A prospective, multicenter, randomized OCT study of early neointimal condition at first and second months after BuMA Supreme stent versus XIENCE stent implantation in high-bleeding-risk coronary artery disease patients: study protocol for a randomized controlled trial

Drug-eluting stents (DES) reduce the rate of restenosis and consequent need for target lesion revascularization (TLR) compared with bare metal stents (BMS). However, impaired endothelialization increases the risk of late and very late stent thrombosis [1]. As a solution, the patient’s postoperative dual anti-platelet therapy (DAPT) treatment increases gradually from 1 month for the BMS to 6–12 months for DES post procedure, or even longer. But extension of DAPT increased the risk of bleeding, which raises another issue of how to shorten the DAPT period after the new DES implantation – which will benefit the patients with relatively high bleeding risk [2].

The BuMA stent (SINOMED, Beijing, China) is a novel, biodegradable, poly-lactic-co-glycolic acid polymer sirolimus-eluting stent (SES), with a thin-strut cobalt-chromium platform (80 μm), thin (200 nm) electro-grafting base between the polymer and stainless-steel stent strut. The BuMA Supreme SES has a pharmacokinetic polymer degradation/drug release profile where the top coat releases the drug relatively rapidly such that sirolimus release from the stents surface is nearly complete by 28 days after implantation [3]. The PIONEER trial showed that the BuMA stent did not meet the criteria for non-inferiority to zotarolimus-eluting stents (ZES) in terms of angiographic in-stent late lumen loss (LLL) at 9-month follow-up [4]. The study also showed that the BuMA SES was superior to the EXCEL SES in endothelialization at 3-month follow-up [5]. However, the earlier (≤ 2-month) endothelialization data are limited. This study can provide accurate imaging evidence on early neointimal formation of the BuMA and Xience stents, and provide evidence for further exploration and adjustment of DAPT treatment.

PCI is widely used for patients with CAD all over the world. Compared with BMS, DES reduce the rate of restenosis from 20–35% to 10% and reduce the consequent need for TLR. However, DES increases the risk of late stent thrombosis, death and MI [11‐13]. A previous study [12] reported that the incidence of definite stent thrombosis was increased by 0.53% (CI 0.44–0.64) per year, and the cumulative rate of definite stent thrombosis was 3.3%, combined incidence of definite stent thrombosis and the probable stent thrombosis was 5.7% in 4 years. At present, some studies have regarded endothelialization as one of the important factors that may reduce late thrombosis and then reduce cardiovascular events; therefore, research on DES has focused on how to promote the endothelialization. The ideal DES is to maximize the inhibition of smooth-muscle-cell proliferation and migration, minimize changes of structure and functional recovery of endothelial cell, and promote faster healing of endothelium [14, 15]. The second generation of drug-eluting stents (DES) has emerged with more biocompatible durable polymer coatings on thin-strut stents that have shown better safety than first-generation DES [16, 17]. The Biodegradable Polymer (BP)-DES, BuMA Supreme stent, was developed to prevent polymer-related adverse effects [18].

DAPT treatment increases from 1 month of the BMS to 6–12 months of DES post procedure, or even longer, which increases the risk of bleeding. Research on how to shorten the DAPT period after the new DES implantation will benefit relatively high-bleeding-risk patients. Studies showed that one out of seven to eight CAD PCI patients has a relatively high risk of bleeding, so clinicians need to evaluate bleeding and ischemic risk after DES, and adjust their DAPT treatment to obtain better clinical results [2].

In the recent 10 years, OCT has been widely used as an intravascular imaging technology to determine the morphology of the implanted stents, whereby high-resolution intravascular images can be obtained quickly – especially accurate results of stent-strut coverage in the vessel [19, 20]. For example, Ishigami K et al. observed stent-strut coverage of the first-generation sirolimus eluting stent (SES) at 9 months, 9–24 months and 25 months, respectively, and they found that only 17.6% of the SES was completely covered at 25 months. Delayed neointimal coverage was observed in patients with small blood vessels, complex lesions, high-lipid and high-calcium lesion or diabetics [21]. OCT was a reliable method for assessing the neointimal formation of stent strut post PCI, and it provided a good match to the resemblance of “optical biopsy.”

The research and development of stents is focused on the materials and coating composition of stents in China [22]. OCT is rarely used to evaluate vessel healing after new stent implantation. We have evaluated new BuMA DES strut coverage at 9 months by OCT in 2010, which showed that stent-strut coverage rate in BuMA stent was 94.3%, which was superior to that of the Endeavor stent [23]. The PANDA-III study with 2348 samples showed a statistically significant difference in the incidence of definite and probable stent thrombosis (0.7% vs. 1.4%) at 1 year, that is less stent thrombosis than occurred in the BuMA stent [24]. Moreover, in OCT follow-up at 3 months, the percentage of stent-strut coverage was significantly higher in the BuMA vs. the EXCEL group (strut level: 94.2% vs. 90.0%, P < 0.01) [5]. It showed that the design concept and technology of BuMA stent is good to promote early and complete healing of the neointima at a corresponding time after PCI at 3 months. The LEADERS FREE study also used large samples to compare the efficacy and safety of implantation of BMS and new DES in patients with CAD; 1-year follow-up showed that the efficacy and safety of the new DES group was superior to that of the BMS group [6, 25]. The OCT study of neointimal coverage has been reduced from 9 months to 3 months at present [5]; one purpose of this study is whether we could learn more about stent-strut coverage rate at 2 months and 1 month, which will help to conduct further study of an adjusted postoperative DAPT regimen. The evidence may provide clinicians and patients with more precise imaging evidence in DAPT regimens, especially more benefit for patients with a relatively high bleeding risk.

For BuMA stents that used international-patent, electronic-grafted (eG) technology, common problems, such as stent surface cracking and residue after drug release, are solved successfully, leading to rapid and complete endometrial healing and inhibition of late stent thrombosis. This feature is more conducive to helping patients with a relatively high risk of bleeding to adjust their DAPT treatment regimen. Based on the design of the previous generation of BuMA stents, the stent metal platform of the BuMA Supreme changed from 316 L stainless steel to L605 cobalt chromium – with thinner stent strut and better stent effects in contrast imaging and flexibility. Meanwhile, the thinner stent strut may further benefit the endothelium healing, which will bring the patients more safety benefits.

In conclusion, this is the first study to compare the strut coverage of the XIENCE stent with that of the BuMA Supreme sirolimus-eluting cobalt-chromium stent, which has a shorter drug elution on optical coherence tomography (OCT) 1 or 2 months after implantation; and it will give us accurate imaging evidence on neointimal formation of the BuMA Supreme stent and the Xience stent at 1–2 months post PCI. The result should inspire further exploration and adjustment of DAPT treatments Additional file 1.