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载匹伐他汀纳米颗粒洗脱支架可减轻猪冠状动脉模型中的支架内狭窄,而不延迟内皮愈合效应。

Pitavastatin-incorporated nanoparticle-eluting stents attenuate in-stent stenosis without delayed endothelial healing effects in a porcine coronary artery model.

机构信息

Department of Cardiovascular Medicine, Graduate School of Medical Sciences, Kyushu University, Fukuoka, Japan.

出版信息

J Atheroscler Thromb. 2013;20(1):32-45. doi: 10.5551/jat.13862. Epub 2012 Sep 13.

DOI:10.5551/jat.13862
PMID:22986515
Abstract

AIM

The use of currently marketed drug-eluting stents presents safety concerns including increased late thrombosis, which is thought to result mainly from delayed endothelial healing effects (impaired re-endothelialization resulting in abnormal inflammation and fibrin deposition). We recently developed a bioabsorbable polymeric nanoparticle (NP)-eluting stent using a novel cationic electrodeposition technology. Statins are known to inhibit the proliferation of vascular smooth muscle cells (VSMC) and to promote vascular healing. We therefore hypothesized that statin-incorporated NP-eluting stents would attenuate in-stent stenosis without delayed endothelial healing effects.

METHODS

Among six marketed statins, pitavastatin (Pitava) was found to have the most potent effects on VSMC proliferation and endothelial regeneration in vitro. We thus formulated a Pitava-NP-eluting stent (20µg Pitava per stent).

RESULTS

In a pig coronary artery model, Pitava-NP-eluting stents attenuated in-stent stenosis as effectively as polymer-coated sirolimus-eluting stents (SES). At SES sites, delayed endothelial healing effects were noted, whereas no such effects were observed in Pitava-NP-eluting stent sites.

CONCLUSION

Pitava-NP-eluting stents attenuated in-stent stenosis as effectively as SES without the delayed endothelial healing effects of SES in a porcine coronary artery model. This nanotechnology platform could be developed into a safer and more effective device in the future.

摘要

目的

目前市售的药物洗脱支架的使用存在安全隐患,包括晚期血栓形成增加,这主要被认为是由于内皮愈合效果延迟(内皮细胞再内皮化受损导致异常炎症和纤维蛋白沉积)。我们最近开发了一种使用新型阳离子电沉积技术的可生物吸收聚合物纳米颗粒(NP)洗脱支架。他汀类药物被认为能抑制血管平滑肌细胞(VSMC)的增殖,并促进血管愈合。因此,我们假设他汀类药物结合的 NP 洗脱支架不会延迟内皮愈合效果,从而减轻支架内狭窄。

方法

在六种市售的他汀类药物中,发现匹伐他汀(Pitava)在体外对 VSMC 增殖和内皮再生的作用最强。因此,我们制定了匹伐他汀 NP 洗脱支架(每个支架 20µg 匹伐他汀)。

结果

在猪冠状动脉模型中,匹伐他汀 NP 洗脱支架减轻支架内狭窄的效果与聚合物涂层西罗莫司洗脱支架(SES)一样有效。在 SES 部位观察到内皮愈合效果延迟,而在匹伐他汀 NP 洗脱支架部位则没有观察到这种效果。

结论

在猪冠状动脉模型中,匹伐他汀 NP 洗脱支架减轻支架内狭窄的效果与 SES 一样有效,而没有 SES 的内皮愈合效果延迟。这个纳米技术平台在未来可能会发展成为一种更安全、更有效的装置。

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