Test Efficacy With Bioresorbable Polymer Coating Versus Bioresorbable Polymer Backbone (ISAR-RESORB)

Percutaneous coronary intervention (PCI) with drug-eluting stent (DES) implantation currently represents the dominant treatment strategy in patients undergoing catheter intervention. However, effective neointimal suppression occurs at the cost of a systematic delay in arterial healing in comparison with after bare metal stenting. This underlies a small but significant increased risk of stent thrombosis after DES implantation in comparison with bare metal stent implantation as well as a possible excess of in-stent neoatheroma formation. To address this issue recent technological advances have focused on bioresorbable polymer coatings and the development of stents with fully resorbable backbones.

Newer generation metallic DES with bioresorbable polymer coatings have been shown to improve vascular healing after coronary stenting. In particular a novel thin-strut bioresorbable polymer everolimus-eluting stent (EES, SYNERGY, Boston Scientific Corp., Natick, MA, USA) has shown high angiographic antirestenotic efficacy as well as high clinical efficacy and safety in early randomized trials. In addition, DES with bioresorbable backbones represent an alternative approach to ensure short-term vessel scaffolding and drug delivery with enhanced vessel healing. The everolimus-eluting bioresorbable backbone stent (ABSORB bioresorbable vascular scaffold [BVS], Abbott Vascular, Santa Rosa, CA, USA) is the most-extensively studied device in this class and early reports in selected patients show encouraging clinical results. However requirement for thicker stent struts and more careful lesion preparation has led to concerns that potential clinical benefits may be offset by erosion of early antirestenotic efficacy and occurrence of clinical events related to limitations of device deployment.

At present there is a lack of randomized clinical trial data examining outcomes of patients treated with these two alternative strategies. The aim of the current ISAR-RESORB study is to test the clinical performance of the bioresorbable-polymer SYNERGY with that of the ABSORB BVS in patients undergoing PCI of de novo coronary lesions. The primary endpoint will be percentage diameter stenosis at protocol-mandated 6-8 month angiographic follow-up. Secondary clinical endpoint will be assessed at 12 months. Sample size calculation is based on a superiority hypothesis for SYNERGY versus ABSORB BVS. It is planned to enrol a total of 230 patients.