Iranian Journal of Biomedical Engineering (IJBME)
نشریه علمی مهندسی پزشکی زیستی

The effect of wall shear stress and oscillatory shear index on probability of atherosclerosis plaque formation in normal left coronary artery tree

Document Type : Full Research Paper

Authors

Saeed Bahrami 1
Faramarz Firouzi 2

1 M.Sc Student, Mechanical EngineeringDepartment, Shahrood University of Technology, Shahrood, Iran

2 Assistant Professor, Biomechanic Department, Biomedical Engineering Faculty, Islamic Azad University of Mashhad, Iran

https://doi.org/10.22041/ijbme.2016.22693
Abstract
It is accepted that wall shear stress (WSS) and Oscillatory Shear index (OSI) are strong hemodynamic factors to development of atherosclerotic (AS) plaque. Sometimes, OSI has an important effect on AS plaque formation, because WSSdoesn't make it happenalone. Most computational fluid dynamic (CFD) simulations were performed on left main coronary bifurcation geometry, and whole left coronary artery tree has not been investigated by now. In this paper, a thorough three-dimensional model of left coronary artery tree was considered, including left main coronary, left anterior descending and its branches, left circumflex artery and its branches. Effects of cardiac motions on vessel wall of left coronary were considered. The governingNavier–Stokes equations for pulsatile flow and incompressible non-Newtonian blood was analyzed with finite element method. The study concentrates on shear stress distribution and OSI distribution on the vessel wall. Comparing the results of this study with previous clinical investigations shows that the regions with low wall shear stress (equal to and less than 1.5[Pa]) along with high OSI value (equal to and more than 0.3) have potential to development of AS plaque.So it can be predicted that the LAD region after D3 and the bifurcation of LCxA-OM have high potential to development of AS, in addition to the bifurcation of LCxA-LMCA which had been specified before.

Keywords

Computational fluid dynamic
Artery stenosis
Shear stressoscillatory
Left coronary tree

Subjects

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Iranian Journal of Biomedical Engineering (IJBME)
Volume 9, Issue 3
Autumn 2015
Pages 293-303

  • Receive Date 19 July 2016
  • Accept Date 21 November 2016

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