A Study on the Compliance of a Right Coronary Artery and Its Impact on Wall Shear Stress

Overview

Journal J Biomech Eng

Publisher American Society of Mechanical Engineers

Date 2008 Jul 8

PMID 18601456

Citations 17

Authors

Dehong Zeng

Evangelos Boutsianis

Marc Ammann

Kevin Boomsma

Simon Wildermuth

Dimos Poulikakos

Affiliations

Soon will be listed here.

Abstract

A computational model incorporating physiological motion and uniform transient wall deformation of a branchless right coronary artery (RCA) was developed to assess the influence of artery compliance on wall shear stress (WSS). Arterial geometry and deformation were derived from modern medical imaging techniques, whereas the blood flow was solved numerically employing a moving-grid approach using a well-validated in-house finite element code. The simulation results indicate that artery compliance affects the WSS in the RCA heterogeneously, with the distal region mostly experiencing these effects. Under physiological inflow conditions, coronary compliance contributed to phase changes in the WSS time history, without affecting the temporal gradient of the local WSS nor the bounds of the WSS magnitude. Compliance does not cause considerable changes to the topology of WSS vector patterns nor to the localization of WSS minima along the RCA. We conclude that compliance is not an important factor affecting local hemodynamics in the proximal region of the RCA while the influence of compliance in the distal region needs to be evaluated in conjunction with the outflow to the myocardium through the major branches of the RCA.

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