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Advances in Interventional Cardiology/Postępy w Kardiologii Interwencyjnej
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2/2018
vol. 14
 
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Original paper

Two-year clinical outcomes after implantation of an everolimus-eluting bioresorbable scaffold (Absorb) in stable angina and acute coronary syndrome patients. Single-centre real-life registry data

Ieva Briede
,
Inga Narbute
,
Indulis Kumsars
,
Dace Sondore
,
Karlis Trushinskis
,
Sanda Jegere
,
Gustavs Latkovskis
,
Karlis Strenge
,
Ainars Rudzitis
,
Andrejs Erglis

Adv Interv Cardiol 2018; 14, 2 (52): 144–148
Online publish date: 2018/06/19
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Introduction

In recent years, second-generation drug-eluting stents (DES) have demonstrated improved efficacy and safety over first-generation DES. Nonetheless, even current generation DES are limited by late adverse events, including stent thrombosis and restenosis [1, 2]. Bioresorbable vascular scaffolds (BVS) are transient devices that, like metallic stents, prevent acute closure of coronary vessels and with the eluting drug eliminate neointimal proliferation. Permanent implantation of metal and polymers in the vessel wall can provoke inflammation, endothelial dysfunction, ongoing tissue growth within the stent frame, and neoatherosclerosis. To reduce these late clinical consequences, fully bioresorbable scaffolds that also elute antiproliferative drugs were developed [3]. The first generation BVS Absorb (Abbott Vascular, Abbott Park, Illinois) showed acceptable results in the first clinical testing [4]. The latest publications have drawn attention to the possible increase in scaffold thrombosis with BVS compared to the gold standard DES [5, 6]. Some registries showed safe and successful BVS implantation in the acute coronary syndrome patient population [7]. Scaffold thrombosis was associated with lesion selection and implantation technique failure. In our registry we wanted to collect real-life data from our single centre and analyse patients’ outcomes after BVS implantation at mid-term follow-up.

Aim

The aim of this long-term registry analysis was to evaluate 2-year clinical and angiographic outcomes after implantation of everolimus-eluting bioresorbable scaffolds (Absorb) from the Centre of Cardiology Real-life Registry.

Material and methods

Between November 2012 and December 2014 in the Centre of Cardiology, 250 patients with documented stable angina and/or acute coronary syndrome received a BVS and were included in the registry. The coronary vessel reference diameter by visual estimate had to be ≤ 4.0 mm and ≥ 2.5 mm to be eligible for BVS implantation. Of the 450 patients who were included in the registry between November 2012 and January 2017, 250 patients were included in the registry between 2012 and 2014. From them, 50 patients have left main bifurcation treatment and were excluded from the data analysis. Finally 187 patients were selected for data analysis because these patients reached 2-year clinical follow-up. Dual antiplatelet therapy (DAPT) was prescribed at least for 12 months for all patients. At 2 years, patients received a phone call follow-up visit. Seven patients were lost to follow-up. Angiographic follow-up was available in 46.0% (82/178) of patients. Angiographic follow-up mostly was available due to staged treatment of another coronary lesion or if the patient had angina symptoms with a positive treadmill stress test. All clinical and angiographic data at baseline and at follow-up were collected in one database. Main endpoints of the database analysis included rates of major adverse cardiac events (MACE): all-cause death, myocardial infarction, cerebral infarction, coronary artery bypass (CABG), major bleeding, scaffold thrombosis, in-scaffold restenosis, target lesion revascularization (TLR), target vessel revascularization (TVR). Scaffold thrombosis was categorized as acute if < 1 day, sub-acute if 1-30 days and late if > 30 days [8].

Statistical analysis

Statistical analyses were performed using SPSS version 24.0 software (IBM SPSS, Corp., Armonk, NY). Continuous variables were expressed as mean and standard deviation (SD).

Results

From all patients included between November 2012 and December 2014 in the Centre of Cardiology Real-life Registry, 187 patients with stable angina and acute coronary syndrome and 2-year follow-up were selected. Coronary lesion types were A, B and C according to the ACC/AHA classification. Main coronary lesion types were A and B [9].

Patient demographics

Baseline clinical characteristics for all patients are shown in Table I. Mean patient age was 56.74 ±11.85 years. Male gender was 78.6%. The majority of patients, 79.1%, presented with stable angina. In the acute coronary syndrome patient group, ST-segment elevation myocardial infarction (STEMI) represented 9.6% of patients, non-STEMI 3.2% and unstable angina 5.9%. 41.2% of patients had documented previous percutanous coronary intervention (PCI) with stent implantation.

Lesion characteristics and procedural details

Lesion characteristics and procedural details are shown in Table II. Multi-vessel disease was noted in 61.5% of patients and true bifurcation lesions in 14.9%. Bioresorbable vascular scaffolds implantation in 49.7% was performed in the left anterior descending (LAD) coronary artery, 25.1% in the right coronary artery (RCA) and 14.4% in the left circumflex (LCX) artery. Lesions were mostly localized proximally and in the middle segment of the artery, 65.8% and 60.4% respectively. Procedural characteristics are shown in Table III. Pre-dilatation was done in almost all cases (92.5%); in 49.7% a plaque modification technique with a cutting balloon was used, and in 50.3% pre-dilatation was done with a regular balloon (1 : 1 ratio). The mean scaffold length treated was 20.10 ±6.48 mm and 3.17 ±0.36 mm for the treated mean vessel diameter. Post-dilatation was performed in 92.5% of cases with mean post-dilatation balloon diameter 3.46 ±0.41 mm with maximal pressure used 17.11 ±3.34 atm.

Clinical outcomes

Patient clinical and angiographic outcomes are shown in Table IV. Results are shown for all patients and separated by groups for stable angina (n = 187) and acute coronary syndrome (n = 29). Two patient deaths were recorded during the hospitalization period. One death occurred in the acute coronary syndrome group (3.4%; 1/29), not association with scaffold thrombosis. The patient died due to progression of acute heart failure during myocardial infarction. The second hospital death was in the stable angina group and was associated with acute scaffold thrombosis. Unfortunately, the scaffold thrombosis occurred due to clopidogrel resistance (vasodilator-stimulated phosphoprotein analyses – VASP); a standardized flow cytometric assay test was positive. From 187 patients, 7 (3.8%) were lost to follow-up. All other patients (96.2%) reached 2-year clinical follow-up. All-cause death (cancer, cerebrovascular, unknown) was 3.9% (7/178). Myocardial infarction during follow-up occurred in 1.6% (3/178) of patients. Definite sub-acute scaffold thrombosis occurred in 1 patient (0.5%; 1/178), 5 days after scaffold implantation. The patient presented with STEMI with thrombotic occlusion of the first diagonal branch where a 2.5 mm × 18 mm BVS had been previously implanted. He was treated with plain old balloon angioplasty (POBA) and scaffold optimization. Twelve-month DAPT was prescribed with aspirin and ticagrelor. After that, the patient reached 2-year follow-up without any other clinical event.
Angiographic in-scaffold restenosis was recorded in 6% (5/82) of patients. Treated in-scaffold restenosis occurred in 4.8% (4/82) of patients with clinically positive angina symptoms. At 2 years, TLR occurred in 3.9% (7/178) of patients. Target vessel revascularization was performed in 8.4% (15/178) of patients.

Discussion

Bioresorbable vascular scaffolds is relatively new in interventional cardiology. First generation BVS in simple de-novo lesions has been proven to be almost as good as DES with comparable MACE event rates (ABSORB, ABSORB II) and in all comer registries as in the retrospective registry GHOST-EU, the target lesion failure rate (TLF) at 1 year was very acceptable given the lesion and patient complexity; however, an increase in early ST was noted [10, 11]. The ABSORB III trial demonstrated that the scaffold was non-inferior to the Xience stent with respect to target lesion failure at 1 year [12]. Absorb II 3-year BVS outcomes showed that treatment with BVS was associated with a higher scaffold thrombosis (3%) rate compared with the newest generation DES [5]. Sotomi et al. conducted pre- and post-procedural intravascular ultrasound (IVUS) matching analysis from the Absorb II trial, analysing pre-procedural minimal lumen area (MLA). They concluded that to achieve equivalent acute gain in the Absorb compared to the Xience, implantation of the scaffold may require more aggressive strategies for pre- and post-dilation and implantation than the technique used in the ABSORB II trial [13]. Three-year clinical outcomes of the ABSORB China randomized trial were recently published. They concluded that BVS and Cobalt-Cromium Everolimus-eluting metallic stents (CoCr-EES) had similar results up to 3-year follow-up, at which time the scaffold has completely resorbed. Definite/probable ST 0.9% vs. 0.0% (p = 0.50) [14].
Our centre’s real-life registry of 2-year data shows comparable results with the current gold standard. As described before in the literature, in the “Predilatation-Sizing-Postdilatation (PSP) implantation technique” of BVS, the most important steps are vessel preparation before BVS, appropriate sizing and post-dilatation of the scaffold to optimize the result. Nevertheless, our centre’s local recommendations have required that “PSP” be performed for all stent/scaffold interventions for the last few years. For this particular BVS cohort, pre-dilatation and post-dilatation was done in 92.5%, which resulted in good mid-term outcomes. Same local centre recommendations include usage of GPIIb/IIIa receptor blockers. In this particular data registry we used GPIIb/IIIa in 59.9% (n = 112) of cases, due to the long procedure time or long target lesion treatments where more than one stent/scaffold implantation were needed. High rate of the radial approach and cutting balloon predilatation as in our centre’s practice requires GPIIb/IIIa administration with low bleeding risk and low scaffold thrombosis rates.
The use of imaging techniques such as IVUS and/or optical coherence tomography (OCT) in BVS implantation could be critical to achieve good long-term results. In more complex PCI cases where BVS is used, our centre’s strategy is “I-PSP” – Imaging, Pre-treatment, Sizing, Post-dilatation.
Stable angina patients at our centre receive standard DAPT therapy after PCI: aspirin and clopidogrel 6 to 12 months. Our registry experience with one acute scaffold thrombosis due to clopidogrel resistance changed our strategy for stable angina patients to more aggressive and longer DAPT usage, at-least 1-month ticagrelor continuously up to 12–24 months. Nevertheless, in total 450 patients were included in this registry and more precise data will be reported when patients reach more than 2-year follow-up.
A limitation of this real-life registry could be that the cohort did not reach the complete follow-up, yet the follow-up rate was quite high at 96.2%. The imaging techniques IVUS and OCT were used only in 17.1% and 16.6% of cases, mostly during complex lesions, but they should be used more. Another limitation is that this is single-centre evaluation with no adjudication of events. As this is a real-life registry, no angiographic follow-up was required, which might have led to biased results regarding TLR.

Conclusions

Our single-centre, real-life BVS registry data show a relatively low rate of MACE and scaffold thrombosis at mid-term 2-year clinical follow-up in stable angina and acute coronary syndrome patients. These results are comparable with current gold standards and show that BVS implantation could be safe.

Acknowledgments

This registry was supported in part by the National Research Program “Biomedicine for Public Health” (BIOMEDICINE) and by a grant from the corporation “Sistemu Inovacijas”.

Conflict of interest

One author has received consultancy fees, a research grant to the institution from Abbott Vascular, Boston Scientific, Biosensors, Cordis J&J, Medtronic. Other authors declare no conflict of interest.

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