聚l -乳酸心血管应用的实验与计算研究:最新进展

Raasti Naseem, Liguo Zhao, Yang Liu, Vadim V. Silberschmidt
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引用次数: 18

摘要

支架通常用于医疗程序,以减轻冠心病的症状,一种普遍的现代社会疾病。这些结构用于维持血管通畅和恢复血液流动。传统的支架是由不锈钢或钴铬等金属制成的;然而,这些支架有已知的缺点。暂时性支架的出现越来越受欢迎,在病变动脉壁愈合的同时,这种结构可以维持一段时间。聚合物在医疗器械领域占主导地位,用于缝合线、支架和螺钉。由于其良好的机械和生物特性以及自然降解的能力。聚乳酸是一种非常通用的聚合物,其特性很容易根据应用进行定制。其在支架领域的主导地位不断增强,2016年第一个聚合物支架获得FDA批准。PLLA生物可吸收材料仍然存在一些挑战,特别是在了解其力学响应,评估其降解变化以及与金属药物洗脱支架性能的比较方面。目前,对这些支架的预降解性能和降解性能进行评价的工作还很缺乏。此外,还没有建立材料模型来考虑pla的非线性粘弹性行为及其随服役退化的演变。通过实验分析以及分析和数值研究来评估这些特征,将为这些结构的设计和优化提供强大的工具,从而支持它们在支架置入中的广泛应用。本文综述了最近研究聚乳酸的力学和计算性能及其在支架应用中的应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Experimental and computational studies of poly-L-lactic acid for cardiovascular applications: recent progress

Stents are commonly used in medical procedures to alleviate the symptoms of coronary heart disease, a prevalent modern society disease. These structures are employed to maintain vessel patency and restore blood flow. Traditionally stents are made of metals such as stainless steel or cobalt chromium; however, these scaffolds have known disadvantages. An emergence of transient scaffolds is gaining popularity, with the structure engaged for a required period whilst healing of the diseased arterial wall occurs. Polymers dominate a medical device sector, with incorporation in sutures, scaffolds and screws. Thanks to their good mechanical and biological properties and their ability to degrade naturally. Polylactic acid is an extremely versatile polymer, with its properties easily tailored to applications. Its dominance in the stenting field increases continually, with the first polymer scaffold gaining FDA approval in 2016. Still some challenges with PLLA bioresorbable materials remain, especially with regard to understanding their mechanical response, assessment of its changes with degradation and comparison of their performance with that of metallic drug-eluting stent. Currently, there is still a lack of works on evaluating both the pre-degradation properties and degradation performance of these scaffolds. Additionally, there are no established material models incorporating non-linear viscoelastic behaviour of PLLA and its evolution with in-service degradation. Assessing these features through experimental analysis accompanied by analytical and numerical studies will provide powerful tools for design and optimisation of these structures endorsing their broader use in stenting. This overview assesses the recent studies investigating mechanical and computational performance of poly(l-lactic) acid and its use in stenting applications.

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