F sheath (Balkin or Ansel; Cook Inc., Bloomington, IN, USA) was used on the contralateral approach. To cross the target lesion, a 0.018 or 0.035-inch guidewire was used. To evaluate the characteristics of the iliac artery lesion and runoff vessels, pre-procedure angiography was obtained from the proximal iliac artery to the distal tibial artery. In cases of complete occlusion, an intraluminal or subintimal approach was selected at the operator's discretion. Target lesions were pre-dilated with a balloon catheter to a diameter equal-to or smaller-than the reference diameter. All iliac target lesions were treated with EPIC™ stents. The stent diameter was chosen to be 1 mm larger than the target lesion reference diameter. The stent length was selected to be sufficient to cover the whole diseased segment. Post-dilation was performed with a balloon of vessel diameter at a relatively low inflation pressure. After EVT, dual antiplatelet agents (aspirin at 100 mg/day and clopidogrel at 75 mg/day) were administrated for at least 6 months. After 6 months, single antiplatelet therapy with aspirin or clopidogrel was maintained.

Follow-up

After EVT, patients were evaluated for symptom status via Rutherford classification and ABI, and laboratory tests were performed. Patients were followed-up routinely at 1 month after the procedure and 3- or 6-month intervals thereafter. At each follow-up, clinical evaluations including Rutherford classification and physical examinations were performed. ABI was repeated at 6 months and 1 year after the procedure, or at any time if symptom status deteriorated. K-PAQ was performed at the 1-month and 1-year follow-up. An imaging evaluation such as CT angiography, duplex ultrasound, or intra-arterial angiography was recommended at the 1-year follow-up or at any time if the patient's symptoms worsened by ≥1 Rutherford category or if symptom status deteriorated and ABI decreased by >0.15.

Endpoints and definitions

The primary endpoint was the 1-year freedom from target lesion revascularization (TLR), which was defined as any surgical or percutaneous intervention to the target lesion after initial EVT due to restenosis of the target lesion with worsened symptoms. The secondary endpoints were a 1-year clinical patency rate and freedom from major adverse events (MAEs) after implantation of EPIC™ stents. Clinical patency was defined as freedom from symptom aggravation by increased Rutherford category combined with a decrease in ABI over 0.15 compared with post-procedure ABI or as an absence of restenosis (>50%) on imaging modalities, such as duplex ultrasound, angiography, or CT based angiography. MAE was defined as a composite of procedure-related death within one month, in-hospital myocardial infarction, TLR, and amputation of the treated limb. Procedural success was defined as the absence of residual stenosis more than 30% or arterial dissection limiting blood flow.

Statistical analysis

Continuous variables are presented as the mean±standard deviation, and categorical variables are presented as frequency and percentage. Baseline clinical and lesion characteristics were analyzed using the Student's t-test for continuous data and χ² and Fisher's exact test for categorical data. The one-way analysis of variance was used for comparisons of K-PAQ scores at baseline, 1 month, and 1 year of follow-up.

Freedom from TLR, clinical patency, and MAE were assessed using the Kaplan-Meier method and a log-rank test was used to compare each group. The predictors of TLR were evaluated using a univariate and multivariate analyses of the Cox proportional hazard regression. All variables with p<0.15 in univariate analysis were included in the multivariate analysis model.

A p value <0.05 was considered significant. All statistical analyses were performed using SPSS 25.0 software (IBM Corp., Armonk, NY, USA).

RESULTS

Study population

Initially, a total of 150 patients were enrolled at 9 university hospitals in South Korea between December 2015 to July 2018. However, 12 patients were excluded due to pre-specified criteria (Rutherford category 0 or 1 [n=6], Rutherford category 5 or 6 [n=3], congestive heart failure [n=1], non-treated aortic lesion [n=1], and withdrawal of consent [n=1]). The remaining 138 patients were included in the present analysis (Figure 1). The baseline clinical characteristics of the study subjects are summarized in Table 1. The mean age was 66.8±8.5 years and most patients were male (86.2%). Hypertension and diabetes were present in 75.4% and 50.0% of the study subjects, respectively. Coronary artery disease was observed in 33.3% of patients. The most common clinical presentation in the study subjects was severe claudication (68.1%). The mean ABI in the target limb was 0.60±0.30.

Figure 1
Patient flowchart.

Table 1
Baseline patient characteristics

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Lesion characteristics

Table 2 shows the lesion characteristics of all patients. The most frequent lesion type was TASC B (n=60, 43.5%), followed by the TASC A (n=41, 29.7%), TASC C (n=22, 15.9%), and TASC D (n=15, 10.9%). The majority (56.5%) of target lesions were located in the common iliac artery (CIA). Extensive lesions involving both the common and external iliac arteries were observed in 15.9% of patients. Total occlusion was found in 39.1% of patients. Pre-dilation was performed in all patients. The mean stent diameter was 8.8±1.0 mm. Post-dilation was required in 77.5% of patients.

Table 2
Baseline lesion characteristics

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Immediate outcomes

Procedural success was obtained in 137 of the 138 patients (99.3%). The one procedural failure was a case with residual stenosis over 30% despite post-dilation after stenting. Procedure-related complications occurred in 2 patients (1.4%). One patient showed distal embolization to the ipsilateral popliteal artery, which was successfully treated by thrombus aspiration. Another patient experienced perforation of the CIA during the procedure, which was successfully managed by prolonged balloon inflation.

Clinical outcomes at 1-year follow-up

Of the 138 patients included in this study, 136 patients completed the 1-year clinical follow-up. An imaging follow-up at 12 months was performed in 46 patients (33.3%). Clinical symptom assessment using K-PAQ was followed in 130 patients (94.2%). One patient died at 2 months due to a cardiovascular complication after TLR by bypass surgery. Another patient died at 8 months due to sepsis. The freedom from TLR was 94.9% at 1 year (Figure 2A). Among 7 patients who required TLR, 6 patients underwent endovascular revascularization and 1 patient received bypass surgery. The 1-year clinical patency was 92.3% (Figure 2B). The 1-year rate of freedom from MAE was 94.9% (Figure 2C). Within 1 month, there was no mortality, in-hospital myocardial infarction, or target limb amputation. All 7 MAEs were related to TLR within 1 year.

Figure 2
Kaplan-Meier curves for clinical outcomes of all patients.
MAE = major adverse event; PTA = percutaneous transluminal angioplasty; TLR = target lesion revascularization.

When TASC lesion types A/B and C/D were compared, the freedom from TLR (90.4% vs. 94.4%, log-rank p=0.456, Figure 3A) as well as the clinical patency (91.7% vs. 94.1%, log-rank p=0.628, Figure 3B) showed no significant difference between the 2 subgroups. Patients' symptom status, expressed as Rutherford category at baseline, post-procedure, 6 months, and 12 months are shown in Figure 4. Before the procedure, all patients (n=138) had either intermittent claudication (Rutherford class 2–3, n=121) or rest pain (Rutherford class 4, n=17). After the EVT, 67 patients (48.6%) were asymptomatic (Rutherford class 0) and the proportion of asymptomatic patients further increased to 64.7% at 6 months and 72.1% at 12 months. Health status expressed as K-PAQ at baseline, 1 month, and 12 months are shown in Supplementary Table 1. The summary score at baseline was 40.9±23.1 and was significantly improved to 74.2±24.7 at 1 month and 82.3±23.2 at 12 months. All K-PAQ domains (except the one representing treatment satisfaction) were significantly improved after 1 and 12 months.

Figure 3
Kaplan-Meier curves for clinical outcomes in patients with TASC A/B and C/D.
PTA = percutaneous transluminal angioplasty; TASC = Trans-Atlantic Inter-Society Consensus; TLR = target lesion revascularization.

Figure 4
Rutherford class at baseline as well as post-procedure, 6 months, and 12 months after endovascular treatment for aortoiliac occlusive diseases.

Predictors for TLR

In univariate analyses, a history of coronary artery disease, smaller stent diameter, and longer stent length was significantly associated with increased risk of TLR. The multivariate analysis of the Cox proportional hazard model identified the history of coronary artery disease (hazard ratio [HR], 5.91; 95% confidence interval [CI], 1.13–30.89; p=0.035) and smaller stent diameter (HR, 0.38; 95% CI, 0.17–0.88; p=0.023) as significant independent predictors of restenosis (Table 3).

Table 3
Predictors of TLR

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DISCUSSION

This prospective registry study evaluated clinical outcomes in patients treated with EPIC™ self-expanding stents for iliac lesions and evaluated risk factors to predict TLR. The main findings of the present study were as follows: 1) The EPIC™ stent showed excellent clinical outcomes in terms of freedom from TLR (94.9%) and clinical patency (92.3%) at 1-year of follow-up. 2) The incidence of procedure-related complications was rare (1.4%). 3) The 1-year rate of MAE also remained low (5.1%). 4) In our study population, combined coronary artery disease and smaller stent diameter were identified as independent risk factors of TLR after EPIC™ stent implantation in the iliac artery lesions. 5) The lesion complexity, such as TASC C/D, had no apparent impact on patency after EVT.

In a prior randomized trial, the first generation nitinol stent (SMART™; Cordis, Warren, NJ, USA) demonstrated comparable primary patency (94.7% vs. 94.6%) in iliac lesions at 12 months compared with Wallstent™, a braided Elgiloy stainless steel stent.10) However, the procedural success rate of the SMART™ stent was significantly higher than that of the Wallstent™, at 98.2% and 87.5%, respectively. Owing to the characteristic properties of nitinol, such as shape memory and superelasticity,11) self-expanding nitinol stents appear to be effective for maintaining patency in complex aortoiliac lesions by preventing vessel collapse and ensuring stability. Other studies evaluating nitinol stents such as Protégé stents (Medtronic, Plymouth, MN, USA) and the Astron stent (Biotronik AG, Bülach, Switzerland) have also reported favorable outcomes in the treatment of iliac artery disease. The 9-month primary patency and freedom from the target for Protégé stents in the DURABILITY study were 95.8% and 98.6%, respectively. The 12-month primary patency and freedom from TLR for the Astron stent were 89.8% and 97.9%, respectively.12) The EPIC™ stent is a self-expanding nitinol stent with a hybrid design of open- and closed-cell geometry engineered to provide flexibility. The efficacy and safety of the EPIC™ stent have been previously evaluated in the ORION trial, a single-arm prospective multicenter clinical trial, which enrolled 125 patients with 166 iliac artery lesions in 28 sites in the USA. At the 12-month follow-up, the freedom from the TLR rate was 94.6% and the primary patency was 94.4%.13) A Japanese multicenter retrospective study also investigated the clinical outcomes of the EPIC™ stent in aortoiliac artery disease and reported similar 12-month rates of freedom from TLR (96.0%) and primary patency (92.2%).8) Our study demonstrated results that were consistent with those previous studies. Similarly to our study, the ORION study did not show a significant difference in the primary patency rate between the TASC A/B group vs. TASC C/D group (96.1% and 97.6%).13)

The efficacy of self-expanding stents was shown in a randomized controlled study comparing self-expanding stents vs. balloon-expandable stents for iliac artery disease.14) In this study, the self-expanding stents showed superior outcomes in terms of primary patency (94.5% vs. 87.0%) and freedom from TLR (97.2% vs. 93.6%) relative to balloon-expandable stents.

Predictable factors of revascularization after the implantation of nitinol stents in iliac artery lesions have been analyzed in several studies. Tsujimura et al.8) reported that diabetes mellitus and a small reference vessel diameter were predictors of lesion patency. In the BRAVISSIMO study,15) kissing stent technique and obesity were independent risk factors for restenosis. Interestingly, Bechter-Hugl et al.16) found that younger age, especially in female patients, was a significant predictor of restenosis, as was a smaller stent diameter. Our study also found that a small stent diameter (HR, 0.38; p=0.023) was an independent risk factor for TLR. Furthermore, coronary artery disease was another independent risk factor for TLR (HR, 5.91; p=0.035) in our study. The reason for the significant association between coronary artery disease and the development of restenosis after iliac stenting remains unclear. It is possible that patients with polyvascular disease, involving more than one vascular system, would have more progressed atherosclerosis than PAD alone, and would be high-risk patients to develop restenosis after revascularization. Previous studies have shown that polyvascular atherosclerotic disease in PAD patients is associated with increased rates of mortality, major adverse cardiac events, and lower extremity revascularization.17), 18)

This study had several limitations. First, the study population was relatively small. In particular, subjects with complex iliac artery lesions such as TASC C or D were not sufficiently represented. Second, follow-up imaging studies such as CT angiography, vascular angiography, or Doppler ultrasound were not consistently performed in all patients, potentially contributing to bias. We defined primary clinical patency as freedom from symptom aggravation with an ABI decrease >0.15 or absence of restenosis on imaging studies. Thus, restenosis without causing an ABI decrease >0.15 or related symptoms may have been undetected, and the primary patency rate may have been overestimated. Third, the duration of clinical follow-up in this study was only one year, which may be not sufficient to evaluate the efficacy of stents in iliac arteries.

In conclusion, in a multicenter prospective registry study, the EPIC™ stent demonstrated excellent immediate and 1-year efficacy and safety in patients with iliac artery disease.

SUPPLEMENTARY MATERIAL

Supplementary Table 1

The 6 domains and K-PAQ summary score in patients before EVT and after 12 months

Click here to view.^{(28K, xls)}

Notes

Funding:This study was sponsored by research grants from an investigator-sponsored study program of Boston Scientific, the Korea Health Technology R&D Project through the Korea Health Industry Development Institute (KHIDI), funded by the Ministry of Health & Welfare, Republic of Korea (No. HI17C0882 and HI16C2211), and the Cardiovascular Research Center (Seoul, Korea). Boston Scientific was not involved in the design, execution, analysis, or approval of any studies related to this publication.

Conflict of Interest:The authors have no financial conflicts of interest.

Author Contributions:

Conceptualization: Kim DY, Ko YG, Lee SJ, Ahn CM, Rha SW, Choi CU, Park JK.
Data curation: Kim DY, Ko YG, Lee SJ, Ahn CM, Rha SW, Choi CU, Park JK.
Formal analysis: Kim DY, Ko YG, Lee SJ, Ahn CM, Rha SW, Choi CU, Park JK.
Funding acquisition: Kim DY, Ko YG.
Investigation: Kim DY, Ko YG, Yoon CH, Choi SH, Min PK, Bae JW, Han JK, Park SH.
Methodology: Kim DY, Ko YG, Yoon CH, Choi SH, Min PK, Bae JW, Han JK, Park SH.
Project administration: Kim DY, Ko YG, Yoon CH, Choi SH, Min PK, Bae JW, Han JK, Park SH.
Resources: Kim DY, Ko YG, Yoon CH, Choi SH, Min PK, Bae JW, Han JK, Park SH.
Software: Kim DY, Ko YG, Yoon CH.
Supervision: Kim DY, Ko YG, Yoon CH.
Validation: Kim DY, Ko YG.
Visualization: Kim DY, Ko YG.
Writing - original draft: Kim DY, Ko YG.
Writing - review & editing: Kim DY, Ko YG, Lee SJ, Ahn CM, Rha SW, Choi CU, Park JK, Choi SH, Min PK, Bae JW, Park SH, Choi D.

ACKNOWLEDGMENTS

We would like to express our gratitude to Dr. Kyoung Im Cho, who passed away recently, for providing us with the Korean-Peripheral Artery Questionnaire (K-PAQ) and for her contribution to the K-EPIC study.

References

1. Norgren L, Hiatt WR, Dormandy JA, et al. Inter-society consensus for the management of peripheral arterial disease (TASC II). J Vasc Surg 2007;45 Suppl S:S5–67.
  PubMed
  
  CrossRef
1. Gerhard-Herman MD, Gornik HL, Barrett C, et al. 2016 AHA/ACC guideline on the management of patients with lower extremity peripheral artery disease: a report of the American College of Cardiology/American Heart Association Task Force on clinical practice guidelines. J Am Coll Cardiol 2017;69:e71–126.
  PubMed
  
  CrossRef
1. Aboyans V, Ricco JB, Bartelink ME, et al. 2017 ESC guidelines on the diagnosis and treatment of peripheral arterial diseases, in collaboration with the European Society for Vascular Surgery (ESVS): Document covering atherosclerotic disease of extracranial carotid and vertebral, mesenteric, renal, upper and lower extremity arteries. Endorsed by: the European Stroke Organization (ESO). The Task Force for the Diagnosis and Treatment of Peripheral Arterial Diseases of the European Society of Cardiology (ESC) and of the European Society for Vascular Surgery (ESVS). Eur Heart J 2018;39:763–816.
  PubMed
  
  CrossRef
1. Ko YG, Ahn CM, Min PK, et al. Baseline characteristics of a retrospective patient cohort in the Korean vascular intervention society endovascular therapy in lower limb artery diseases (K-VIS ELLA) registry. Korean Circ J 2017;47:469–476.
  PubMed
  
  CrossRef
1. Ye W, Liu CW, Ricco JB, Mani K, Zeng R, Jiang J. Early and late outcomes of percutaneous treatment of TransAtlantic Inter-Society Consensus class C and D aorto-iliac lesions. J Vasc Surg 2011;53:1728–1737.
  PubMed
  
  CrossRef
1. Kim TI, Schneider PA. Bare metal stenting of the iliac arteries. J Cardiovasc Surg (Torino) 2016;57:325–335.
  PubMed
1. Higashiura W, Kichikawa K, Kubota Y, et al. Does stent affect the configuration of the iliac artery in flexion of the hip joint? Jpn J Endovasc Interv 2004;5:22–24.
1. Tsujimura T, Iida O, Fujita M, et al. Two-year clinical outcomes post implantation of Epic^TM self-expanding nitinol stents for the aortoiliac occlusive disease in patients with peripheral arterial disease. J Atheroscler Thromb 2018;25:344–349.
  PubMed
  
  CrossRef
1. Lee JH, Cho KI, Spertus J, Kim SM. Cross-cultural adaptation and validation of the Peripheral Artery Questionnaire: Korean version for patients with peripheral vascular diseases. Vasc Med 2012;17:215–222.
  PubMed
  
  CrossRef
1. Ponec D, Jaff MR, Swischuk J, et al. The Nitinol SMART stent vs Wallstent for suboptimal iliac artery angioplasty: CRISP-US trial results. J Vasc Interv Radiol 2004;15:911–918.
  PubMed
  
  CrossRef
1. Stoeckel D, Pelton A, Duerig T. Self-expanding nitinol stents: material and design considerations. Eur Radiol 2004;14:292–301.
  PubMed
  
  CrossRef
1. Burket MW, Brodmann M, Metzger C, Tan K, Jaff MR. Twelve-month results of the nitinol astron stent in iliac artery lesions. J Vasc Interv Radiol 2016;27:1650–1656.e1.
  PubMed
  
  CrossRef
1. Clair DG, Adams J, Reen B, et al. The EPIC nitinol stent system in the treatment of iliac artery lesions: one-year results from the ORION clinical trial. J Endovasc Ther 2014;21:213–222.
  PubMed
  
  CrossRef
1. Krankenberg H, Zeller T, Ingwersen M, et al. Self-expanding versus balloon-expandable stents for iliac artery occlusive disease: the randomized ICE trial. JACC Cardiovasc Interv 2017;10:1694–1704.
  PubMed
  
  CrossRef
1. de Donato G, Bosiers M, Setacci F, et al. 24-month data from the BRAVISSIMO: A large-scale prospective registry on iliac stenting for TASC A & B and TASC C & D lesions. Ann Vasc Surg 2015;29:738–750.
  PubMed
  
  CrossRef
1. Bechter-Hugl B, Falkensammer J, Gorny O, Greiner A, Chemelli A, Fraedrich G. The influence of gender on patency rates after iliac artery stenting. J Vasc Surg 2014;59:1588–1596.
  PubMed
  
  CrossRef
1. van Kuijk JP, Flu WJ, Welten GM, et al. Long-term prognosis of patients with peripheral arterial disease with or without polyvascular atherosclerotic disease. Eur Heart J 2010;31:992–999.
  PubMed
  
  CrossRef
1. Gutierrez JA, Mulder H, Jones WS, et al. Polyvascular disease and risk of major adverse cardiovascular events in peripheral artery disease: a secondary analysis of the EUCLID trial. JAMA Netw Open 2018;1:e185239
  PubMed
  
  CrossRef