Shear stress variation induced by red blood cell motion in microvessel

Annals of Biomedical Engineering

Volumn 38, Issue 8, 2010, Pages 2649-2659

  Xiong, Wenjuan ^a   Zhang, Junfeng ^a  

^a LAURENTIAN UNIVERSITY   (Canada)

Author keywords

Blood flow; Erythrocyte; Glycocalyx; Lattice Boltzmann method; Mechanotransduction; Microcirculation; Shear stress

Indexed keywords

BLOOD FLOW; CELL CONCENTRATIONS; CELL DEFORMATION; CELL LENGTHS; DYNAMIC NATURE; GAP SIZE; GLYCOCALYX; LATTICE BOLTZMANN METHOD; MECHANOTRANSDUCTION; PEAK STRUCTURE; PEAK- VALLEY; RED BLOOD CELL; RED CELLS; SIMULATION RESULT; STRUCTURE CHANGE; VESSEL WALLS; WALL SHEAR STRESS;

BIOINFORMATICS; BLOOD; BLOOD VESSELS; DEFORMATION; DROP FORMATION; FLOW VELOCITY; HEMOGLOBIN OXYGEN SATURATION; MICROCIRCULATION; SHEAR STRESS; STRENGTH OF MATERIALS;

CELLS;

ARTICLE; BLOOD VESSEL; CYTOLOGY; ERYTHROCYTE; GLYCOCALYX; HEMATOCRIT; HUMAN; MECHANICAL STRESS; MICROVASCULATURE; MOTION; PHYSIOLOGY;

BLOOD VESSELS; ERYTHROCYTES; GLYCOCALYX; HEMATOCRIT; HUMANS; MICROVESSELS; MOTION; STRESS, MECHANICAL;

EID: 77955176922     PISSN: 00906964     EISSN: 15739686     Source Type: Journal    
DOI: 10.1007/s10439-010-0017-3     Document Type: Article

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