A Study of Flow in Atherosclerotic Arteries Using Virtual and In-Vitro Models and Its Implications Regarding Vessel Erosion

Volume 5: Biomedical and Biotechnology Pub Date : 2021-11-01 DOI:10.1115/imece2021-70553

M. Salinas, Evan Weber, Paula Veras De La Rocha, Caylee Cox, Jonathon Yanello

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Abstract

Despite the prevalence of atherosclerosis in the western world, many questions have yet to be answered about the origin, development, and failure of atherosclerotic lesions. To better understand atherosclerotic events such as formation and vessel erosion, a bioreactor chamber was developed using similitude theory together with human coronary artery parameters for geometry and flow conditions. The chamber was virtually validated using Ansys CFX. Simulations were performed under laminar flow conditions, density = 1060 kg/m3, and viscosity = 3.5 centipoise. We applied a velocity waveform at the inlet modified through similitude theory to match that of a human coronary artery. Zero relative-pressure condition was set at the outlet. No slip boundary conditions were prescribed at the coronary artery walls. The results showed that the novel bioreactor can create flow disturbances like those observed in human atherosclerotic arteries. In our future work, we would like to include vessel compliance and experimental data utilizing porcine arterial tissue. Our overall goal is to delineate the entire repertoire of events that happen during vessel erosion.

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使用虚拟和体外模型研究动脉粥样硬化动脉的血流及其对血管侵蚀的影响

尽管动脉粥样硬化在西方世界普遍存在，但许多关于动脉粥样硬化病变的起源、发展和失败的问题尚未得到回答。为了更好地了解动脉粥样硬化事件，如形成和血管侵蚀，利用相似理论和人类冠状动脉的几何和流动条件参数开发了一个生物反应器室。使用Ansys CFX对该腔室进行了虚拟验证。在层流条件下进行模拟，密度为1060 kg/m3，粘度为3.5厘泊。我们应用了通过相似理论修正的入口速度波形，以匹配人类冠状动脉的速度波形。出口相对压力为零。冠状动脉壁无滑移边界条件。结果表明，这种新型生物反应器可以像在人类动脉粥样硬化动脉中观察到的那样产生血流紊乱。在我们未来的工作中，我们希望包括血管顺应性和利用猪动脉组织的实验数据。我们的总体目标是描述在血管侵蚀过程中发生的所有事件。

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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Volume 5: Biomedical and Biotechnology

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