Intermittency and synchronized motion of red blood cell dynamics in shear flow

Daniel Cordasco; Prosenjit Bagchi

doi:10.1017/jfm.2014.587

Intermittency and synchronized motion of red blood cell dynamics in shear flow

Daniel Cordasco, Prosenjit Bagchi

School of Engineering, Mechanical & Aerospace Engineering

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

24 Scopus citations

Abstract

We present the first full-scale computational evidence of intermittent and synchronized dynamics of red blood cells in shear flow. These dynamics are characterized by the coexistence of a tumbling motion in which the cell behaves like a rigid body and a tank-treading motion in which the cell behaves like a liquid drop. In the intermittent dynamics, we observe sequences of tumbling interrupted by swinging, as well as sequences of swinging interrupted by tumbling. In the synchronized dynamics, the tumbling and membrane rotation are observed to occur simultaneously with integer ratios of the rotational frequencies. These dynamics are shown to be dependent on the stress-free state of the cytoskeleton, and are explained based on the cell membrane energy landscape.

Original language	English (US)
Pages (from-to)	472-488
Number of pages	17
Journal	Journal of Fluid Mechanics
Volume	759
DOIs	https://doi.org/10.1017/jfm.2014.587
State	Published - Nov 25 2014

All Science Journal Classification (ASJC) codes

Condensed Matter Physics
Mechanics of Materials
Mechanical Engineering
Applied Mathematics

Keywords

Biological fluid dynamics
Blood flow
Capsule/cell dynamics

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10.1017/jfm.2014.587

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title = "Intermittency and synchronized motion of red blood cell dynamics in shear flow",

abstract = "We present the first full-scale computational evidence of intermittent and synchronized dynamics of red blood cells in shear flow. These dynamics are characterized by the coexistence of a tumbling motion in which the cell behaves like a rigid body and a tank-treading motion in which the cell behaves like a liquid drop. In the intermittent dynamics, we observe sequences of tumbling interrupted by swinging, as well as sequences of swinging interrupted by tumbling. In the synchronized dynamics, the tumbling and membrane rotation are observed to occur simultaneously with integer ratios of the rotational frequencies. These dynamics are shown to be dependent on the stress-free state of the cytoskeleton, and are explained based on the cell membrane energy landscape.",

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AU - Cordasco, Daniel

AU - Bagchi, Prosenjit

N1 - Publisher Copyright: © Cambridge University Press 2014.

PY - 2014/11/25

Y1 - 2014/11/25

N2 - We present the first full-scale computational evidence of intermittent and synchronized dynamics of red blood cells in shear flow. These dynamics are characterized by the coexistence of a tumbling motion in which the cell behaves like a rigid body and a tank-treading motion in which the cell behaves like a liquid drop. In the intermittent dynamics, we observe sequences of tumbling interrupted by swinging, as well as sequences of swinging interrupted by tumbling. In the synchronized dynamics, the tumbling and membrane rotation are observed to occur simultaneously with integer ratios of the rotational frequencies. These dynamics are shown to be dependent on the stress-free state of the cytoskeleton, and are explained based on the cell membrane energy landscape.

AB - We present the first full-scale computational evidence of intermittent and synchronized dynamics of red blood cells in shear flow. These dynamics are characterized by the coexistence of a tumbling motion in which the cell behaves like a rigid body and a tank-treading motion in which the cell behaves like a liquid drop. In the intermittent dynamics, we observe sequences of tumbling interrupted by swinging, as well as sequences of swinging interrupted by tumbling. In the synchronized dynamics, the tumbling and membrane rotation are observed to occur simultaneously with integer ratios of the rotational frequencies. These dynamics are shown to be dependent on the stress-free state of the cytoskeleton, and are explained based on the cell membrane energy landscape.

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Intermittency and synchronized motion of red blood cell dynamics in shear flow

Abstract

All Science Journal Classification (ASJC) codes

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