A computational study of red blood cell deformability effect on hemodynamic alteration in capillary vessel networks

A computational study of red blood cell deformability effect on hemodynamic alteration in capillary vessel networks

Capillary blood vessels, the smallest vessels in the body, form an intricate network with constantly bifurcating, merging and winding vessels. Red blood cells (RBCs) must navigate through such complex microvascular networks in order to maintain tissue perfusion and oxygenation. Normal, healthy RBCs...

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Bibliographic Details
Published in:Scientific reports Vol. 12; no. 1; p. 4304
Main Authors: Ebrahimi, Saman, Bagchi, Prosenjit
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 11-03-2022
Nature Publishing Group
Nature Portfolio
Subjects:
631/443/1338/2729
639/166
639/166/985
Blood
Blood flow
Blood vessels
Cell migration
Computer applications
Deformability
Erythrocyte Deformability - physiology
Erythrocytes
Erythrocytes - physiology
Hematocrit
Hemodynamics
Humanities and Social Sciences
Microvasculature
Microvessels - physiology
multidisciplinary
Oxygenation
Perfusion
Science
Science (multidisciplinary)
Shear stress
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Summary:Capillary blood vessels, the smallest vessels in the body, form an intricate network with constantly bifurcating, merging and winding vessels. Red blood cells (RBCs) must navigate through such complex microvascular networks in order to maintain tissue perfusion and oxygenation. Normal, healthy RBCs are extremely deformable and able to easily flow through narrow vessels. However, RBC deformability is reduced in many pathological conditions and during blood storage. The influence of reduced cell deformability on microvascular hemodynamics is not well established. Here we use a high-fidelity, 3D computational model of blood flow that retains exact geometric details of physiologically realistic microvascular networks, and deformation of every one of nearly a thousand RBCs flowing through the networks. We predict that reduced RBC deformability alters RBC trafficking with significant and heterogeneous changes in hematocrit. We quantify such changes along with RBC partitioning and lingering at vascular bifurcations, perfusion and vascular resistance, and wall shear stress. We elucidate the cellular-scale mechanisms that cause such changes. We show that such changes arise primarily due to the altered RBC dynamics at vascular bifurcations, as well as cross-stream migration. Less deformable cells tend to linger less at majority of bifurcations increasing the fraction of RBCs entering the higher flow branches. Changes in vascular resistance also seen to be heterogeneous and correlate with hematocrit changes. Furthermore, alteration in RBC dynamics is shown to cause localized changes in wall shear stress within vessels and near vascular bifurcations. Such heterogeneous and focal changes in hemodynamics may be the cause of morphological abnormalities in capillary vessel networks as observed in several diseases.
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ISSN:2045-2322
2045-2322
DOI:10.1038/s41598-022-08357-z