A formalism for modelling traction forces and cell shape evolution during cell migration in various biomedical processes

AbstractThe phenomenological model for cell shape deformation and cell migration Chen (BMM 17:1429–1450, 2018), Vermolen and Gefen (BMM 12:301–323, 2012), is extended with the incorporation of cell traction forces and the evolution of cell equilibrium shapes as a result of cell differentiation. Plastic deformations of the extracellular matrix are modelled using morphoelasticity theory. The resulting partial differential differential equations are solved by the use of the finite element method. The paper treats various biological scenarios that entail cell migration and cell shape evolution. The experimental observations in Mak et al. (LC 13:340–348, 2013), where transmigration of cancer cells through narrow apertures is studied, are reproduced using a Monte Carlo framework.

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Analysis of cell traction forces based on the cell shape differences using traction force microscopy

The Proceedings of Ibaraki District Conference ◽

10.1299/jsmeibaraki.2018.26.512 ◽

2018 ◽

Vol 2018.26 (0) ◽

pp. 512

Author(s):

Harunobu TATSUNO ◽

Kazuaki NAGAYAMA

Keyword(s):

Cell Shape ◽

Traction Force ◽

Traction Force Microscopy ◽

Traction Forces ◽

Force Microscopy ◽

Cell Traction Forces ◽

Cell Traction

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Simplifying Cell Traction Forces Using Fibronectin Patterned Polyacrylamide Gels

ASME 2011 Summer Bioengineering Conference, Parts A and B ◽

10.1115/sbc2011-53898 ◽

2011 ◽

Author(s):

Samuel R. Polio ◽

Katheryn E. Rothenberg ◽

Dimitrije Stamenović ◽

Michael L. Smith

Keyword(s):

Cell Shape ◽

Protein Complexes ◽

Dynamic Environments ◽

Cell Behavior ◽

Traction Forces ◽

Adhesion Sites ◽

Cell Traction Forces ◽

Cell Traction ◽

A Cell ◽

And Function

Cells inhabit highly dynamic environments which greatly influence cell behavior. One of the ways in which a cell interacts with its environment is through its membrane by focal adhesion complexes. These protein complexes form an intermediary between the cytoskeleton and the extracellular matrix. Tension generated within the contractile cytoskeleton results in cellular traction forces (CTFs) at the adhesion sites, which can greatly affect cell shape, adhesion, and function (1).

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Video-microscopic measurement of cell-substratum traction forces generated by locomoting keratocytes

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100146783 ◽

1993 ◽

Vol 51 ◽

pp. 188-189

Author(s):

Tim Oliver ◽

Michelle Leonard ◽

Juliet Lee ◽

Akira Ishihara ◽

Ken Jacobson

Keyword(s):

Silicone Rubber ◽

Molecular Motors ◽

Video Frame ◽

Traction Forces ◽

Cell Traction Forces ◽

Latex Beads ◽

Cell Traction ◽

Local Cell ◽

Microscopic Measurement ◽

Kinetics Of

We are using video-enhanced light microscopy to investigate the pattern and magnitude of forces that fish keratocytes exert on flexible silicone rubber substrata. Our goal is a clearer understanding of the way molecular motors acting through the cytoskeleton co-ordinate their efforts into locomotion at cell velocities up to 1 μm/sec. Cell traction forces were previously observed as wrinkles(Fig.l) in strong silicone rubber films by Harris.(l) These forces are now measureable by two independant means.In the first of these assays, weakly crosslinked films are made, into which latex beads have been embedded.(Fig.2) These films report local cell-mediated traction forces as bead displacements in the plane of the film(Fig.3), which recover when the applied force is released. Calibrated flexible glass microneedles are then used to reproduce the translation of individual beads. We estimate the force required to distort these films to be 0.5 mdyne/μm of bead movement. Video-frame analysis of bead trajectories is providing data on the relative localisation, dissipation and kinetics of traction forces.

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Cell Traction Forces Direct Fibronectin Matrix Assembly

Biophysical Journal ◽

10.1016/j.bpj.2008.10.009 ◽

2009 ◽

Vol 96 (2) ◽

pp. 729-738 ◽

Cited By ~ 99

Author(s):

Christopher A. Lemmon ◽

Christopher S. Chen ◽

Lewis H. Romer

Keyword(s):

Matrix Assembly ◽

Traction Forces ◽

Cell Traction Forces ◽

Fibronectin Matrix ◽

Cell Traction

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Dissipation of contractile forces: the missing piece in cell mechanics

Molecular Biology of the Cell ◽

10.1091/mbc.e16-09-0672 ◽

2017 ◽

Vol 28 (14) ◽

pp. 1825-1832 ◽

Cited By ~ 12

Author(s):

Laetitia Kurzawa ◽

Benoit Vianay ◽

Fabrice Senger ◽

Timothée Vignaud ◽

Laurent Blanchoin ◽

...

Keyword(s):

Cell Mechanics ◽

Force Production ◽

Traction Force ◽

Structural Rearrangements ◽

Force Transmission ◽

Traction Forces ◽

Cell Traction Forces ◽

Cell Traction ◽

Contractile Forces ◽

Fiber Contraction

Mechanical forces are key regulators of cell and tissue physiology. The basic molecular mechanism of fiber contraction by the sliding of actin filament upon myosin leading to conformational change has been known for decades. The regulation of force generation at the level of the cell, however, is still far from elucidated. Indeed, the magnitude of cell traction forces on the underlying extracellular matrix in culture is almost impossible to predict or experimentally control. The considerable variability in measurements of cell-traction forces indicates that they may not be the optimal readout to properly characterize cell contractile state and that a significant part of the contractile energy is not transferred to cell anchorage but instead is involved in actin network dynamics. Here we discuss the experimental, numerical, and biological parameters that may be responsible for the variability in traction force production. We argue that limiting these sources of variability and investigating the dissipation of mechanical work that occurs with structural rearrangements and the disengagement of force transmission is key for further understanding of cell mechanics.

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