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Assessment of Rheological Models Applied to Blood Flow in Human Thoracic Aorta

Purpose: The purpose of this study is to assess the importance of non-Newtonian rheological models on blood flow in the human thoracic aorta. Methods: The pulsatile flow in the aorta is simulated using the models of Casson, Quemada and Walburn–Schneck in addition to a case of fixed (Newtonian) visco...

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Autores principales: Fuchs, Alexander, Berg, Niclas, Fuchs, Laszlo, Prahl Wittberg, Lisa
Formato: Online Artículo Texto
Lenguaje:English
Publicado: MDPI 2023
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10669506/
https://www.ncbi.nlm.nih.gov/pubmed/38002364
http://dx.doi.org/10.3390/bioengineering10111240
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author Fuchs, Alexander
Berg, Niclas
Fuchs, Laszlo
Prahl Wittberg, Lisa
author_facet Fuchs, Alexander
Berg, Niclas
Fuchs, Laszlo
Prahl Wittberg, Lisa
author_sort Fuchs, Alexander
collection PubMed
description Purpose: The purpose of this study is to assess the importance of non-Newtonian rheological models on blood flow in the human thoracic aorta. Methods: The pulsatile flow in the aorta is simulated using the models of Casson, Quemada and Walburn–Schneck in addition to a case of fixed (Newtonian) viscosity. The impact of the four rheological models (using constant hematocrit) was assessed with respect to (i) magnitude and deviation of the viscosity relative to a reference value (the Newtonian case); (ii) wall shear stress (WSS) and its time derivative; (iii) common WSS-related indicators, OSI, TAWSS and RRT; (iv) relative volume and surface-based retrograde flow; and (v) the impact of rheological models on the transport of small particles in the thoracic aorta. Results: The time-dependent flow in the thoracic aorta implies relatively large variations in the instantaneous WSS, due to variations in the instantaneous viscosity by as much as an order of magnitude. The largest effect was observed for low shear rates (tens s(−1)). The different viscosity models had a small impact in terms of time- and spaced-averaged quantities. The significance of the rheological models was clearly demonstrated in the instantaneous WSS, for the space-averaged WSS (about 10%) and the corresponding temporal derivative of WSS (up to 20%). The longer-term accumulated effect of the rheological model was observed for the transport of spherical particles of 2 mm and 2 mm in diameter (density of 1200 kg/m(3)). Large particles’ total residence time in the brachiocephalic artery was 60% longer compared to the smaller particles. For the left common carotid artery, the opposite was observed: the smaller particles resided considerably longer than their larger counterparts. Conclusions: The dependence on the non-Newtonian properties of blood is mostly important at low shear regions (near walls, stagnation regions). Time- and space-averaging parameters of interest reduce the impact of the rheological model and may thereby lead to under-estimation of viscous effects. The rheological model affects the local WSS and its temporal derivative. In addition, the transport of small particles includes the accumulated effect of the blood rheological model as the several forces (e.g., drag, added mass and lift) acting on the particles are viscosity dependent. Mass transport is an essential factor for the development of pathologies in the arterial wall, implying that rheological models are important for assessing such risks.
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spelling pubmed-106695062023-10-24 Assessment of Rheological Models Applied to Blood Flow in Human Thoracic Aorta Fuchs, Alexander Berg, Niclas Fuchs, Laszlo Prahl Wittberg, Lisa Bioengineering (Basel) Article Purpose: The purpose of this study is to assess the importance of non-Newtonian rheological models on blood flow in the human thoracic aorta. Methods: The pulsatile flow in the aorta is simulated using the models of Casson, Quemada and Walburn–Schneck in addition to a case of fixed (Newtonian) viscosity. The impact of the four rheological models (using constant hematocrit) was assessed with respect to (i) magnitude and deviation of the viscosity relative to a reference value (the Newtonian case); (ii) wall shear stress (WSS) and its time derivative; (iii) common WSS-related indicators, OSI, TAWSS and RRT; (iv) relative volume and surface-based retrograde flow; and (v) the impact of rheological models on the transport of small particles in the thoracic aorta. Results: The time-dependent flow in the thoracic aorta implies relatively large variations in the instantaneous WSS, due to variations in the instantaneous viscosity by as much as an order of magnitude. The largest effect was observed for low shear rates (tens s(−1)). The different viscosity models had a small impact in terms of time- and spaced-averaged quantities. The significance of the rheological models was clearly demonstrated in the instantaneous WSS, for the space-averaged WSS (about 10%) and the corresponding temporal derivative of WSS (up to 20%). The longer-term accumulated effect of the rheological model was observed for the transport of spherical particles of 2 mm and 2 mm in diameter (density of 1200 kg/m(3)). Large particles’ total residence time in the brachiocephalic artery was 60% longer compared to the smaller particles. For the left common carotid artery, the opposite was observed: the smaller particles resided considerably longer than their larger counterparts. Conclusions: The dependence on the non-Newtonian properties of blood is mostly important at low shear regions (near walls, stagnation regions). Time- and space-averaging parameters of interest reduce the impact of the rheological model and may thereby lead to under-estimation of viscous effects. The rheological model affects the local WSS and its temporal derivative. In addition, the transport of small particles includes the accumulated effect of the blood rheological model as the several forces (e.g., drag, added mass and lift) acting on the particles are viscosity dependent. Mass transport is an essential factor for the development of pathologies in the arterial wall, implying that rheological models are important for assessing such risks. MDPI 2023-10-24 /pmc/articles/PMC10669506/ /pubmed/38002364 http://dx.doi.org/10.3390/bioengineering10111240 Text en © 2023 by the authors. https://creativecommons.org/licenses/by/4.0/Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
spellingShingle Article
Fuchs, Alexander
Berg, Niclas
Fuchs, Laszlo
Prahl Wittberg, Lisa
Assessment of Rheological Models Applied to Blood Flow in Human Thoracic Aorta
title Assessment of Rheological Models Applied to Blood Flow in Human Thoracic Aorta
title_full Assessment of Rheological Models Applied to Blood Flow in Human Thoracic Aorta
title_fullStr Assessment of Rheological Models Applied to Blood Flow in Human Thoracic Aorta
title_full_unstemmed Assessment of Rheological Models Applied to Blood Flow in Human Thoracic Aorta
title_short Assessment of Rheological Models Applied to Blood Flow in Human Thoracic Aorta
title_sort assessment of rheological models applied to blood flow in human thoracic aorta
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10669506/
https://www.ncbi.nlm.nih.gov/pubmed/38002364
http://dx.doi.org/10.3390/bioengineering10111240
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