2009 APS March Meeting
Volume 54, Number 1
Monday–Friday, March 16–20, 2009;
Pittsburgh, Pennsylvania
Session X5: Active Soft Matter: From Granular Rods to Flocks to Living Cells
2:30 PM–5:30 PM,
Thursday, March 19, 2009
Room: 401/402
Sponsoring
Unit:
GSNP
Chair: Cristina Marchetti, Syracuse University
Abstract ID: BAPS.2009.MAR.X5.5
Abstract: X5.00005 : Beller Lectureship Talk: Active response of biological cells to mechanical stress
4:54 PM–5:30 PM
Preview Abstract
Abstract
Author:
Samuel Safran
(Dept. Materials and Interfaces, Weizmann Institute of Science, Rehovot, Israel 76100)
Forces exerted by and on adherent cells are important for many
physiological
processes such as wound healing and tissue formation. In
addition, recent
experiments have shown that stem cell differentiation is
controlled, at
least in part, by the elasticity of the surrounding matrix. We
present a
simple and generic theoretical model for the active response of
biological
cells to mechanical stress. The theory includes cell activity and
mechanical
forces as well as random forces as factors that determine the
polarizability
that relates cell orientation to stress. This allows us to
explain the
puzzling observation of parallel (or sometimes random) alignment
of cells
for static and quasi-static stresses and of nearly perpendicular
alignment
for dynamically varying stresses. In addition, we predict the
response of
the cellular orientation to a sinusoidally varying applied stress
as a
function of frequency and compare the theory with recent
experiments. The
dependence of the cell orientation angle on the Poisson ratio of the
surrounding material distinguishes cells whose activity is
controlled by
stress from those controlled by strain. We have extended the
theory to
generalize the treatment of elastic inclusions in solids to
''living''
inclusions (cells) whose active polarizability, analogous to the
polarizability of non-living matter, results in the feedback of
cellular
forces that develop in response to matrix stresses. We use this
to explain
recent observations of the non-monotonic dependence of stress-fiber
polarization in stem cells on matrix rigidity. These findings
provide a
mechanical correlate for the existence of an optimal substrate
elasticity
for cell differentiation and function.
\\[3pt]
*In collaboration with R. De (Brown University), Y. Biton
(Weizmann Institute), and A. Zemel (Hebrew University) and the
experimental groups: Max Planck Institute, Stuttgart: S.
Jungbauer, R. Kemkemer, J. Spatz; University of Pennsylvania: A.
Brown, D. Discher, F. Rehfeldt.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2009.MAR.X5.5