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Published in:
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2012 | OriginalPaper | Chapter

Models of Low Reynolds Number Swimmers Inspired by Cell Blebbing

Authors : Qixuan Wang, Jifeng Hu, Hans Othmer

Published in: Natural Locomotion in Fluids and on Surfaces

Publisher: Springer New York

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Abstract

Eukaryotic cells move through the complex micro-environment of a tissue either by attaching to the extracellular matrix – sometimes degrading it locally – and pulling themselves along, or by squeezing through the matrix by appropriate sequences of shape changes. Some cells can even swim by shape changes, and one mode used is called blebbing, in which a cell creates a small hemispherical protrusion that may grow to incorporate the entire cell volume or may be reabsorbed into the primary volume. Herein we develop and analyze several models for swimming at low Reynolds number inspired by cell blebbing. These models comprise several connected spheres, and each connected pair of spheres can exchange volume with their complement in the pair. We show that the cell can propel itself through the fluid using a suitable sequence of volume exchanges, and we evaluate the efficiency of this mode of swimming.

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previous chapter Computing optimal Strokes for Low Reynolds Number Swimmers
next chapter A Low-Reynolds-Number Treadmilling Swimmer Near a Semi-infinite Wall
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Metadata
Title
Models of Low Reynolds Number Swimmers Inspired by Cell Blebbing
Authors
Qixuan Wang
Jifeng Hu
Hans Othmer
Copyright Year
2012
Publisher
Springer New York
Book
Natural Locomotion in Fluids and on Surfaces

Print ISBN: 978-1-4614-3996-7

Electronic ISBN: 978-1-4614-3997-4

Copyright Year: 2012

DOI
https://doi.org/10.1007/978-1-4614-3997-4_14

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