On the Importance of Blood Rheology for Bulk Flow in Hemodynamic Models of the Carotid Bifurcation

Overview

Journal J Biomech

Specialty Physiology

Date 2011 Jul 15

PMID 21752380

Citations 26

Authors

Umberto Morbiducci

Diego Gallo

Diana Massai

Raffaele Ponzini

Marco A Deriu

Luca Antiga

Alberto Redaelli

Franco M Montevecchi

Affiliations

Soon will be listed here.

Abstract

Here we present a study on the impact of assumptions on image-based hemodynamic simulations of healthy carotid bifurcations. In particular, we evaluate to which extent assumptions on blood rheology influence bulk flow features, driven by the fact that few studies have provided adequate insights into the influence of assumptions to confidently model the 4D hemodynamics within the bifurcation. The final goal is to complement, integrate and extend with a quantitative characterization of the bulk flow the description currently adopted to classify altered hemodynamics, which is based on wall shear stress (WSS). Hemodynamic simulations of two image-based carotid bifurcation geometries were carried out assuming a reference Newtonian viscosity, two non-Newtonian rheology models and Newtonian viscosities based on characteristic shear rates. WSS-based and Lagrangian-based metrics for helical flow quantification and for vorticity dynamics quantification were calculated. Our findings suggest that the assumption of Newtonian rheology: (1) could be reasonable for bulk flow metrics (differences from non-Newtonian behavior are lower than 10%); (2) influences at different levels the WSS-based indicators, depending on the bifurcation model, even if in our study it is lower than the major source of uncertainty as recognized by the literature (i.e., uncertainty on geometry reconstruction).

Citing Articles

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Vortical Structures Promote Atheroprotective Wall Shear Stress Distributions in a Carotid Artery Bifurcation Model.

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Fluid flow to mimic organ function in 3D models.

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Simulation of Mechanical Heart Valve Dysfunction and the Non-Newtonian Blood Model Approach.

Chen A, Basri A, Ismail N, Tamagawa M, Zhu D, Ahmad K Appl Bionics Biomech. 2022; 2022:9612296.

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