Traction force microscopy in physics and biology

Robert W. Style; Rostislav Boltyanskiy; Guy K. German; Callen Hyland; Christopher W. Macminn; Aaron F. Mertz; Larry A. Wilen; Ye Xu; Eric R. Dufresne

doi:10.1039/c4sm00264d

Traction force microscopy in physics and biology

Robert W. Style
, Rostislav Boltyanskiy
, Guy K. German
, Callen Hyland
, Christopher W. Macminn
, Aaron F. Mertz
, Larry A. Wilen
, Ye Xu
, Eric R. Dufresne^*

^*Corresponding author for this work

Research output: Contribution to journal › Review article › peer-review

284 Scopus citations

Abstract

Adherent cells, crawling slugs, peeling paint, sessile liquid drops, bearings and many other living and non-living systems apply forces to solid substrates. Traction force microscopy (TFM) provides spatially-resolved measurements of interfacial forces through the quantification and analysis of the deformation of an elastic substrate. Although originally developed for adherent cells, TFM has no inherent size or force scale, and can be applied to a much broader range of mechanical systems across physics and biology. In this paper, we showcase the wide range of applicability of TFM, describe the theory, and provide experimental details and code so that experimentalists can rapidly adopt this powerful technique. This journal is

Original language	English
Pages (from-to)	4047-4055
Number of pages	9
Journal	Soft Matter
Volume	10
Issue number	23
DOIs	https://doi.org/10.1039/c4sm00264d
State	Published - 21 Jun 2014
Externally published	Yes

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10.1039/c4sm00264d

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title = "Traction force microscopy in physics and biology",

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AU - Boltyanskiy, Rostislav

AU - German, Guy K.

AU - Hyland, Callen

AU - Macminn, Christopher W.

AU - Mertz, Aaron F.

AU - Wilen, Larry A.

AU - Xu, Ye

AU - Dufresne, Eric R.

PY - 2014/6/21

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N2 - Adherent cells, crawling slugs, peeling paint, sessile liquid drops, bearings and many other living and non-living systems apply forces to solid substrates. Traction force microscopy (TFM) provides spatially-resolved measurements of interfacial forces through the quantification and analysis of the deformation of an elastic substrate. Although originally developed for adherent cells, TFM has no inherent size or force scale, and can be applied to a much broader range of mechanical systems across physics and biology. In this paper, we showcase the wide range of applicability of TFM, describe the theory, and provide experimental details and code so that experimentalists can rapidly adopt this powerful technique. This journal is

AB - Adherent cells, crawling slugs, peeling paint, sessile liquid drops, bearings and many other living and non-living systems apply forces to solid substrates. Traction force microscopy (TFM) provides spatially-resolved measurements of interfacial forces through the quantification and analysis of the deformation of an elastic substrate. Although originally developed for adherent cells, TFM has no inherent size or force scale, and can be applied to a much broader range of mechanical systems across physics and biology. In this paper, we showcase the wide range of applicability of TFM, describe the theory, and provide experimental details and code so that experimentalists can rapidly adopt this powerful technique. This journal is

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SN - 1744-683X

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JO - Soft Matter

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Traction force microscopy in physics and biology

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