Journal List > Korean Circ J > v.47(6) > 1017541

Ahn, Park, Hong, Ahn, Hahn, Kim, Hong, Nam, Kang, Lee, Chun, Heo, Cho, Kim, Her, Kim, Yoo, Hong, Tahk, Kim, Kim, Jang, and Park: Bioresorbable Vascular Scaffold Korean Expert Panel Report

Abstract

Bioresorbable vascular scaffold (BRS) is an innovative device that provides structural support and drug release to prevent early recoil or restenosis, and then degrades into nontoxic compounds to avoid late complications related with metallic drug-eluting stents (DESs). BRS has several putative advantages. However, recent randomized trials and registry studies raised clinical concerns about the safety and efficacy of first generation BRS. In addition, the general guidance for the optimal practice with BRS has not been suggested due to limited long-term clinical data in Korea. To address the safety and efficacy of BRS, we reviewed the clinical evidence of BRS implantation, and suggested the appropriate criteria for patient and lesion selection, scaffold implantation technique, and management.

INTRODUCTION

Bioresorbable vascular scaffold (BRS) is an innovative device that provides structural support and drug release to prevent early recoil or restenosis, and then degrades into nontoxic compounds to avoid late complications related with metallic drug-eluting stents (DESs). BRS has several putative advantages including early restoration of physiological processes, superior conformability, beneficial edge-vascular response and suppression of late-stent malapposition.1) In addition, 5-years follow-up of BRS showed late lumen enlargement and restoration of vasomotor response and suggested a possible plaque stabilizing effect.2)3)4) However, recent randomized trials and registry studies raised clinical concerns about the safety and efficacy of first generation BRS. They showed that higher rate of procedural related myocardial infarction (MI), and scaffold thrombosis compared with metallic DES.5)6) Thus, at March 2017, the US Food and Drug Administration (FDA) warned physicians that treating patients with first generation BRS.
BRS has been commercially available in Korea since January 2016, and as of August 2017, about 2,800 BRSs were implanted. However, the general guidance for the optimal practice with BRS has not been suggested due to limited long-term clinical data in Korea. Therefore, at 4th August 2017, 18 Korean heart centers combined efforts to address clinical issues raised by previous studies. We reviewed the clinical evidence of BRS implantation, and suggested the appropriate criteria for patient and lesion selection, scaffold implantation technique, and management. The scope of this document is limited to the Absorb Bioresorbable Vascular Scaffold (Absorb BRS; Abbott Vascular, Abbott Park, IL, USA), which is the only available BRS in Korea.

DEVICE DESCRIPTION

The Absorb BRS (Abbott Vascular) consists of a 157-μm-thick bioresorbable poly (L-lactide) scaffold with a 7-μm-thick bioresorbable poly (D,L-lactide) coating, which elutes everolimus (7). About 80% of the drug elutes in the first 30 days, and the remainder elutes over 120 days. Scaffold are fully bioresorbable, with complete bioresorption expected by approximately 24 to 36 months. The initial reduction in molecular weight, the decrease in radial support occurs at approximately equal to 6 months, and finally the loss in mass starts at 12 months (Figure 1).8) To compared with metallic DESs, BRS has less acute gain, and smaller lumen area. In addition, it has a limited expansion capability. Experimental in-vitro study indicated the fracture threshold was +1.0 mm. Overexpansion beyond this threshold can lead to strut disconnections and focal loss of mechanical support.9)
Figure 1
Scaffold biodegradation. (A) Hydrolysis randomly cleaves amorphous tie chains, leading to a decrease in molecular weight without altering radial strength. (B) When enough tie chains are broken, the device begins losing radial strength. After 2–3 years, BRS was fully bioresorbed.
BRS = bioresorbable vascular scaffold.
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CURRENT EVIDENCE

Early pilot trials

The ABSORB cohort A and B experiences provided objective characterization of BRS resorption and coronary healing process in humans.10)11) Serial intravascular imaging studies showed that strut resorption and vascular healing after BRS implantation were associated with late lumen enlargement.2) The formation of a neointima layer after BRS resorption suggested to seal or “cap” the necrotic core plaque, and to prevent plaque rupture in the future.3) In addition, the restoration of vasomotor response to stimuli was demonstrated by 5 years.4) Early promising results called for clinical comparison studies with standard metallic DES.

Randomized trials

ABSORB II is the first randomized controlled trial to compare Absorb BRS with everolimus-eluting stent (EES) in 501 patients.1) The primary endpoint was angiographic vasomotor reactivity after nitrate injection and angiographic late luminal loss. At 1 year, first new or worsening angina was lower with BRS, although clinical outcomes were similar between groups. However, at 3-year follow-up, the vasomotor reactivity, angina status, and exercise capacity were not different. In addition, the late luminal loss was larger in the BRS group. The rate of a device-oriented composite endpoint (DOCE) was significantly higher in the BRS group, mainly driven by target vessel MI. Definite or probable device thrombosis was also significantly higher in the BRS group (Figure 2).5)
Figure 2
A case of acute scaffold thrombosis. (A) Baseline coronary angiography, (B) after Absorb 3.0×23 mm BRS implantation, (C) follow-up coronary angiography due to chest pain with ST elevation after 7 hours, (D) OCT showing acute scaffold thrombosis with underexpansion and malapposition, (E) final angiography after high-pressure balloon dilatation, and (F) final OCT image showing well-apposed scaffold.
BRS = bioresorbable vascular scaffold; OCT = optical coherent tomography.
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ABSORB III is the first large-scale, multicenter, randomized trial for US FDA regulatory approval.7) This study enrolled 2,008 patients with relatively simple coronary lesions. This study demonstrated that the BRS group was non-inferior to the EES group in the respective to target lesion failure (TLF) at 1-year. However, the 2-year results presented at American College of the Cardiology (ACC) 2017 that the rates of TLF were significantly higher in the BRS group due to the increased risk of target vessel MI in the BRS group. However, ABSORB China and ABSORB Japan at EuroPCR 2017 showed that BRS had comparable safety and efficacy to EESs at 3 years.
Recently, the Amsterdam Investigator-initiateD Absorb Strategy (AIDA) study reported early because of the higher incidence of device thrombosis in the BRS group.6) This study enrolled 1,845 patients with more complex lesion subset than ABSORB III trial in the context of routine clinical practice: acute coronary syndrome (ACS) was 54% and small vessel disease was about 20%. In addition, postdilatation (74%) was still underused. Although target vessel failure (TVF) was not significantly different, device thrombosis, and subsequently target vessel myocadial infarction were significantly higher in the BRS group. Table 1 summarized currently available randomized trials.
Table 1

Summary of randomized trials with the Absorb BRS

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Clinical trial No. of patients (BRS:DES) Primary endpoint Primary outcome DOCE rate (BRS vs. DES) Scaffold thrombosis rate (BRS vs. DES)
ABSORB II1) 501 (335:166) Vasomotor reactivity/angiographic lumen loss at 3 years 0.47 mm vs. 0.56 mm (p=0.49)/0.37 mm vs. 0.25 mm (pnon-inferiority=0.78) 5% vs. 3% (p=0.35) 0.9% vs. 0% (p=0.55)
ABSORB III7) 2,008 (1,322:686) Target-lesion failure at 1 year 7.8% vs. 6.1% (p=0.16, pnon-inferiority=0.007) Same as primary outcome 1.5% vs. 0.7% (p=0.13)
ABSORB Japan42) 400 (266:134) Target-lesion failure at 1 year 4.2% vs. 3.8% (pnon-inferiority<0.0001) Same as primary outcome 1.5% vs. 1.5% (p>0.99)
ABSORB China43) 480 (241:239) In-segment lumen loss at 1 year 0.19 mm vs. 0.13 mm (p=0.01) 3.4% vs. 4.2% (p=0.62) 0.4% vs. 0% (p>0.99)
EVERBIO II64) 240 (80:160) Late lumen loss at 9 months 0.28±0.39 mm vs. 0.25±0.36 mm (p=0.30) 12% vs. 9% (p=0.6) 1.3% vs. 0%
TROFI II65) 191 (95:96) Healing score at 6 months 1.74 vs. 2.80 (pnon-inferiority<0.001) 1.1% vs. 0% 1.1% vs. 0%
AIDA6) 1,845 (924:921) Target-vessel failure at 2 years 11.7% vs. 10.7% (p=0.43) 10.3% vs. 8.9% (p=0.31) 3.5% vs. 0.9% (p<0.001)
AIDA = Amsterdam Investigator-initiated Absorb Strategy; BRS = bioresorbable vascular scaffold; DES = drug-eluting stent; DOCE = device-oriented composite endpoint; EVERBIO = Comparison of Everolimus- and Biolimus-Eluting Coronary Stents with Everolimus-Eluting Bioresorbable Vascular Scaffold; TROFI II = Comparison of the ABSORB Everolimus Eluting Bioresorbable Vascular Scaffold System With a Drug-Eluting Metal Stent (Xience™) in Acute ST-Elevation Myocardial Infarction.
Update meta-analysis of 2-year outcomes from 7 randomized trials showed that BRS had higher 2-year risk of the DOCE than EES.12) This difference was mainly derived from target vessel MI and ischemic-driven target lesion revascularization (TLR). In addition, device thrombosis was significantly higher in the BRS group. However, cardiac mortality was not different between groups (Figure 3).
Figure 3
Meta-analysis from 7 randomized trials: 2 year outcomes.
BRS = bioresorbable vascular scaffold; CI = confidence interval; EES = everolimus-eluting stent; RR = relative risk; TLR = target lesion revascularization; TV-MI = target vessel myocardial infarction.
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Registry studies

The Gauging coronary Healing with bioresorbable Scaffolding plaTforms in EUrope (GHOST-EU) registry evaluated the performance of the Absorb BRS in a real-world practice from 10 European heart centers.13) The incidence of TLF was 2.2% at 30 days and 4.4% at 6 months. However, definite or probable scaffold thrombosis was 1.5% at 30 days and 2.1% at 6 months. ABSORB expand registry reported that 12-month clinical outcomes in the first 512 patients.14) At one year, the ischemia-driven TVF was 4.9%. The cumulative rate of definite and probable scaffold thrombosis for this population was 0.8%. A Prospective, Randomized Trial of Bioresorbable Vascular Scaffold Versus Everolimus Eluting Stent in Patients Undergoing Coronary Stenting for Myocardial Infarction (ISAR-ABSORB MI) registry enrolled more complex population with diabetes (31.5%), ACS (39.0%), and bifurcation (13.1%).15) At 2 years, the composite of death, MI, or TLR occurred in 21.6%. Definite scaffold thrombosis occurred in 3.8%. This study showed the higher event rates than expected, which raised concerns about the daily use of BRS. The Registro Absorb Italiano (RAI) registry enrolled 1,505 patients (22.4% diabetes, 59.6% ACS) from 23 Italian heart centers16). All lesions were predilated and 96.8% lesions were post-dilated after BRS implantation. At 30 days, TLR occurred in 0.6% and definite or probable scaffold thrombosis occurred in 0.8%. This registry suggested that when accurate BRS implantation technique was used, an unrestricted BRS use would be safe and effective.17)18)19)20)21) In addition, BRS was evaluated in the complex patients and lesions subset including diabetes,22) ACS,23)24)25) MI,26)27)28)29)30)31)32)33) small vessel,34) and in-stent restenosis.35)36)37) However, the interpretation of such studies should be careful considering the biased nature of registry studies. Table 2 summarized currently available registry studies.
Table 2

Summary of registry studies with the Absorb BRS

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Trial/author Study design Population/lesion subset No. of patients Duration of follow-up Composite endpoint (%) MI (%) TLR (%) Definite/probable ST (%)
Absorb cohort A10) Multi-center, prospective Non-complex 30 5 years MACE: 3.4 3.4 3.4 0
Absorb cohort B11) Multi-center, prospective Non-complex 101 5 years MACE: 11 3.0 11 N/A
GHOST-EU13) Multi-center, retrospective All-comers 1,189 6 months TLF: 4.4 2.0 2.5 2.1
Absorb EXTEND14) Multi-center, prospective All-comers 512 1 year MACE: 4.3 2.9 1.8 0.8
ISAR-ABSORB MI15) Multi-center, prospective All-comers 419 2 years MACE: 21.6 3.9 16.0 3.8
Prospective RAI16) Multi-center, prospective All-comers 1505 30 days DOCE: 1.0 2.0 0.6 0.8
ASSURE17) Multi-center, prospective All-comers 183 12 months MACE: 5.0 1.7 2.8 0
MICAT18) Multi-center, retrospective All-comers 1305 485 days N/A N/A N/A 3.0
AMC single centre real world PCI registry19) Single-center, prospective All-comers 135 6 months TVF: 8.5 3.0 6.3 3.0
Polish national registry20) Multi-center, retrospective All-comers 468 12 months MACE: 3.0 1.7 N/A 0.4
BVS Expand21) Single-center, prospective All-comers 249 18 months MACE: 6.8 5.2 4.0 1.9
Muramatsu et al.22) Pooled analysis of ABSORB, SPIRIT trials DM 102 1 year DOCE: 3.9 2.9 2.0 1.0
POLAR ACS23) Multi-center, prospective ACS 100 1 year MACE: 4.0 1.0 1.0 1.0
Gori et al.24) Single-center, prospective ACS 150 1 month MACE: 10.7 4.0 N/A 2.7
BVS registry Göttingen25) Single-center, prospective Mainly ACS 195 834 days DOCE: 15.4 6.7 4.6 2.6
Kajiya et al.26) Single-center, prospective STEMI 11 53 days MACE: 9.1 0 0 0
Prague 1927) Multi-center, prospective STEMI 40 6 months MACE: 5.0 N/A N/A N/A
Wiebe et al.28) Single-center, prospective STEMI 25 6 months MACE: 8.3 4.2 0 0
BVS STEMI first29) Single-center, prospective STEMI 49 30 days DOCE: 2.6 0 0 0
BVS-EXAMINATION30) Multi-center, retrospective STEMI 290 1 year DOCE: 4.1 2.1 1.7 2.4
RAI registry31) Multi-center, prospective STEMI 122 6 months POCE: 4.9 4.1 4.1 2.5
Kochman et al.32) Single-center, prospective STEMI 23 229 days N/A 4.3 4.3 4.3
Chakraborty et al.33) Single-center, prospective STEMI 35 11.5 months N/A 0 0 0
Diletti et al.34) Substudy of Absorb cohort B Small vessel 41 2 years MACE: 7.3 4.9 2.4 0
Ielasi et al.35) Multi-center, retrospective ISR 25 7 months MACE: 8.0 4.0 8.0 0
Moscarella et al.36) Multi-center, prospective ISR 83 7 months MACE: 12.0 N/A 7.7 2.4
RIBS-VI37) Multi-center, prospective ISR 141 1 year MACE: 12.8 2.8 11.3 0.7
ACS = acute coronary syndrome; AMC = Academic Medical Center; ASSURE = An Absorb post-marketing surveillance registry to monitor the everolimus-eluting bioresorbable vascular scaffold in patients with coronary artery disease; BRS (BVS) = bioresorbable vascular scaffold; DM = diabetes mellitus; DOCE = device-oriented composite endpoint; GHOST-EU = Gauging coronary Healing with bioresorbable Scaffolding plaTforms in EUrope; ISAR-ABSORB MI = A Prospective, Randomized Trial of Bioresorbable Vascular Scaffold Versus Everolimus Eluting Stent in Patients Undergoing Coronary Stenting for Myocardial Infarction; ISR = in-stent restenosis; MACE = major cardiac adverse event; MI = myocardial infarction; MICAT = Mainz IntraCoronAry daTabase; N/A = not applicable; PCI = percutaneous coronary intervention; POCE = patient-oriented composite endpoint; POLAR ACS = POLishAbsorb Registry for ACS Patients; RAI = Registro Absorb Italiano; RIBS-VI = Restenosis Intra-stent: drug eluting Balloon vs. everolimus-eluting Stent-VI; SPIRIT = A Clinical Evaluation of the XIENCE V Everolimus Eluting Coronary Stent System; ST = stent thrombosis; STEMI = ST-segment elevation myocardial infarction; TLF = target lesion failure; TLR = target lesion revascularization; TVF = target vessel failure.

RISK FACTORS FOR SCAFFOLD THROMBOSIS

Risk factors for scaffold thrombosis were multifactorial in the combination of the device, procedural, and patient factors. Mainz IntraCoronAry daTabase (MICAT) registry enrolled 42 scaffold thrombosis. Multivariate analysis showed that ostial lesions and impaired left ventricular ejection fraction were independent predictors of scaffold thrombosis. In addition, early discontinuation of dual antiplatelet therapy (DAPT) was frequent in those patients. Most striking finding was that a BRS-specific implantation strategy reduced 12-months scaffold thrombosis rate from 3.3% to 1.0% (Figure 4).18)
Figure 4
BRS specific implantation protocol. BRS specific implantation protocol was associated with about 70% reduction of scaffold thrombosis.
BRS = bioresorbable vascular scaffold.
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Recent meta-analysis from ABSORB trials reported that diabetes and preprocedural reference vessel diameter (<2.25 mm vs. ≥2.25 mm) were independent predictors for definite or probable device thrombosis.12)

KOREAN EXPERIENCE

The Absorb BRS has been used since October 2015 in Korea. As of August 2017, a total of 2,833 BRSs were implanted. Among those, only 9 scaffold thrombosis were reported in 9 patients. All patients presented with ACS (5 acute MI, 4 unstable angina). BRSs were implanted under the intracoronary imaging guidance in all cases. Postdilatation was performed in 8 patients. Scaffold thrombosis occurs in 2 cases within 24 hours and in 7 cases between 1 day and 30 days. No late scaffold thrombosis was reported. Possible mechanisms of scaffold thrombosis are early continuation of DAPT in 5 cases, underexpansion in 4 cases, and scaffold malapposition in 1 case. All patients were successfully treated without events (Table 3).
Table 3

BRS thrombosis from Korean population

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Characteristic Case 1 Case 2 Case 3 Case 4 Case 5 Case 6 Case 7 Case 8 Case 9
Sex/age M/54 M/45 M/67 M/87 F/75 F/68 M/58 M/73 M/74
Diagnosis UA NSTEMI NSTEMI STEMI UA UA NSTEMI STEMI ACS
Location m LAD p LAD m LAD m LAD p LAD p-m LAD m LAD m LAD m LAD
BRS (mm) 3.5×28 2.5×18 2.5×28 3.0×18 3.0×18 3.5×28 3.5×28 3.0×23 3.0×18
Image guidance IVUS OCT OCT OCT OCT IVUS/OCT IVUS/OCT None IVUS
Post-dilatation Done Done Done Not done (complete Scaffold apposition) Done Done Done Done (3.5×12 mm) Done (3.0×12 mm)
Days post-procedure 12 days 14 days 20 days 8 days 7 days 5 hours 13 days 7 hours 2 months
DAPT Aspirin, Clopidogrel Aspirin, Ticagrelor Aspirin, Ticagrelor Aspirin, Clopidogrel Aspirin, Clopidogrel Aspirin, Clopidogrel Aspirin, Ticagrelor Aspirin, Clopidogrel Aspirin, clopidogrel
D/C for 3 days D/C for 2 days D/C for 3 days D/C for 5 hours D/C for 3 days
Possible mechanism DAPT D/C DAPT D/C DAPT D/C Under-expansion Under-expansion Jailed diagonal branch DAPT D/C Scaffold malapposition DAPT D/C
Underexpansion Underexpansion
Outcomes Survival Survival Survival Survival Survival Survival Survival Survival Survival
ACS = acute coronary syndrome; BRS = bioresorbable vascular scaffold; DAPT = dual antiplatelet therapy; D/C = discontinuation; IUVS = intravascular ultrasound; LAD = left anterior descending; m = mid; NSTEMI = non-ST-segment elevation myocardial infarction; OCT = optical coherent tomography; p = proximal; ST = stent thrombosis; STEMI = ST-segment elevation myocardial infarction; UA = unstable angina.
Interventional Cardiology Research In-cooperation Society Fractional Flow Reserve Bioresorbable Vascular Scaffold (IRIS BVS) registry is the ongoing prospective, multicenter registry to enroll all patients who underwent the Absorb BRS implantation from 15 Korean heart centers. Preliminary data of early 352 patients was presented at Transcatheter Cardiovascular Therapeutics Angioplasty Summit (TCTAP) 2017. All procedures were performed under the intracoronary imaging guidance. Predilatation was performed in 94%; postdilation with non-compliant balloon in 99%. Mean scaffold diameter was 3.5±1.9 mm. Final non-compliant balloon pressure was 19.5±5.3 mm. Final balloon diameter was 3.6±0.3 mm. Mean balloon to artery ratio was 1.22±0.30. Mean inflation time was 25±12 seconds. At 1 year, no scaffold thrombosis occurred. Only 2 TLFs related with periprocedural MI occurred (Table 4). Compared with other studies, the IRIS BVS registry had the higher rate of imaging guidance, and pre- and postdilation. This could be a plausible reason of favorable BRS outcomes with very low rate of scaffold thrombosis in Korea, although preliminary.
Table 4

IRIS BVS registry: 1 year outcome (n=352)

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Variable No. of patients (%)
Device-oriented endpoint
TVF 2 (0.45)
Cardiac death 0 (0.0)
MI 2 (0.45)
Periprocedural MI 2 (0.45)
Spontaneous MI 0 (0.0)
Target-vessel revascularization 0 (0.0)
Scaffold thrombosis 0 (0.0)
Patient-oriented endpoint
Death from any cause 0 (0.0)
Cardiac death 0 (0.0)
Non-cardiac death 0 (0.0)
Stroke 0 (0.0)
IRIS BVS = Interventional Cardiology Research In-cooperation Society Fractional Flow Reserve Bioresorbable Vascular Scaffold; MI = myocardial infarction; TVF = target vessel failure.

INDICATIONS FOR BRS IMPLANTATION

Patient selection

As current BRSs resolve 2–3 years after implantation, improvement in outcome comparing with metallic DESs is expected in long-term over those periods. Therefore, ideal BRS candidate is a relatively young with a good life expectancy (>5 years). On the other hand, the use of BRS in patients with limited life expectancy with multiple comorbidities, and at high bleeding risk was not supported.38)

Lesion selection

BRS can be implanted in non-complex lesions including de novo lesions with diameter of 2.25–4.0 mm on on-site quantitative coronary angiography (QCA), relative short lesions, and stable angina presentation. The culprit lesion of ST segment elevated MI, bifurcation lesion treating with 2 scaffolds, and aorto-ostial lesion, extreme tortuous vessel and small vessel (<2.25 mm) were less favorable lesions for BRS implantation. Table 5 summarized the BRS favorable patient and lesion characteristics.38)
Table 5

BRS favorable patient and lesion characteristics

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• A relatively young with a good life expectancy (>5 years)
• De novo lesions
• Diameter 2.35–4.0 mm on QCA
• Maximum length 28 mm
• One BRS scaffold overlap
• Stable or silent ischemia
BRS = bioresorbable vascular scaffold; QCA = quantitative coronary angiography.

BRS specific implantation techniques

Optimal sizing and BRS implantation technique is of paramount importance for achieving favorable long-term outcomes. Operators should understand that thick scaffold struts and their plastic nature results in a lower lumen gain and a smaller post-implanted minimal lumen diameter compared with conventional metallic DES. Importantly, report that early scaffold thrombosis occurs at a time when most patients received DAPT suggested that scaffold thrombosis would be related to procedure related factors.5) In addition, in randomized trials and registry studies, the optimal techniques for BRS implantation was underused. The systemic introduction of a BRS-specific protocol which has come to be known as preparation, sizing, and postdilatation (PSP) are associated with an up to 70% decrease in scaffold thrombosis to rates similar to those reported in metallic DESs (Figure 4).18) We suggest the “effective” PSP methods for BRS implantation (Table 6, Figure 5).38)39)
Table 6

Effective PSP

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Prepare lesion
• Use a non-compliant balloon (1:1 balloon to vessel ratio)
• Encourage scoring/cutting balloon or rotational atherectomy in calcified lesions
• Avoid BRS implantation in the lesion not achieving full balloon expansion
Sizing
• Use intracoronary imaging to select adequate device size
• Otherwise, use on-line QCA with automatic calibration to select device size
• Select device size relying on the proximal Dmax on on-line QCA
(example)
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Postdilatation
• Use a non-compliant balloon with 0.5 mm bigger size than scaffold with high inflation pressure (16–25 atm)
• Target balloon to artery ratio of >1.2 (or balloon to device ratio of >1.15)
• Maintain target pressure for at least 30 seconds
BRS = bioresorbable vascular scaffold; Dmax = maximal lumen diameter; PSP = preparation, sizing, and postdilatation; QCA = quantitative coronary angiography.
Figure 5
A case of “Effective” PSP. Fifty-seven years old man admitted due to effort related chest pain. Coronary angiography showed tight stenosis of LAD artery (A). On-line QCA showed that proximal Dmax was 3.1 mm and distal Dmax was 2.6 mm (E-G). Predilatation was performed using 3.5×1.5 mm non-compliant balloon (B). Absorb BRS 3.0×23 mm was implanted (C). Postdilatation was done by 3.5×15 mm non-compliant balloon up to 18 atm (final balloon diameter: 3.6 mm). Final optimal coherent tomography showed well expanded and apposed scaffold without acute complications.
BRS = bioresorbable vascular scaffold; Dmax = maximal lumen diameter; LAD = left anterior descending; MLD = mean lung dose; NC = non-compliant; PSP = preparation, sizing, and postdilatation; QCA = quantitative coronary angiography; RVD = reference vessel diameter.
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Step 1. lesion preparation with predilatation

The lesions should be prepared using adequate predilatation with semi or non-compliant balloon (1:1 vessel to balloon ratio). At the same time, operator should be cautious to avoid severe dissection over the BRS covered zone. Particularly for calcified lesions, aggressive lesion preparation is mandatory due to the relatively lack of sufficient radial force in BRS. Scoring/cutting balloon or rotational atherectomy can be used with lower threshold.40) If predilatation balloons cannot fully expand lesions, BRS implantation should be avoided.

Step 2. sizing and implantation

Intracoronary imaging including intravascular ultrasound or optical coherent tomography is a useful tool to assess pre-intervention lesion characteristics and optimize stent implantation.41) However, even in clinical trial setting, intracoronary imaging was significantly underused.7)42)43) In addition, angiography guidance with visual estimation may be inaccurate.44)
Instead, online QCA with automatic calibration offers reliable assessment of vessel sizing without additional cost.45)46) We suggest that BRS sizing relies on proximal and distal maximal lumen diameter (Dmax) at the level of intended BRS implantation zone after nitroglycerin administration.47) Except in case of extreme vessel tapering, the scaffold selection should match the proximal Dmax in proximal device landing zone. Considering Dmax from online QCA is about 0.5 mm smaller than vessel diameter from intracoronary imaging,48) this sizing method with additional bigger non-compliant balloon inflation can well-negotiate the risk between underexpansion of proximal edge and dissection of distal edge. In addition, this strategy can limit excessive scaffold/artery ratio, and may decrease thrombogenicity, and neointimal thickness.49)50)
BRS should cover normal looking segment at either edge of lesion. Scaffold deployment should be performed slowly with long-duration. In general, high-pressure inflation with delivery balloon was not recommended. When implanting multiple BRS, minimal overlapping techniques to minimize scaffold thickness are suggested such as “marker-to marker” (up to 1 mm of overlap) or “scaffold-to-scaffold” (no overlap) technique.8)

Step 3. postdilatation with a non-compliant balloon

Postdilitation is also very important during BRS implantation. In previous registry, all acute or subacute BRS thrombosis occurred in severe underexpanded scaffold.51) Postdilatation uses a non-compliant balloon with 0.5 mm bigger size than scaffold device with high inflation pressure (16–25 atm). Recent data showed that higher balloon to artery ratio (>1.2, or balloon to device ratio >1.15) was associated with expansive vessel wall remodeling.52) Target pressure should be maintained for at least 30 seconds, because a significant larger lumen diameter is obtained with a longer inflation time.53)

TREATMENT FOR BRS FAILURE (SCAFFOLD THROMBOSIS AND IN-SCAFFOLD RESTENOSIS)

Understanding the fundamental pathophysiological mechanism underlying BRS failure is of key importance to guide proper subsequent treatment.54) Therefore, intracoronary imaging study is highly recommended in cases of BRS failure.55) Multiple treatment strategy for treating BRS failure was proposed including DES, plane balloon angioplasty, drug-coated balloon, or BRS.55)56) Mechanical causes can be treated first with balloon angioplasty with non-compliant balloon. In-scaffold restenosis due to neointimal hyperplasia can be treated by a drug-coated balloon. If mechanical factors cannot be corrected by balloon angioplasty, DES implantation can be considered. In addition, if BRS failure occurs 6 months after implantation, DES or BRS implantation can be considered because after 6 months disintegration of the scaffold begin and additional radial strength is necessary.55)

HYBRID PERCUTANEOUS CORONARY INTERVENTION

Due to the clinical and mechanical limitations of current generation BRS, complex coronary lesions are frequent unsuitable for pure BRS implantation. To minimize the length of permanent metallic caging, and achieving optimal BRS result, hybrid approach in combination of BRS, DES, and drug-coated balloon was proposed.57) For the BRS less favorable lesion including large vessel, aorto-ostial lesion, side-branch of bifurcation, large size discrepancy, and small vessel, conventional DES was implanted. Drug-coated balloon can be used in small diffuse coronary artery disease.58) BRS was implanted only in BRS favorable lesions overlapping with DES. Aggressive post-dilatation should be performed at the overlapping site to minimize the risk of late malapposition of metallic DES after complete resorption of BRS.57)

ANTIPLATELET THERAPY AFTER BRS IMPLANTATION

For metallic DES, at least 6-month DAPT after PCI for stable ischemic heart disease, and 12-month for ACSs are recommended in American and European guidelines.59)60) However, optimal duration of DAPT for BRS remains to be evaluated. Randomized trials stated the use of DAPT for at least 1 year per protocol.6)7)42)43) Regarding several reports on early as well as late scaffold thrombosis,61) some physicians suggest the longer DAPT regimen (>12 months), and/or more potent agents (e.g., ticagrelor or prasugrel)62)63) or triple antiplatelet therapy, particularly in the early period after BRS implantation. In this context, patients who cannot tolerate a long-term DAPT or are at high risk of bleeding may not be ideal candidate for BRS implantation.

LESSONS FROM FIRST GENERATION ABSORB BRS

At 14th September 2017, Abbott Vascular announced a halt to sales of the Absorb BRS. The experience of the first generation BRS provides the valuable insight for the next generation (Figure 6). First, the new BRS needs to be mechanically stronger, have thinner struts, and available in a broad range of length and diameter. In addition, complete biodegradation occurs without significant inflammatory reaction within 1–2 years. Second, treating physicians should realize that BRS profiles may differ significantly from conventional metallic DESs and should adopt specific BRS implantation technique for favorable outcomes. Third, new BRS should be extensively tested in a stepwise fashion from relatively simple lesion to more complex lesion.
Figure 6
Optimal BRS outcomes.
BRS = bioresorbable vascular scaffold; PSP = preparation, sizing, and postdilatation; QCA = quantitative coronary angiography.
kcj-47-795-g006

CONCLUSION

Although promising early reports, recent studies have raised concerns about the safety and efficacy of BRS compared with contemporary standard metallic DESs. However, we have experienced in the interventional technology field that the drawbacks of old device have greatly motivated technological innovation to solve previous problems. With rapid evolving technology of BRS under a number of current ongoing clinical tests, newer BRS overcoming current issues are expected in a near future.

Notes

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

References

1. Serruys PW, Chevalier B, Dudek D, et al. A bioresorbable everolimus-eluting scaffold versus a metallic everolimus-eluting stent for ischaemic heart disease caused by de-novo native coronary artery lesions (ABSORB II): an interim 1-year analysis of clinical and procedural secondary outcomes from a randomised controlled trial. Lancet. 2015; 385:43–54.
2. Karanasos A, Simsek C, Gnanadesigan M, et al. OCT assessment of the long-term vascular healing response 5 years after everolimus-eluting bioresorbable vascular scaffold. J Am Coll Cardiol. 2014; 64:2343–2356.
3. Brugaletta S, Radu MD, Garcia-Garcia HM, et al. Circumferential evaluation of the neointima by optical coherence tomography after ABSORB bioresorbable vascular scaffold implantation: can the scaffold cap the plaque? Atherosclerosis. 2012; 221:106–112.
4. Simsek C, Karanasos A, Magro M, et al. Long-term invasive follow-up of the everolimus-eluting bioresorbable vascular scaffold: five-year results of multiple invasive imaging modalities. EuroIntervention. 2016; 11:996–1003.
5. Serruys PW, Chevalier B, Sotomi Y, et al. Comparison of an everolimus-eluting bioresorbable scaffold with an everolimus-eluting metallic stent for the treatment of coronary artery stenosis (ABSORB II): a 3 year, randomised, controlled, single-blind, multicentre clinical trial. Lancet. 2016; 388:2479–2491.
6. Wykrzykowska JJ, Kraak RP, Hofma SH, et al. Bioresorbable scaffolds versus metallic stents in routine PCI. N Engl J Med. 2017; 376:2319–2328.
7. Ellis SG, Kereiakes DJ, Metzger DC, et al. Everolimus-eluting bioresorbable scaffolds for coronary artery disease. N Engl J Med. 2015; 373:1905–1915.
8. Tamburino C, Latib A, van Geuns RJ, et al. Contemporary practice and technical aspects in coronary intervention with bioresorbable scaffolds: a European perspective. EuroIntervention. 2015; 11:45–52.
9. Foin N, Lee R, Bourantas C, et al. Bioresorbable vascular scaffold radial expansion and conformation compared to a metallic platform: insights from in vitro expansion in a coronary artery lesion model. EuroIntervention. 2016; 12:834–844.
10. Onuma Y, Dudek D, Thuesen L, et al. Five-year clinical and functional multislice computed tomography angiographic results after coronary implantation of the fully resorbable polymeric everolimus-eluting scaffold in patients with de novo coronary artery disease: the ABSORB cohort A trial. JACC Cardiovasc Interv. 2013; 6:999–1009.
11. Serruys PW, Ormiston J, van Geuns RJ, et al. A polylactide bioresorbable scaffold eluting everolimus for treatment of coronary stenosis: 5-year follow-up. J Am Coll Cardiol. 2016; 67:766–776.
12. Ali ZA, Serruys PW, Kimura T, et al. 2-year outcomes with the absorb bioresorbable scaffold for treatment of coronary artery disease: a systematic review and meta-analysis of seven randomised trials with an individual patient data substudy. Lancet. 2017; 390:760–772.
13. Capodanno D, Gori T, Nef H, et al. Percutaneous coronary intervention with everolimus-eluting bioresorbable vascular scaffolds in routine clinical practice: early and midterm outcomes from the European multicentre GHOST-EU registry. EuroIntervention. 2015; 10:1144–1153.
14. Abizaid A, Ribamar Costa J Jr, Bartorelli AL, et al. The ABSORB EXTEND study: preliminary report of the twelve-month clinical outcomes in the first 512 patients enrolled. EuroIntervention. 2015; 10:1396–1401.
15. Wiebe J, Hoppmann P, Colleran R, et al. Long-term clinical outcomes of patients treated with everolimus-eluting bioresorbable stents in routine practice: 2-year results of the ISAR-ABSORB Registry. JACC Cardiovasc Interv. 2017; 10:1222–1229.
16. Cortese B, Ielasi A, Moscarella E, et al. Thirty-day outcomes after unrestricted implantation of bioresorbable vascular scaffold (from the prospective RAI Registry). Am J Cardiol. 2017; 119:1924–1930.
17. Wöhrle J, Naber C, Schmitz T, et al. Beyond the early stages: insights from the ASSURE registry on bioresorbable vascular scaffolds. EuroIntervention. 2015; 11:149–156.
18. Puricel S, Cuculi F, Weissner M, et al. Bioresorbable coronary scaffold thrombosis: multicenter comprehensive analysis of clinical presentation, mechanisms, and predictors. J Am Coll Cardiol. 2016; 67:921–931.
19. Kraak RP, Hassell ME, Grundeken MJ, et al. Initial experience and clinical evaluation of the absorb bioresorbable vascular scaffold (BVS) in real-world practice: the AMC Single Centre Real World PCI Registry. EuroIntervention. 2015; 10:1160–1168.
20. Rzeszutko Ł, Siudak Z, Tokarek T. Twelve months clinical outcome after bioresorbable vascular scaffold implantation in patients with stable angina and acute coronary syndrome. Data from the Polish National Registry. Postepy Kardiol Interwencyjnej. 2016; 12:108–115.
21. Felix CM, Fam JM, Diletti R, et al. Mid- to long-term clinical outcomes of patients treated with the everolimus-eluting bioresorbable vascular scaffold: the BVS Expand Registry. JACC Cardiovasc Interv. 2016; 9:1652–1663.
22. Muramatsu T, Onuma Y, van Geuns RJ, et al. 1-year clinical outcomes of diabetic patients treated with everolimus-eluting bioresorbable vascular scaffolds: a pooled analysis of the ABSORB and the SPIRIT trials. JACC Cardiovasc Interv. 2014; 7:482–493.
23. Dudek D, Rzeszutko Ł, Zasada W, et al. Bioresorbable vascular scaffolds in patients with acute coronary syndromes: the POLAR ACS study. Pol Arch Med Wewn. 2014; 124:669–677.
24. Gori T, Schulz E, Hink U, et al. Early outcome after implantation of absorb bioresorbable drug-eluting scaffolds in patients with acute coronary syndromes. EuroIntervention. 2014; 9:1036–1041.
25. Hellenkamp K, Becker A, Gabriel YD, et al. Mid- to long-term outcome of patients treated with everolimus-eluting bioresorbable vascular scaffolds: data of the BVS registry Göttingen predominantly from ACS patients. Int J Cardiol. 2017; 234:58–63.
26. Kajiya T, Liang M, Sharma RK, et al. Everolimus-eluting bioresorbable vascular scaffold (BVS) implantation in patients with ST-segment elevation myocardial infarction (STEMI). EuroIntervention. 2013; 9:501–504.
27. Kočka V, Malý M, Toušek P, et al. Bioresorbable vascular scaffolds in acute ST-segment elevation myocardial infarction: a prospective multicentre study ‘Prague 19’. Eur Heart J. 2014; 35:787–794.
28. Wiebe J, Möllmann H, Most A, et al. Short-term outcome of patients with ST-segment elevation myocardial infarction (STEMI) treated with an everolimus-eluting bioresorbable vascular scaffold. Clin Res Cardiol. 2014; 103:141–148.
29. Diletti R, Karanasos A, Muramatsu T, et al. Everolimus-eluting bioresorbable vascular scaffolds for treatment of patients presenting with ST-segment elevation myocardial infarction: BVS STEMI first study. Eur Heart J. 2014; 35:777–786.
30. Brugaletta S, Gori T, Low AF, et al. Absorb bioresorbable vascular scaffold versus everolimus-eluting metallic stent in ST-segment elevation myocardial infarction: 1-year results of a propensity score matching comparison: the BVS-EXAMINATION Study (bioresorbable vascular scaffold-a clinical evaluation of everolimus eluting coronary stents in the treatment of patients with ST-segment elevation myocardial infarction). JACC Cardiovasc Interv. 2015; 8:189–197.
31. Cortese B, Ielasi A, Romagnoli E, et al. Clinical comparison with short-term follow-up of bioresorbable vascular scaffold versus everolimus-eluting stent in primary percutaneous coronary interventions. Am J Cardiol. 2015; 116:705–710.
32. Kochman J, Tomaniak M, Pietrasik A, et al. Bioresorbable everolimus-eluting vascular scaffold in patients with ST-segment elevation myocardial infarction: optical coherence tomography evaluation and clinical outcomes. Cardiol J. 2015; 22:315–322.
33. Chakraborty R, Patra S, Banerjee S, et al. Outcome of everolimus eluting bioabsorbable vascular scaffold (BVS) compared to non BVS drug eluting stent in the management of ST-segment elevation myocardial infarction (STEMI) - a comparative study. Cardiovasc Revasc Med. 2016; 17:151–154.
34. Diletti R, Farooq V, Girasis C, et al. Clinical and intravascular imaging outcomes at 1 and 2 years after implantation of absorb everolimus eluting bioresorbable vascular scaffolds in small vessels. Late lumen enlargement: does bioresorption matter with small vessel size? Insight from the ABSORB cohort B trial. Heart. 2013; 99:98–105.
35. Ielasi A, Latib A, Naganuma T, et al. Early results following everolimus-eluting bioresorbable vascular scaffold implantation for the treatment of in-stent restenosis. Int J Cardiol. 2014; 173:513–514.
36. Moscarella E, Ielasi A, Granata F, et al. Long-term clinical outcomes after bioresorbable vascular scaffold implantation for the treatment of coronary in-stent restenosis: a multicenter Italian experience. Circ Cardiovasc Interv. 2016; 9:e003148.
37. Alfonso F, Cuesta J, Pérez-Vizcayno MJ, et al. Bioresorbable vascular scaffolds for patients with in-stent restenosis: the RIBS VI Study. JACC Cardiovasc Interv. 2017; 10:1841–1851.
38. Everaert B, Wykrzykowska JJ, Koolen J, et al. Recommendations for the use of bioresorbable vascular scaffolds in percutaneous coronary interventions: 2017 revision. Neth Heart J. 2017; 25:419–428.
39. Indolfi C, De Rosa S, Colombo A. Bioresorbable vascular scaffolds - basic concepts and clinical outcome. Nat Rev Cardiol. 2016; 13:719–729.
40. Miyazaki T, Latib A, Ruparelia N, et al. The use of a scoring balloon for optimal lesion preparation prior to bioresorbable scaffold implantation: a comparison with conventional balloon predilatation. EuroIntervention. 2016; 11:e1580–e1588.
41. Hibi K, Kimura K, Umemura S. Clinical utility and significance of intravascular ultrasound and optical coherence tomography in guiding percutaneous coronary interventions. Circ J. 2015; 79:24–33.
42. Kimura T, Kozuma K, Tanabe K, et al. A randomized trial evaluating everolimus-eluting absorb bioresorbable scaffolds vs. everolimus-eluting metallic stents in patients with coronary artery disease: ABSORB Japan. Eur Heart J. 2015; 36:3332–3342.
43. Gao R, Yang Y, Han Y, et al. Bioresorbable vascular scaffolds versus metallic stents in patients with coronary artery disease: ABSORB China Trial. J Am Coll Cardiol. 2015; 66:2298–2309.
44. Campbell PT, Mahmud E, Marshall JJ. Interoperator and intraoperator (in)accuracy of stent selection based on visual estimation. Catheter Cardiovasc Interv. 2015; 86:1177–1183.
45. Gomez-Lara J, Diletti R, Brugaletta S, et al. Angiographic maximal luminal diameter and appropriate deployment of the everolimus-eluting bioresorbable vascular scaffold as assessed by optical coherence tomography: an ABSORB cohort B trial sub-study. EuroIntervention. 2012; 8:214–224.
46. Pinton FA. Falcão Bd, Mariani J Jr, Kajita LJ, Filho AE, Lemos PA. Accuracy and precision of online quantitative coronary angiography with automatic calibration: a pilot study. Rev Bras Cardiol Invasiva. 2015; 23:58–60.
47. Farooq V, Gomez-Lara J, Brugaletta S, et al. Proximal and distal maximal luminal diameters as a guide to appropriate deployment of the ABSORB everolimus-eluting bioresorbable vascular scaffold: a sub-study of the ABSORB Cohort B and the on-going ABSORB EXTEND Single Arm Study. Catheter Cardiovasc Interv. 2012; 79:880–888.
48. Goto K, Mintz GS, Litherland C, et al. Lumen measurements from quantitative coronary angiography and IVUS: a PROSPECT Substudy. JACC Cardiovasc Imaging. 2016; 9:1011–1013.
49. Kawamoto H, Jabbour RJ, Tanaka A, Latib A, Colombo A. The bioresorbable scaffold: will oversizing affect outcomes? JACC Cardiovasc Interv. 2016; 9:299–300.
50. Ishibashi Y, Nakatani S, Sotomi Y, et al. Relation between bioresorbable scaffold sizing using QCA-Dmax and clinical outcomes at 1 year in 1,232 patients from 3 study cohorts (ABSORB Cohort B, ABSORB EXTEND, and ABSORB II). JACC Cardiovasc Interv. 2015; 8:1715–1726.
51. Souteyrand G, Amabile N, Mangin L, et al. Mechanisms of stent thrombosis analysed by optical coherence tomography: insights from the national PESTO French registry. Eur Heart J. 2016; 37:1208–1216.
52. Serruys PW, Katagiri Y, Sotomi Y, et al. Arterial remodeling after bioresorbable scaffolds and metallic stents. J Am Coll Cardiol. 2017; 70:60–74.
53. Sorrentino S, De Rosa S, Ambrosio G, et al. The duration of balloon inflation affects the luminal diameter of coronary segments after bioresorbable vascular scaffolds deployment. BMC Cardiovasc Disord. 2015; 15:169.
54. Elwany M, Latini RA, Di Palma G, Orrego PS, Cortese B. First experience of drug-coated balloons for treatment of bioresorbable vascular scaffold restenosis. [Epub ahead of print]. Cardiovasc Revasc Med. 2017.
55. Felix C, Everaert B, Jepson N, Tamburino C, van Geuns RJ. Treatment of bioresorbable scaffold failure. EuroIntervention. 2015; 11:Suppl V. V175–V180.
56. Tanaka A, Ruparelia N, Kawamoto H, et al. Clinical outcomes following target lesion revascularization for bioresorbable scaffold failure. Catheter Cardiovasc Interv. 2016; 87:832–836.
57. Tanaka A, Jabbour RJ, Mitomo S, Latib A, Colombo A. Hybrid percutaneous coronary intervention with bioresorbable vascular scaffolds in combination with drug-eluting stents or drug-coated balloons for complex coronary lesions. JACC Cardiovasc Interv. 2017; 10:539–547.
58. Ielasi A, Miyazaki T, Geraci S, et al. Hybrid strategy with a bioresorbable scaffold and a drug-coated balloon for diffuse coronary artery disease: the “no more metallic cages” multicentre pilot experience. EuroIntervention. 2016; 11:e1589–e1595.
59. Levine GN, Bates ER, Blankenship JC, et al. 2015 ACC/AHA/SCAI focused update on primary percutaneous coronary intervention for patients with ST-elevation myocardial infarction: an update of the 2011 ACCF/AHA/SCAI Guideline for percutaneous coronary intervention and the 2013 ACCF/AHA Guideline for the management of ST-elevation myocardial infarction. J Am Coll Cardiol. 2016; 67:1235–1250.
60. Authors/Task Force members. 2014 ESC/EACTS Guidelines on myocardial revascularization: the Task Force on Myocardial Revascularization of the European Society of Cardiology (ESC) and the European Association for Cardio-Thoracic Surgery (EACTS)Developed with the special contribution of the European Association of Percutaneous Cardiovascular Interventions (EAPCI). Eur Heart J. 2014; 35:2541–2619.
61. Karanasos A, van Geuns RJ, Zijlstra F, Regar E. Very late bioresorbable scaffold thrombosis after discontinuation of dual antiplatelet therapy. Eur Heart J. 2014; 35:1781.
62. Capodanno D, Angiolillo DJ. Antiplatelet therapy after implantation of bioresorbable vascular scaffolds: a review of the published data, practical recommendations, and future directions. JACC Cardiovasc Interv. 2017; 10:425–437.
63. Valgimigli M, Bueno H, Byrne RA, et al. ESC focused update on dual antiplatelet therapy in coronary artery disease developed in collaboration with EACTS: the Task Force for dual antiplatelet therapy in coronary artery disease of the European Society of Cardiology (ESC) and of the European Association for Cardio-Thoracic Surgery (EACTS). [Epub ahead of print]. Eur Heart J. 2017; 2017.
64. Puricel S, Arroyo D, Corpataux N, et al. Comparison of everolimus- and biolimus-eluting coronary stents with everolimus-eluting bioresorbable vascular scaffolds. J Am Coll Cardiol. 2015; 65:791–801.
65. Sabaté M, Windecker S, Iñiguez A, et al. Everolimus-eluting bioresorbable stent vs. durable polymer everolimus-eluting metallic stent in patients with ST-segment elevation myocardial infarction: results of the randomized ABSORB ST-segment elevation myocardial infarction-TROFI II trial. Eur Heart J. 2016; 37:229–240.
TOOLS
ORCID iDs

Jung-Min Ahn
https://orcid.org/0000-0003-4031-391X

Sung Jin Hong
https://orcid.org/0000-0003-4893-039X

Joo-Yong Hahn
https://orcid.org/0000-0002-4412-377X

Chang-Wook Nam
https://orcid.org/0000-0002-3370-5774

Seung-Yul Lee
https://orcid.org/0000-0002-9039-9806

Myeong-Ki Hong
https://orcid.org/0000-0002-2090-2031

Yangsoo Jang
https://orcid.org/0000-0002-2169-3112

Seung-Jung Park
https://orcid.org/0000-0002-9187-5405

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