Fluid-Structure Interaction in Biological Media / FSI
Saeed Bahrami; Mahmood Norouzi
Volume 10, Issue 2 , August 2016, , Pages 175-186
Abstract
Increasing the cardiovascular disease had led to the researchers to investigate the blood flow more than before. In this article the effects of artery elasticity on hemodynamic parameters with concerning the interaction between blood and the vessel’s wall had been investigated. The wall shear stress ...
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Increasing the cardiovascular disease had led to the researchers to investigate the blood flow more than before. In this article the effects of artery elasticity on hemodynamic parameters with concerning the interaction between blood and the vessel’s wall had been investigated. The wall shear stress had changed with different times and cannot send the congestion of the vessels. From this point the oscillatory shear index had been said the shear stress without the time average. In this study a 3D model from the left coronary bifurcation with 4 models of wall had been investigated. The result from a pulsatile flow from a non-newtonian flow with the method of two ways coupling by using the method of arbitrary Lagrangian–Eulerian had been calculated. The observation had showed a 13 percent decreasing in the profile of velocities at the bifurcation place in that in the hyperelastic model had the highest subtraction. Also by increasing the toughness of the wall the velocity profile and oscillator shear stress were increased. The average shear stress in the model of rigid had showed the 28 percent difference in comparison with the hyperelastic model. By comparing the results with clinical data showed that, the places with average shear stress 1.10 pa and less than that with presenting the oscillatory shear index is more than 0.3 that can be a potential dangerous places in forming atherosclerosis oscillatory shear index plaque especially in the posterior after the bifurcation. Meanwhile in the hyperelastic model the results are more precise than the other models.
Fluid-Structure Interaction in Biological Media / FSI
Saeed Nahidi; Alireza Hossein-Nezhad; Nasser Fatouraee; Zahra Heidari
Volume 6, Issue 1 , June 2012, , Pages 71-79
Abstract
Hemodynamic parameters are always affected by stenosis severity of arterial and these parameters in their turn have influence on the development of atherosclerosis. In this paper, By considering three different stenosis severity, the effects of wall porosity assumption on the hemodynamic parameters of ...
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Hemodynamic parameters are always affected by stenosis severity of arterial and these parameters in their turn have influence on the development of atherosclerosis. In this paper, By considering three different stenosis severity, the effects of wall porosity assumption on the hemodynamic parameters of a stenosed artery with a two-layer flexible wall (intima-media, adventitia), in which inner layer (intima-media) assumed porous, is numerically investigated, using Porous Fluid Structure Interaction (PFSI) model. Blood is assumed as an incompressible non-Newtonian fluid with pulsatile flow condition. In this investigation, the results show that the permeability assumption has much influenced on the hemodynamic characteristics so that the comparison of the results using PFSI with those of a non-porous model show 6% decrease in shear stress, 30% increase in displacement and more than 72% increase in effective stress in the porous layer.