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患者特异性动脉系统血流振荡。

Patient-specific arterial system flow oscillation.

作者信息

Fytanidis Dk, Soulis Jv, Giannoglou Gd

机构信息

Fluid Mechanics Division, School of Engineering, Democrition University of Thrace, Xanthi, Greece.

Cardiovascular Engineering and Atherosclerosis Laboratory, 1 Cardiology Department, AHEPA University Hospital, Medical School, Aristotle University of Thessaloniki, Thessaloniki, Greece.

出版信息

Hippokratia. 2014 Apr;18(2):162-5.

PMID:25336881
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4201404/
Abstract

BACKGROUND

Atherosclerosis formation depends on the biomechanical blood flow properties. The temporal variation during the cardiac cycle has been proposed as a decisive atherogenic factor. Patient-specific (complex configuration) of the vessel promotes flow disturbances. The present study analyses the factors simulating pulsatile blood flow in the human arterial system using patient-specific geometry.

METHODS

With the aid of numerical techniques, we examine the relation between time-Averaged Wall Shear Stress (AWSS), time-Averaged Wall Shear Stress Vector (AWSSV), Oscillatory Shear Index (OSI) and Relative Residence Time (RRT).

RESULTS

The velocity vector oscillates and at the same time alters its direction in places with low AWSS values. Low AWSS and high OSI values do not always collocate. AWSSV tends to alter its values, compared to AWSS, in regions where AWSS is low. RRT present high values in areas with low AWSS. The inverse proportionality relation between RRT and AWSSV is established.

CONCLUSIONS

Regional differences between AWSS magnitude, OSI and RRT, may answer the question as to where atherosclerotic lesions predominately develop and progress at specific aortic regions. This analysis gives information for deeper understanding of the atherosclerosis mechanisms.

摘要

背景

动脉粥样硬化的形成取决于生物力学血流特性。心动周期中的时间变化已被认为是一个决定性的致动脉粥样硬化因素。血管的个体特异性(复杂结构)会促进血流紊乱。本研究使用个体特异性几何结构分析模拟人体动脉系统中脉动血流的因素。

方法

借助数值技术,我们研究了时间平均壁面切应力(AWSS)、时间平均壁面切应力矢量(AWSSV)、振荡切变指数(OSI)和相对停留时间(RRT)之间的关系。

结果

速度矢量振荡,同时在AWSS值较低的地方改变其方向。低AWSS值和高OSI值并不总是同时出现。与AWSS相比,在AWSS较低的区域,AWSSV往往会改变其值。RRT在AWSS较低的区域呈现高值。建立了RRT与AWSSV之间的反比例关系。

结论

AWSS大小、OSI和RRT之间的区域差异,可能回答了动脉粥样硬化病变在特定主动脉区域主要在何处发生和进展的问题。该分析为更深入理解动脉粥样硬化机制提供了信息。

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