PLLA金属丝编织支架力学性能的实验研究。

A. Lucchetti, C. Emonts, Akram Idrissi, T. Gries, T. Vaughan
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引用次数: 1

摘要

我们目前对自膨胀金属丝编织支架性能的大部分理解是基于对镍钛诺基或聚合物非生物可吸收(例如PET, PP等)设备的机械测试。目前关于生物可吸收装置的数据较少,其特点是支架的公称直径大(D≤6mm),而描述小直径金属丝编织生物可吸收装置(D≤5mm)机械性能的数据明显缺乏。本文系统研究了不同编织角度(α=45°、α=30°、α=20°)、丝径(d=100μm、d=150μm)、丝数(n=24、n=48)、编织模式(1:1-1、2:1、1:1-2)、支架直径(d= 5mm、d= 4mm、d= 2.5mm)的生物可吸收聚乳酸(PLLA)丝编织支架的力学性能。通过评估装置的径向、纵向和弯曲响应进行了力学表征。我们的研究结果表明,较小的编织角度、较大的金属丝直径、较多的金属丝数量和较小的支架直径导致支架在三种力学测试中的力学性能都有所提高。研究发现,聚合物编织支架的几何特征可以适应于实现与金属装置相似的性能。特别是,当编织角度较低时,当编织模式遵循两根金属丝平行(1:1-2)的一上一下配置时,支架机械性能显著增加。最后,研究表明,文献中提出的金属编织支架的数学模型也可以提供合理的聚合物支架性能预测,但只是在金属丝摩擦不占主导地位的情况下。本研究提供了广泛的实验数据,可为进一步开发编织生物可吸收装置提供重要参考。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
An experimental investigation of the mechanical performance of PLLA wire-braided stents.
Much of our current understanding of the performance of self-expanding wire-braided stents is based on mechanical testing of Nitinol-based or polymeric non-bioresorbable (e.g. PET, PP etc.) devices. The small amount of data present for bioresorbable devices characterizes stents with big nominal diameters (D>6mm), with a distinct lack of data describing the mechanical performance of small-diameter wire-braided bioresorbable devices (D≤5mm). This study presents a systematic investigation of the mechanical performance of wire-braided bioresorbable Poly-L-Lactic Acid (PLLA) stents having different braiding angles (α=45° , α=30°, and α=20°), wire diameters (d=100μm, and d=150μm), wire count (n=24 and n=48), braiding patterns (1:1-1, 2:2-1 and 1:1-2) and stent diameters (D=5mm, D=4mm, and D=2.5mm). Mechanical characterisation was carried out by evaluating the radial, longitudinal and bending response of the devices. Our results showed that smaller braid angles, larger wire diameters, higher number of wires and smaller stent diameter led to an increase in the stent mechanical properties across each of the three mechanical tests performed. It was found that geometrical features of a polymeric braided stent could be adapted to achieve a similar performance to the one of a metallic device. In particular, substantial increases in stent mechanical properties were found for a low braiding angle and when the braiding pattern followed a one-over-one-under configuration with two wires in parallel (1:1-2). Finally, it was shown that a mathematical model proposed in literature for metal braided stents can provide reasonable predictions also of polymeric stent performance but just in circumstances where wire friction does not have a dominant role. This study presents a wide range of experimental data that can provide an important reference for further development of wire-braided bioresorbable devices.
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