Two-dimensional computational flow analysis and frictional characteristics model for red blood cell under inclined centrifuge microscopy

Kenichi Funamoto; Toshiyuki Hayase; Atsushi Shirai

doi:10.1299/jsmec.46.1304

Two-dimensional computational flow analysis and frictional characteristics model for red blood cell under inclined centrifuge microscopy

Kenichi Funamoto, Toshiyuki Hayase, Atsushi Shirai

Tohoku University

Research output: Contribution to journal › Article › peer-review

3 Citations (Scopus)

Abstract

Simplified two-dimensional flow analysis is performed in order to simulate frictional characteristics measurement of red blood cells moving on a glass plate in a medium with an inclined centrifuge microscope. Computation under various conditions reveals the influences of parameters on lift, drag, and moment acting on a red blood cell. Among these forces, lift appears only when the cell is longitudinally asymmetric. By considering the balance of forces, the frictional characteristics of the red blood cell are modeled as the sum of Coulomb friction and viscous drag. The model describes the possibility that the red blood cell deforms to expand in the front side in response to the inclined centrifugal force. When velocity exceeds some critical value, the lift overcomes the normal centrifugal force component, and the thickness of the plasma layer between the cell and the glass plate increases from the initial value of the plasma protein thickness.

Original language	English
Pages (from-to)	1304-1311
Number of pages	8
Journal	JSME International Journal, Series C: Mechanical Systems, Machine Elements and Manufacturing
Volume	46
Issue number	4
DOIs	https://doi.org/10.1299/jsmec.46.1304
Publication status	Published - 2003 Dec

Keywords

Bio-fluid mechanics
Computational fluid dynamics
Coulomb friction
Frictional characteristics
Inclined centrifuge microscope
Microcirculation
Plasma
Red blood cell
Tribology
Viscous friction

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10.1299/jsmec.46.1304

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title = "Two-dimensional computational flow analysis and frictional characteristics model for red blood cell under inclined centrifuge microscopy",

abstract = "Simplified two-dimensional flow analysis is performed in order to simulate frictional characteristics measurement of red blood cells moving on a glass plate in a medium with an inclined centrifuge microscope. Computation under various conditions reveals the influences of parameters on lift, drag, and moment acting on a red blood cell. Among these forces, lift appears only when the cell is longitudinally asymmetric. By considering the balance of forces, the frictional characteristics of the red blood cell are modeled as the sum of Coulomb friction and viscous drag. The model describes the possibility that the red blood cell deforms to expand in the front side in response to the inclined centrifugal force. When velocity exceeds some critical value, the lift overcomes the normal centrifugal force component, and the thickness of the plasma layer between the cell and the glass plate increases from the initial value of the plasma protein thickness.",

keywords = "Bio-fluid mechanics, Computational fluid dynamics, Coulomb friction, Frictional characteristics, Inclined centrifuge microscope, Microcirculation, Plasma, Red blood cell, Tribology, Viscous friction",

author = "Kenichi Funamoto and Toshiyuki Hayase and Atsushi Shirai",

year = "2003",

month = dec,

doi = "10.1299/jsmec.46.1304",

language = "English",

volume = "46",

pages = "1304--1311",

journal = "JSME International Journal, Series C: Mechanical Systems, Machine Elements and Manufacturing",

issn = "1344-7653",

publisher = "Japan Society of Mechanical Engineers",

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}

Two-dimensional computational flow analysis and frictional characteristics model for red blood cell under inclined centrifuge microscopy. / Funamoto, Kenichi ; Hayase, Toshiyuki; Shirai, Atsushi.
In: JSME International Journal, Series C: Mechanical Systems, Machine Elements and Manufacturing, Vol. 46, No. 4, 12.2003, p. 1304-1311.

Research output: Contribution to journal › Article › peer-review

TY - JOUR

T1 - Two-dimensional computational flow analysis and frictional characteristics model for red blood cell under inclined centrifuge microscopy

AU - Funamoto, Kenichi

AU - Hayase, Toshiyuki

AU - Shirai, Atsushi

PY - 2003/12

Y1 - 2003/12

N2 - Simplified two-dimensional flow analysis is performed in order to simulate frictional characteristics measurement of red blood cells moving on a glass plate in a medium with an inclined centrifuge microscope. Computation under various conditions reveals the influences of parameters on lift, drag, and moment acting on a red blood cell. Among these forces, lift appears only when the cell is longitudinally asymmetric. By considering the balance of forces, the frictional characteristics of the red blood cell are modeled as the sum of Coulomb friction and viscous drag. The model describes the possibility that the red blood cell deforms to expand in the front side in response to the inclined centrifugal force. When velocity exceeds some critical value, the lift overcomes the normal centrifugal force component, and the thickness of the plasma layer between the cell and the glass plate increases from the initial value of the plasma protein thickness.

AB - Simplified two-dimensional flow analysis is performed in order to simulate frictional characteristics measurement of red blood cells moving on a glass plate in a medium with an inclined centrifuge microscope. Computation under various conditions reveals the influences of parameters on lift, drag, and moment acting on a red blood cell. Among these forces, lift appears only when the cell is longitudinally asymmetric. By considering the balance of forces, the frictional characteristics of the red blood cell are modeled as the sum of Coulomb friction and viscous drag. The model describes the possibility that the red blood cell deforms to expand in the front side in response to the inclined centrifugal force. When velocity exceeds some critical value, the lift overcomes the normal centrifugal force component, and the thickness of the plasma layer between the cell and the glass plate increases from the initial value of the plasma protein thickness.

KW - Bio-fluid mechanics

KW - Computational fluid dynamics

KW - Coulomb friction

KW - Frictional characteristics

KW - Inclined centrifuge microscope

KW - Microcirculation

KW - Plasma

KW - Red blood cell

KW - Tribology

KW - Viscous friction

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Two-dimensional computational flow analysis and frictional characteristics model for red blood cell under inclined centrifuge microscopy

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