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基于图像的支架冠状动脉分叉模型的计算流体动力学模拟。

Computational fluid dynamic simulations of image-based stented coronary bifurcation models.

机构信息

Chemistry, Materials and Chemical Engineering Department, Politecnico di Milano, Milan, Italy.

出版信息

J R Soc Interface. 2013 May 15;10(84):20130193. doi: 10.1098/rsif.2013.0193. Print 2013 Jul 6.

DOI:10.1098/rsif.2013.0193
PMID:23676893
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3673154/
Abstract

One of the relevant phenomenon associated with in-stent restenosis in coronary arteries is an altered haemodynamics in the stented region. Computational fluid dynamics (CFD) offers the possibility to investigate the haemodynamics at a level of detail not always accessible within experimental techniques. CFD can quantify and correlate the local haemodynamics structures which might lead to in-stent restenosis. The aim of this work is to study the fluid dynamics of realistic stented coronary artery models which replicate the complete clinical procedure of stent implantation. Two cases of pathologic left anterior descending coronary arteries with their bifurcations are reconstructed from computed tomography angiography and conventional coronary angiography images. Results of wall shear stress and relative residence time show that the wall regions more prone to the risk of restenosis are located next to stent struts, to the bifurcations and to the stent overlapping zone for both investigated cases. Considering a bulk flow analysis, helical flow structures are generated by the curvature of the zone upstream from the stent and by the bifurcation regions. Helical recirculating microstructures are also visible downstream from the stent struts. This study demonstrates the feasibility to virtually investigate the haemodynamics of patient-specific coronary bifurcation geometries.

摘要

与冠状动脉内支架再狭窄相关的一个相关现象是支架区域血流动力学的改变。计算流体动力学(CFD)提供了一种可能性,可以在实验技术通常无法达到的细节水平上研究血液动力学。CFD 可以量化和关联局部血液动力学结构,这些结构可能导致支架内再狭窄。这项工作的目的是研究真实的支架冠状动脉模型的流体动力学,这些模型复制了支架植入的完整临床过程。从计算机断层血管造影和常规冠状动脉造影图像重建了两条病理性左前降支冠状动脉及其分支的模型。壁面切应力和相对停留时间的结果表明,在两种情况下,更易发生再狭窄风险的壁区位于支架支柱、分叉和支架重叠区附近。考虑到主流分析,由支架上游区域的曲率和分叉区域产生螺旋流动结构。在支架支柱下游也可以看到螺旋再循环微结构。这项研究证明了虚拟研究患者特定冠状动脉分叉几何形状血液动力学的可行性。

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