University of Groningen Chronic limb-threatening ischemia Ipema, Jetty

University of Groningen

Chronic limb-threatening ischemia

Ipema, Jetty

DOI:

10.33612/diss.170945328

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Publication date: 2021

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Ipema, J. (2021). Chronic limb-threatening ischemia: Optimizing endovascular and medical treatment. University of Groningen. https://doi.org/10.33612/diss.170945328

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3

Outcomes of the paclitaxel-eluting

Eluvia stent for long femoropopliteal

lesions in Asian patients with

predominantly chronic

limb-threatening ischemia

Vasc Med. 2021 Mar (Online ahead of print)

Steven Kum*

Jetty Ipema*

Eline Huizing

Yih K Tan

Darryl Lim

Ian YH Lok

Constantijn EVB Hazenberg

Çagdas Ünlü

The fluoropolymer-coated, paclitaxel-eluting Eluvia stent has shown promising results for the endovascular treatment of femoropopliteal artery lesions in patients with claudication. The aim of the current study was to evaluate efficacy and safety outcomes of the Eluvia stent for the treatment of long femoropopliteal lesions in Asian patients.

This is a single-center, retrospective study. The primary endpoint was primary patency at one year. Secondary outcomes were 30-days complication rate technical success, one-year freedom from clinically driven target lesion revascularization (CD-TLR), limb salvage, survival, amputation-free survival (AFS), wound healing, and clinical improvement.

A total of 64 patients with 67 femoropopliteal lesions were included; 78% suffered from diabetes and 84% had chronic limb-threatening ischemia (CLTI). Of those with ischemic wounds, 79% did not have runoff to the foot. Mean lesion length was 193 ± 128 mm and 52% was severely calcified. Primary patency at one year was 84% in the overall cohort and 91% in patients with complete lesion coverage with the Eluvia stent. Technical success was achieved in 100% of the cases and 30-day complications occurred in six patients. 12-month freedom from CD-TLR, limb salvage, survival, and AFS were 92%, 93%, 85% and 80%, respectively. In 80% of patients, complete wound healing was experienced and 84% had clinical improvement after one year.

The Eluvia stent showed promising 12-month patency and clinical results for femoropopliteal treatment in this CLTI dominant patient population with severely calcified, long lesions. Patient numbers were, however, small; larger trials are required to validate these findings. Aneurysmal change seen in some cases also needs further investigation.

Endovascular treatment is the first choice for short femoropopliteal (FP) artery lesions. However, percutaneous intervention of long FP lesions still remains challenging due to high rates of restenosis.1,2 _{Drug-eluting stents (DESs) were}

introduced to help lower neointimal hyperplasia that causes restenosis. A recent meta-analysis showed favorable results with DESs compared with balloon angioplasty and bare metal stents (BMSs) in terms of lower rates of restenosis and target lesion revascularization.3

The polymer-free, paclitaxel-eluting Zilver PTX stent (Cook Medical, Bloomington, IN, USA) was the first DES that showed good 5-year results for

the treatment of short FP lesions in patients with claudication.4 _However,

for patients with longer lesions, the Zilver PTX stent showed no superiority over BMSs or balloon angioplasty.5–7

The Eluvia (Boston Scientific, Marlborough, MA, USA) is another paclitaxel- eluting vascular stent but, unlike Zilver PTX, is coated with a fluoropolymer.8

In addition, Eluvia releases drug over a longer period of time: 12 months vs 2 months for the Zilver PTX.9,10 _{Early experience with the Eluvia stent for the}

treatment of short lesions in claudicants has shown promising results.11-13 _The

Eluvia stent was non-inferior compared with the Zilver PTX stent in 12-month primary patency and major adverse event rates, and showed significantly lower 12-month late lumen loss.11,14

Despite the good outcomes in these studies, there is limited evidence of the Eluvia stent in patients with chronic limb-threatening ischemia (CLTI) with long lesions. Therefore, the aim of the current study was to investigate the safety and efficacy of the Eluvia stent for the treatment of long FP artery lesions in an Asian patient population.

Methods

Study design and population

The study is a single-center, physician-initiated, retrospective study undertaken at Changi General Hospital, Singapore. The study was approved by the SingHealth institutional review board (IRB 2019/2493). Baseline data was collected from the electronic medical records of all patients. Procedural data was collected from the interventional report and visual assessment of the angiograms by an experienced vascular surgeon.

Inclusion criteria included consecutive patients with symptomatic peripheral arterial occlusive disease who underwent stenting with the Eluvia™ DES system for the treatment of superficial femoral or popliteal artery disease between September 2016 and October 2018. Treatment with the Eluvia stent was performed on the discretion of the operator. Excluded were patients with acute limb ischemia, common femoral artery disease, use of DES to treat in-stent restenosis, drug-coated balloon (DCB) treatment of the same segment less than one month before, and patients who were subjected to bail-out stenting with DES after simultaneous DCB treatment of the same segment (i.e. double drug).

Patients with claudication were followed up at least once every 6 months until 2 years. Patients with CLTI were seen at least every 2 weeks by a vascular surgeon who also cared for their wounds according to the local protocol, until complete wound healing was achieved. Duplex ultrasound surveillance of the FP tract was performed at 12 months. Angiography was performed in case of suspicion of clinically relevant restenosis meaning delayed or no wound healing, or deterioration of claudication, in the presence of restenosis determined by ultrasound. Ankle-brachial index or other indices of perfusion were not performed routinely as per institutional practice due to a high prevalence of calcified vessels below-the-knee.

Study device

The Eluvia stent consists of a primer layer of poly n-butylmethacrylate (PBMA). The second layer above the primer layer comprises of an active layer of

paclitaxel (at a concentration of 0.167 μg/mm2 _{stent surface area) and the}

fluoropolymer, polyvinylidene fluoride-cohexafluoropropylene (PVDF-HFP). The biocompatible fluoropolymer allows the gradual elution of paclitaxel over a 12-month period. The diameter and length range of the stent are 6–7 mm and 40–120 mm, respectively.8,10

Procedure overview

All patients received antiplatelet therapy with 100 mg of aspirin at least 7 days prior to the procedure. Dual antiplatelet therapy consisting of aspirin and clopidogrel was prescribed for 6 months after the procedure, followed by lifelong monotherapy with either one of the medications. Patients who required anticoagulation for other indications were maintained on anticoagulant agents with additional clopidogrel therapy 6 months after the procedure. Patients with aspirin allergy received lifelong clopidogrel and vice versa.

Diagnostic angiography was performed via antegrade or crossover access. Two orthogonal magnified angiographic projections of the target lesions were obtained prior to the intervention. After angiography, systemic intra-arterial heparinization was performed as per the institutional protocol.

A 0.018 or 0.035-inch guidewire was passed through the target lesion and predilatation with a balloon catheter was performed. The predilatation balloon was sized 0.5 mm less than the reference vessel diameter (RVD), which was visually assessed. Balloon was routinely inflated for a minimum of 90 seconds. If there was a suboptimal result to balloon angioplasty due to dissection or recoil of more than 50%, the patient was considered for stenting with DES. Prior to DES implantation, the vessel was again predilated with a semi-compliant balloon (Mustang™Balloon, Boston Scientific, Marlborough, MA, USA) sized 1:1 to RVD at aggressive pressures (approximating burst) to facilitate optimal stent expansion. Non-compliant balloon angioplasty was used when results were suboptimal. RVD was determined by visual assessment of the operator during the procedure and confirmed on angiographic response to predilatation. Stents were sized 1 mm larger than the RVD. Stenting of distal segments was performed before proximal segments and stents were overlapped at least 1 cm in length,

with careful consideration to avoid geographic miss. Total lesion coverage with DES was preferred and left to the discretion of the operator but not mandatory. When used in combination with a DCB, maximum overlap of 1 cm between the stent and DCB was allowed whilst ensuring that the whole lesion was covered by either DES or DCB (hybrid drug coverage). Hybrid drug coverage was used to limit the length of the stents in the target vessel. In these cases, segments that responded well to predilatation were treated with DCB and those segments with recoil after predilatation were stented with DES. A 1 cm segment of overlap between the DCB segment and the DES segment was used to avoid geographic miss which can happen due to parallel errors and ensure that the whole lesion was covered with drug. A combination with bare metal stents (BMSs) was also possible and used as bail-out in the initial experience.

Postdilatation was routinely performed with a less compliant balloon (e.g. Mustang™ Balloon, Boston Scientific, Marlborough, MA, USA) or a non-compliant balloon with a size at least equivalent to the RVD within the treated area to ensure no geographical miss.

Supplementary iliac stenting and below-the-knee therapy was performed simultaneously in the same setting if required. Coronary everolimus-eluting stents (XIENCE PRIME, Abbott vascular, Santa Clara, CA, USA) were occasionally used below-the-knee for bail-out stenting in combination with plain balloon angioplasty (POBA) but no DESs were used for the iliac arteries.

Study endpoints

The primary endpoint was one-year primary patency, defined as freedom from restenosis or occlusion on ultrasound or angiography without any clinically driven target lesion revascularization (CD-TLR) or bypass. Significant restenosis on duplex ultrasound was defined as peak systolic velocity ratio (PSVR) ≥2.4. Angiographic definition of restenosis was >50% on orthogonal views.

Secondary endpoints were 30-days complication rate, technical success, and one-year freedom from CD-TLR, limb salvage, survival, amputation-free survival (AFS), complete wound healing (full epithelization of wound), and clinical improvement. Technical success was defined as delivery and

deployment of the study stent to the target lesion to achieve residual angiographic stenosis ≤30%, assessed visually on final angiogram. Major amputation was defined as amputation above the ankle. Survival was defined as freedom from all-cause death. Clinical improvement was defined as complete wound healing, resolution of rest pain or improvement of claudication at least one Rutherford class. Clinical improvement was evaluated during outpatient follow-up visits.

Statistical analysis

Baseline characteristics and procedural information are presented as mean with standard deviation (SD) or median and interquartile range (IQR) in case of continuous data, and as numbers with percentages in case of categorical data. Kaplan-Meier (KM) analysis was performed to estimate the primary patency, freedom from CD-TLR, survival, limb salvage and AFS at 12 months. Subgroup analysis for primary patency was performed for patients with TASC C and D lesions. Also, primary patency analysis between total lesion coverage with Eluvia stents, the combination of Eluvia and DCB (hybrid drug coverage), and the combination of Eluvia and BMS or POBA, was performed. Statistical significance was defined as a p-value <0.05. Statistical analysis was performed using SPSS 26.0 software (IBM, Armonk, NY, USA).

Baseline patient and lesion characteristics

A total of 64 patients were enrolled in the study with a mean age of 70 ± 12 years. A total of 67 FP lesions were treated with 146 Eluvia stents. Three patients had bilateral treatment. Rutherford category 4 or 5 (i.e. CLTI) accounted for 84% of the limbs. Mean lesion length was 193 ± 128 mm; 48% of the lesions were occlusions and 52% were severely calcified according to the Peripheral Academic Research Consortium (PARC) classification. Before revascularization, 60% of the patients had 0 or 1 tibial runoff vessels. Table 3.1 summarizes the baseline patient and lesion characteristics.

Procedural endpoints

The mean radiologic follow-up was 11.3 ± 7.8 months. Technical success was achieved in all cases. Complications within 30 days after the intervention occurred in six patients: two patients developed a pseudoaneurysm of the groin that was managed with either compression or thrombin injection, two patients had a hematoma on the access site that did not require transfusion and were treated conservatively, one patient experienced a myocardial infarction, and one patient died from a myocardial infarction.

Primary endpoint

The primary patency at one year for the total cohort was 84%. In the subset of patients with TASC C and D lesions, primary patency was 86%. This subgroup consisted of 49% severely calcified lesions and a mean lesion length of 280 mm (± 97).

A subgroup of the total cohort with severely calcified lesions (n = 35) was also analyzed and showed a one-year primary patency of 82%.

Analyzing patients per type of lesion coverage, one-year primary patency was the highest (91%) for total lesion coverage with Eluvia stents, followed by 80% for hybrid drug coverage, and 42% for Eluvia and BMS or POBA coverage (Figure 3.1). Baseline characteristics did not differ significantly between the groups. The group with total lesion coverage included 60% TASC C and D

lesions, the hybrid group 46% and the Eluvia plus BMS or POBA group 72%. The group with total lesion coverage had, with 60%, more severely calcified lesions than the hybrid (23%) and Eluvia plus BMS or POBA groups (29%). Runoff was the poorest in the hybrid group, with 31% with zero runoff vessels, versus 9% and 0% in the total lesion coverage and Eluvia plus BMS or POBA groups, respectively. Mean lesion lengths for the subgroups were 201 ± 136 mm for the total lesion coverage group, 153 ± 86 mm for the hybrid group, and 211 ± 143 mm for the Eluvia plus BMS or POBA group. Primary patency for lesions with a length ≥150mm and total lesion coverage with Eluvia stents (n = 27) was 90% after 12 months.

Figure 3.1. Primary patency rate based on the type of lesion coverage. BMS = bare metal stent; DCB = drug-coated balloon; DES = drug-eluting stent (Eluvia); POBA = plain balloon angioplasty.

Secondary endpoints

Freedom from CD-TLR was 92% at 12 months after the index intervention. No major amputations were performed within 30 days after the procedure. Limb salvage was 93% at 12 months. Survival rate at 12 months was 85% and AFS 80%. 44 of 55 limbs with wounds (80%) experienced complete healing within

No at risk

Full DES 47 36 25

DES+DCB 13 9 7

12 months. Clinical improvement was achieved in 56 out of 67 patients (84%) in the same period.

Three patients developed aneurysmal change defined as visible absence of wall apposition to the stent exceeding the diameter of the stent. Two of these were detected at 5 and 20 months postintervention and were occluded. The other one was asymptomatic and diagnosed at 22 months after the procedure. This patient refused intervention at the time of follow-up.

Characteristic n (%)

Patients 64

Age, years, mean ± SD 70 ± 12.5

Sex (male) 38 (59)

Ischemic heart disease 26 (41)

Diabetes Mellitus 50 (78)

Hyperlipidemia 48 (75)

Hypertension 55 (86)

Dialysis dependent renal failure 11 (17)

ASA class 2 6 (9) 3 48 (75) 4 10 (16) Limbs 67 Rutherford category 3 11 (16) 4 3 (5) 5 53 (79)

Total number of lesions treated with Eluvia 67

Lesion locationa Upper SFA 40 (60) Mid SFA 48 (72) Lower SFA 45 (67) P1 35 (52) P2 25 (37) P3 20 (30)

Lesion length

Median, mm (range) 200 (20-450)

Mean ± SD, mm 193 ± 128

Total number of Eluvia stents 146

Total lesion coverage with Eluvia 47 (70)

Occlusions 32 (48) PARC classification Non 0 (0) Focal 16 (24) Mild 4 (6) Moderate 12 (18) Severe 35 (52) TASC classfication A 14 (21) B 14 (21) C 17 (25) D 22 (33)

Number of runoff vessels Pre-intervention Post-intervention

0 8 (12) 0 (0)

1 32 (48) 29 (43)

2 16 (24) 24 (36)

3 11 (16) 14 (21)

ASA = American Society of Anesthesiologists Classification; IQR = interquartile range; PARC = Peripheral Academic Research Consortium; P1 = popliteal artery segment one; P2 = popliteal artery segment two; P3 = popliteal artery segment three; SD = standard deviation; SFA = superficial femoral artery; TASC = Trans-Atlantic Inter-Society Consensus.

Discussion

The paclitaxel-eluting Eluvia stent showed good clinical and patency outcomes for the treatment of femoropopliteal artery disease in patients with claudication. The current study is the first investigating the Eluvia stent in a CLTI predominant population showing promising results for the treatment of long, severely calcified FP lesions in patients with compromised runoff.

Our patient population seemed more complex when compared to prior studies with the Eluvia stent in long (>150 mm) FP lesions. The population in the current study comprised of 84% patients with CLTI compared with 48% in the MUENSTER registry and <5% in the IMPERIAL long lesion cohort.15,16 _Besides,

the prevalence of diabetes mellitus among our study subjects was higher: 78% vs 37% in the MUENSTER registry and 40% in the IMPERIAL long lesion cohort. Furthermore, the prevalence of renal insufficiency and dialysis-dependent renal failure reported in the previous studies was 5-6%, compared to 17% dialysis- dependent renal failure in ours.

Besides differences in patient population, lesion complexity also varied. Severely calcified lesions were reported in 52% of our patients, similar to the 42% moderate/severe calcification noted in the MUENSTER registry, but was higher than the 28% in the IMPERIAL long lesion cohort. In addition, our study had more mid and distal popliteal involvement compared with the other studies; close to 30% of our lesions involved the mid to distal popliteal artery. The degree of runoff vessels to the foot was also poorer in our study when compared to the MUENSTER registry; only 40% had ≥2 runoff vessels versus 80% reported in the MUENSTER registry. In addition, for patients in our study with ischemic wounds 79% did not have direct flow to the foot on preintervention angiogram. However, the number of total occlusions was higher in the MUENSTER registry.

Despite a more complex patient population, a larger proportion of CLTI with poorer runoff, primary patency and freedom from CD-TLR rates are comparable to those in the MUENSTER registry and IMPERIAL long lesion cohort. It is important to note however that the MUENSTER registry used a more stringent duplex criteria to define primary patency (PSVR ≤2.0) whereas we used a PSVR

of ≤2.4 in line with the IMPERIAL study.

Compared with the Zilver PTX stent, patency and freedom from CD-TLR rates in our study are higher than most results reported on the Zilver PTX stent.5,6,17–19

Whereas a direct comparison cannot be made, since this is not a randomized trial, the results are in line with the IMPERIAL trial, that showed significantly higher patency and lower major adverse event rates with Eluvia compared with Zilver PTX in claudicants.12

Another interesting finding is that total lesion coverage was achieved in 70% of the lesions with a corresponding patency rate of 91% in these lesions. This patency rate was better compared with hybrid drug coverage with the Eluvia stent and DCB or the combination of Eluvia and BMS or POBA, while the total lesion coverage group had the highest proportion of severely calcified lesions. This seems to suggest that total lesion coverage with prolonged controlled drug elution combined with a stent scaffold could be a viable solution in long calcified lesions. However, due to the small numbers and retrospective study design, no inference can be made and this is hypothesis generating at best. The respectable patency results could also be explained by the aggressive pre- and postdilatation in all patients. The importance of standardized vessel preparation has been described before.20,21

Regarding safety of the Eluvia for treating FP lesions, aneurysm formation was reported in three patients in our study (4.5%). This was first reported in

the MUENSTER registry with a prevalence of 8%.16 _{All three patients in the}

current study had full lesion coverage with Eluvia stents. Two of them had occluded stents while the stent was still patent in the third patient. The risk of aneurysmal formation due to drug elution has to be further explored.

This study has some limitations. The major one is the retrospective study design. Due to this there was heterogeneity in the follow-up schedule. Besides, no routine duplex ultrasound or angiography follow-up of the patency of the below-the-knee vessels was performed as per institutional protocol, however, this was also not recommended by guidelines.22,23 _{Furthermore, clinical improvement was}

not reported in a standardized way by questionnaires, but was obtained from reports during outpatient visits. Another limitation is that during the study period Eluvia was chosen randomly by different operators which could be a source of

bias. Due to a shortage of long Eluvia stents, many patients received more than one Eluvia stent to fully cover the lesion. On the other hand, this reflects daily clinical practice and therefore shows results from real-world practice. Further, our study did not have a control arm and therefore extrapolation of study results and its comparison with other studies should be done cautiously. We carried out a subgroup analysis for the type of lesion coverage, however, the number of patients in each group was small to draw firm conclusions.

Conclusion

In conclusion, this study demonstrated promising one-year stent patency and clinical outcomes with the Eluvia stent in severely calcified, long FP lesions in patients with predominantly CLTI and poor runoff. Owing to the non-comparative retrospective study design and small subgroups, a well-powered prospective study is needed to validate our study findings. Presumptive aneurysmal change on duplex ultrasound, defined as visible absence of wall apposition to the stent exceeding the diameter of the stent on transverse section, in a minority of cases should be subject of further systematic investigations.

Declaration of conflicting interests

The authors declared the following potential conflicts of interest with respect to the research, authorship, and/or publication of this article: S Kum and CEVB Hazenberg are consultants to Boston Scientific. The other authors report no relevant disclosures.

Funding

The authors received an educational grant for travel from Boston Scientific. Boston Scientific had no role in the study design; collection, analysis, and interpretation of data; writing of the manuscript; and there were no restrictions regarding publication.

References

1. Muradin GS, Bosch JL, Stijnen T, et al. Balloon Dilation and Stent Implantation for Treatment of

Femoropopliteal Arterial Disease: Meta-Analysis. Radiology. 2001;221:137-145.

2. Mwipatayi BP, Hockings A, Hofmann M, et al. Balloon Angioplasty Compared With Stenting for Treatment of Femoropopliteal Occlusive Disease: A Meta-Analysis. J Vasc Surg. 2008;47:461-469.

3. Zhou Y, Zhang Z, Lin S, et al. Comparative Effectiveness of Endovascular Treatment Modalities for De Novo Femoropopliteal Lesions: A Network Metaanalysis of Randomized Controlled Trials. J Endovasc Ther. 2020;27:42-59.

4. Dake MD, Ansel GM, Jaff MR, et al. Durable Clinical Effectiveness With Paclitaxel-Eluting Stents in the Femoropopliteal Artery. Circulation. 2016;133:1472-1483.

5. Iida O, Takahara M, Soga Y, et al. 1-Year Results of the ZEPHYR Registry (Zilver PTX for the Femoral Artery and Proximal Popliteal Artery). JACC Cardiovasc Interv. 2015;8:1105-1112. 6. Davaine J-M, Querat J, Kaladji A, et al. Treatment of TASC C and D Femoropopliteal Lesions with

Paclitaxel eluting Stents: 12 month Results of the STELLA-PTX Registry. Eur J Vasc Endovasc Surg. 2015;50:631-637.

7. Vent PA, Kaladji A, Davaine J-M, et al. Bare Metal Versus Paclitaxel-Eluting Stents for Long Femoropopliteal Lesions: Prospective Cohorts Comparison Using a Propensity Score - Matched Analysis. Ann Vasc Surg. 2017;43:166-175.

8. Müller-Hülsbeck S. Eluvia peripheral stent system for the treatment of peripheral lesions above the knee. Expert Opin Drug Deliv. 2016;13:1639-1644.

9. Dake MD, Alstine Van WG, Zhou Q, et al. Polymer-free paclitaxel-coated Zilver PTX Stents— evaluation of pharmacokinetics and comparative safety in porcine arteries. J Vasc Interv Radiol. 2011;22:603-610.

10. Eluvia Drug-Eluting Vascular Stent System. https://www.bostonscientific.com/en-US/ products/stents--vascular/eluvia-drug-eluting-stent-system/sustained-drug-release.html. Accessed June 4, 2020.

11. Gray WA, Keirse K, Soga Y, et al. A Polymer-Coated, Paclitaxel-Eluting Stent (Eluvia) Versus a Polymer-Free, Paclitaxel-Coated Stent (Zilver PTX) for Endovascular Femoropopliteal Intervention (IMPERIAL): A Randomised, Non-Inferiority Trial. Lancet. 2018;27:1541-1551. 12. Soga Y, Fujihara M, Iida O, et al. Japanese Patients Treated in the IMPERIAL Randomized Trial

Comparing Eluvia and Zilver PTX Stents. Cardiovasc Interv Radiol. 2020;43:215-222. 13. Müller-Hülsbeck S, Keirs K, Zeller T, et al. Twelve-Month Results From the MAJESTIC Trial of

the Eluvia Paclitaxel-Eluting Stent for Treatment of Obstructive Femoropopliteal Disease. J Endovasc Ther. 2016;23:701-706.

14. Soga Y, Fujihara M, Tomoi Y, et al. One-Year Late Lumen Loss between A Polymer-Coated Paclitaxel-Eluting Stent (Eluvia) and a Polymer-Free Paclitaxel-Coated Stent (Zilver PTX) for Femoropopliteal Disease. J Atheroscler Thromb. 2020;27:164-171.

15. Golzar J, Soga Y, Babaev A, et al. Effectiveness and Safety of a Paclitaxel- Eluting Stent for Superficial Femoral Artery Lesions up to 190 mm: One-Year Outcomes of the Single-Arm

IMPERIAL Long Lesion Substudy of the Eluvia Drug-Eluting Stent. J Endovasc Ther. 2020;27:296-303.

16. Bisdas T, Beropoulis E, Argyriou A, et al. 1-Year All-Comers Analysis of the Eluvia Drug-Eluting Stent for Long Femoropopliteal Lesions After Suboptimal Angioplasty. JACC Cardiovasc Interv. 2018;11:957-966.

17. Yokoi H, Ohki T, Kichikawa K, et al. Zilver PTX post-market surveillance study of paclitaxel- eluting stents for treating femoropopliteal artery disease in Japan: 12-month results. J Am Coll Cardiol Intv. 2016;9:271-277.

18. Zeller T, Rastan A, Macharzina R, et al. Drug-Coated Balloons vs. Drug-Eluting Stents for Treatment of Long Femoropopliteal Lesions. J Endovasc Ther. 2014;21:359-368.

19. Bosiers M, Peeter P, Tessarek J, et al. The Zilver® PTX® Single Arm Study: 12-month Results From the TASC C/D Lesion Subgroup. J Cardiovasc Surg. 2013;54:115-122.

20. Barbato E, Shlofmitz E, Milkas A, et al. State of the art: Evolving concepts in the treatment of heavily calcified and undilatable coronary stenoses - from debulking to plaque modification, a 40-year-long journey. EuroIntervention. 2017;13:696-705.

21. Varcoe RL, Thomas SD, Rapoza RJ, et al. Lessons learned regarding handling and deployment of the Absorb bioresorbable vascular scaffold in infrapopliteal arteries. J Endovasc Ther. 2017;24:337-341.

22. Aboyans V, Ricco J-B, Bartelink M-L EL, et al. Editor’s Choice 2017 ESC Guidelines on the Diagnosis and Treatment of Peripheral Arterial Diseases, in collaboration with the European Society for Vascular Surgery (ESVS). Eur J Vasc Endovasc Surg. 2018;55:305-368.

23. Gerhard-Herman MD, Gornik HL, Barrett C, et al. 2016 AHA/ACC Guideline on the Management of Patients With Lower Extremity Peripheral Artery Disease: Executive Summary. A Report of the American College of Cardiology/American Heart Association Task Force on Clinical Practice Guidelines. Circulation. 2017;135:e686-e725.