使用静态、动态和猪离体模型评估可扩张镁基螺旋支架。

Expandable Mg-based Helical Stent Assessment using Static, Dynamic, and Porcine Ex Vivo Models.

机构信息

NSF-Engineering Research Center, North Carolina A&T State University, Greensboro, NC, 27411, USA.

FIT BEST Laboratory, Department of Chemical, Biological, and Bio Engineering, North Carolina A&T State University, Greensboro, NC, 27411, USA.

出版信息

Sci Rep. 2017 Apr 26;7(1):1173. doi: 10.1038/s41598-017-01214-4.

DOI:10.1038/s41598-017-01214-4

PMID:28446750

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5430820/

Abstract

A bioresorbable metallic helical stent was explored as a new device opportunity (magnesium scaffold), which can be absorbed by the body without leaving a trace and simultaneously allowing restoration of vasoreactivity with the potential for vessel remodeling. In this study, developed Mg-based helical stent was inserted and expanded in vessels with subsequent degradation in various environments including static, dynamic, and porcine ex vivo models. By assessing stent degradation in three different environments, we observed: (1) stress- and flow-induced degradation; (2) a high degradation rate in the dynamic reactor; (3) production of intermediate products (MgO/Mg(OH) and Ca/P) during degradation; and (4) intermediate micro-gas pocket formation in the neighboring tissue ex vivo model. Overall, the expandable Mg-based helical stent employed as a scaffold performed well, with expansion rate (>100%) in porcine ex vivo model.

摘要

探索了一种可生物吸收的金属螺旋支架作为一种新的器械机会（镁支架），它可以被身体吸收而不留痕迹，同时允许恢复血管反应性，并具有血管重塑的潜力。在这项研究中，开发的基于镁的螺旋支架被插入并扩张在血管中，随后在包括静态、动态和猪离体模型在内的各种环境中降解。通过在三种不同环境下评估支架降解，我们观察到：（1）应力和流动诱导的降解；（2）在动态反应器中降解速度快；（3）降解过程中产生中间产物（MgO/Mg(OH) 和 Ca/P）；（4）在离体模型中相邻组织中形成中间微气袋。总的来说，作为支架使用的可扩张镁基螺旋支架表现良好，在猪离体模型中的扩张率（>100%）。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3b08/5430820/35f6b15bdb89/41598_2017_1214_Fig1_HTML.jpg

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使用静态、动态和猪离体模型评估可扩张镁基螺旋支架。

Expandable Mg-based Helical Stent Assessment using Static, Dynamic, and Porcine Ex Vivo Models.

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