Mechanics of blood flow in arteriolar and venular bifurcations

Aleksander S. Popel; Giora Enden; Joseph Ong

Mechanics of blood flow in arteriolar and venular bifurcations

Aleksander S. Popel, Giora Enden, Joseph Ong

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

3 Scopus citations

Abstract

Results of ongoing theoretical computational studies of blood flow in arteriolar and venular bifurcations are presented. In arteriolar bifurcations, the blood is modeled as a two-phase continuum, with a central core that is a concentrated suspension of red blood cells and with a layer of plasma adjacent to the vessel wall; the fluids are assumed to be Newtonian with different constant viscosities. The evolution of the two phases as the blood flows through the arteriolar bifurcation is studied. In venular bifurcations, two converging streams are modeled as Quemada-type thixotropic fluids with different hematocrits. The streams are followed through the bifurcation as they fold and form a strongly asymmetric velocity profile at the outlet cross section. These models yield predictions of the hematocrit and the velocity distribution downstream from arteriolar and venular bifurcations. The implications of these results for blood flow in microvascular networks are discussed.

Original language	English
Title of host publication	Advaces in Biological Heat and Mass Transfer - 1992
Publisher	Publ by ASME
Pages	105-111
Number of pages	7
ISBN (Print)	0791811115
State	Published - 1 Dec 1992
Externally published	Yes
Event	Winter Annual Meeting of the American Society of Mechanical Engineers - Anaheim, CA, USA Duration: 8 Nov 1992 → 13 Nov 1992

Publication series

Name	American Society of Mechanical Engineers, Heat Transfer Division, (Publication) HTD
Volume	231
ISSN (Print)	0272-5673

Conference

Conference	Winter Annual Meeting of the American Society of Mechanical Engineers
City	Anaheim, CA, USA
Period	8/11/92 → 13/11/92

ASJC Scopus subject areas

Mechanical Engineering
Fluid Flow and Transfer Processes

Cite this

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title = "Mechanics of blood flow in arteriolar and venular bifurcations",

abstract = "Results of ongoing theoretical computational studies of blood flow in arteriolar and venular bifurcations are presented. In arteriolar bifurcations, the blood is modeled as a two-phase continuum, with a central core that is a concentrated suspension of red blood cells and with a layer of plasma adjacent to the vessel wall; the fluids are assumed to be Newtonian with different constant viscosities. The evolution of the two phases as the blood flows through the arteriolar bifurcation is studied. In venular bifurcations, two converging streams are modeled as Quemada-type thixotropic fluids with different hematocrits. The streams are followed through the bifurcation as they fold and form a strongly asymmetric velocity profile at the outlet cross section. These models yield predictions of the hematocrit and the velocity distribution downstream from arteriolar and venular bifurcations. The implications of these results for blood flow in microvascular networks are discussed.",

author = "Popel, {Aleksander S.} and Giora Enden and Joseph Ong",

year = "1992",

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language = "English",

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series = "American Society of Mechanical Engineers, Heat Transfer Division, (Publication) HTD",

publisher = "Publ by ASME",

pages = "105--111",

booktitle = "Advaces in Biological Heat and Mass Transfer - 1992",

note = "Winter Annual Meeting of the American Society of Mechanical Engineers ; Conference date: 08-11-1992 Through 13-11-1992",

}

Popel, AS, Enden, G & Ong, J 1992, Mechanics of blood flow in arteriolar and venular bifurcations. in Advaces in Biological Heat and Mass Transfer - 1992. American Society of Mechanical Engineers, Heat Transfer Division, (Publication) HTD, vol. 231, Publ by ASME, pp. 105-111, Winter Annual Meeting of the American Society of Mechanical Engineers, Anaheim, CA, USA, 8/11/92.

Mechanics of blood flow in arteriolar and venular bifurcations. / Popel, Aleksander S.; Enden, Giora; Ong, Joseph.
Advaces in Biological Heat and Mass Transfer - 1992. Publ by ASME, 1992. p. 105-111 (American Society of Mechanical Engineers, Heat Transfer Division, (Publication) HTD; Vol. 231).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Mechanics of blood flow in arteriolar and venular bifurcations

AU - Popel, Aleksander S.

AU - Enden, Giora

AU - Ong, Joseph

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N2 - Results of ongoing theoretical computational studies of blood flow in arteriolar and venular bifurcations are presented. In arteriolar bifurcations, the blood is modeled as a two-phase continuum, with a central core that is a concentrated suspension of red blood cells and with a layer of plasma adjacent to the vessel wall; the fluids are assumed to be Newtonian with different constant viscosities. The evolution of the two phases as the blood flows through the arteriolar bifurcation is studied. In venular bifurcations, two converging streams are modeled as Quemada-type thixotropic fluids with different hematocrits. The streams are followed through the bifurcation as they fold and form a strongly asymmetric velocity profile at the outlet cross section. These models yield predictions of the hematocrit and the velocity distribution downstream from arteriolar and venular bifurcations. The implications of these results for blood flow in microvascular networks are discussed.

AB - Results of ongoing theoretical computational studies of blood flow in arteriolar and venular bifurcations are presented. In arteriolar bifurcations, the blood is modeled as a two-phase continuum, with a central core that is a concentrated suspension of red blood cells and with a layer of plasma adjacent to the vessel wall; the fluids are assumed to be Newtonian with different constant viscosities. The evolution of the two phases as the blood flows through the arteriolar bifurcation is studied. In venular bifurcations, two converging streams are modeled as Quemada-type thixotropic fluids with different hematocrits. The streams are followed through the bifurcation as they fold and form a strongly asymmetric velocity profile at the outlet cross section. These models yield predictions of the hematocrit and the velocity distribution downstream from arteriolar and venular bifurcations. The implications of these results for blood flow in microvascular networks are discussed.

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T3 - American Society of Mechanical Engineers, Heat Transfer Division, (Publication) HTD

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BT - Advaces in Biological Heat and Mass Transfer - 1992

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Mechanics of blood flow in arteriolar and venular bifurcations

Abstract

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Conference

ASJC Scopus subject areas

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