Kinetic theory based model for blood flow and its viscosity

Annals of Biomedical Engineering

Volumn 37, Issue 8, 2009, Pages 1534-1545

  Gidaspow, Dimitri ^a   Huang, Jing ^a  

^a Illinois Institute of Technology   (United States)

Author keywords

Computational fluid dynamics; Hemodynamics; Multiphase flow

Indexed keywords

BLOOD FLOW; BLOOD VISCOSITY; EXPERIMENTAL MEASUREMENTS; FAHRAEUS-LINDQVIST EFFECTS; GRANULAR TEMPERATURE; NARROW TUBES; PER UNIT; RED BLOOD CELL; SHEAR-INDUCED DIFFUSION; TWO PHASE FLOW MODEL;

BLOOD; CELLS; COMPUTATIONAL FLUID DYNAMICS; DIELECTRIC DEVICES; FLUID DYNAMICS; HEMODYNAMICS; HEMOGLOBIN OXYGEN SATURATION; HYDRODYNAMICS; KINETIC THEORY; PLASMA DIAGNOSTICS; VISCOSITY;

TWO PHASE FLOW;

ANIMAL; ARTICLE; BIOLOGICAL MODEL; BLOOD FLOW VELOCITY; BLOOD VISCOSITY; ERYTHROCYTE; HEMATOCRIT; HUMAN; PHYSIOLOGY; PLASMA;

ANIMALS; BLOOD FLOW VELOCITY; BLOOD VISCOSITY; ERYTHROCYTES; HEMATOCRIT; HUMANS; MODELS, CARDIOVASCULAR; PLASMA;

EID: 70349580373     PISSN: 00906964     EISSN: 15739686     Source Type: Journal    
DOI: 10.1007/s10439-009-9720-3     Document Type: Article

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