The influence of red blood cell deformability on hematocrit profiles and platelet margination

The influence of red blood cell (RBC) deformability in whole blood on platelet margination is investigated using confocal microscopy measurements of flowing human blood and cell resolved blood flow simulations. Fluorescent platelet concentrations at the wall of a glass chamber are measured using con...

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Veröffentlicht in:	PLoS computational biology 2020-03, Vol.16 (3), p.e1007716-e1007716
Hauptverfasser:	Czaja, Benjamin, Gutierrez, Mario, Závodszky, Gábor, de Kanter, David, Hoekstra, Alfons, Eniola-Adefeso, Omolola
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Sprache:	eng
Schlagworte:	Biology and Life Sciences Blood Blood flow Blood platelets Blood vessels Chemical engineering Collisions Confocal microscopy Deformability Deformation Diabetes Erythrocytes Experiments Flow Flow (Dynamics) Flow simulation Fluorescence Formability Gutierrez, Mario Hematocrit Hemoglobin Informatics Medicine and Health Sciences Microscopy Oxidative stress Physical Sciences Platelets Red blood cells Research and Analysis Methods Rheology Sickle cell anemia Software Stiffness Supervision
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creator	Czaja, Benjamin Gutierrez, Mario Závodszky, Gábor de Kanter, David Hoekstra, Alfons Eniola-Adefeso, Omolola
description	The influence of red blood cell (RBC) deformability in whole blood on platelet margination is investigated using confocal microscopy measurements of flowing human blood and cell resolved blood flow simulations. Fluorescent platelet concentrations at the wall of a glass chamber are measured using confocal microscopy with flowing human blood containing varying healthy-to-stiff RBC fractions. A decrease is observed in the fluorescent platelet signal at the wall due to the increase of stiffened RBCs in flow, suggesting a decrease of platelet margination due to an increased fraction of stiffened RBCs present in the flow. In order to resolve the influence of stiffened RBCs on platelet concentration at the channel wall, cell-pair and bulk flow simulations are performed. For homogeneous collisions between RBC pairs, a decrease in final displacement after a collision with increasing membrane stiffness is observed. In heterogeneous collisions between healthy and stiff RBC pairs, it is found that the stiffened RBC is displaced most. The influence of RBC deformability on collisions between RBCs and platelets was found to be negligible due to their size and mass difference. For a straight vessel geometry with varying healthy-to-stiff RBC ratios, a decrease was observed in the red blood cell-free layer and platelet margination due to an increase in stiffened RBCs present in flow.
doi_str_mv	10.1371/journal.pcbi.1007716
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Fluorescent platelet concentrations at the wall of a glass chamber are measured using confocal microscopy with flowing human blood containing varying healthy-to-stiff RBC fractions. A decrease is observed in the fluorescent platelet signal at the wall due to the increase of stiffened RBCs in flow, suggesting a decrease of platelet margination due to an increased fraction of stiffened RBCs present in the flow. In order to resolve the influence of stiffened RBCs on platelet concentration at the channel wall, cell-pair and bulk flow simulations are performed. For homogeneous collisions between RBC pairs, a decrease in final displacement after a collision with increasing membrane stiffness is observed. In heterogeneous collisions between healthy and stiff RBC pairs, it is found that the stiffened RBC is displaced most. The influence of RBC deformability on collisions between RBCs and platelets was found to be negligible due to their size and mass difference. 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red blood cell (RBC) deformability in whole blood on platelet margination is investigated using confocal microscopy measurements of flowing human blood and cell resolved blood flow simulations. Fluorescent platelet concentrations at the wall of a glass chamber are measured using confocal microscopy with flowing human blood containing varying healthy-to-stiff RBC fractions. A decrease is observed in the fluorescent platelet signal at the wall due to the increase of stiffened RBCs in flow, suggesting a decrease of platelet margination due to an increased fraction of stiffened RBCs present in the flow. In order to resolve the influence of stiffened RBCs on platelet concentration at the channel wall, cell-pair and bulk flow simulations are performed. For homogeneous collisions between RBC pairs, a decrease in final displacement after a collision with increasing membrane stiffness is observed. In heterogeneous collisions between healthy and stiff RBC pairs, it is found that the stiffened RBC is displaced most. The influence of RBC deformability on collisions between RBCs and platelets was found to be negligible due to their size and mass difference. 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subjects	Biology and Life Sciences Blood Blood flow Blood platelets Blood vessels Chemical engineering Collisions Confocal microscopy Deformability Deformation Diabetes Erythrocytes Experiments Flow Flow (Dynamics) Flow simulation Fluorescence Formability Gutierrez, Mario Hematocrit Hemoglobin Informatics Medicine and Health Sciences Microscopy Oxidative stress Physical Sciences Platelets Red blood cells Research and Analysis Methods Rheology Sickle cell anemia Software Stiffness Supervision
title	The influence of red blood cell deformability on hematocrit profiles and platelet margination
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