Substrate stiffness and oxygen availability as regulators of mesenchymal stem cell differentiation within a mechanically loaded bone chamber.
Loading...
Files
Date
Authors
Journal Title
Journal ISSN
Volume Title
Publisher
Access
openAccess
Embargo end date
Citation
Burke DP, Khayyeri H, Kelly DJ, Substrate stiffness and oxygen availability as regulators of mesenchymal stem cell differentiation within a mechanically loaded bone chamber., Biomechanics and modeling in mechanobiology, 14, 1, 2014, 93-105
Abstract
M
echanical stimuli
such as tissue deformation and fluid flow
are often implicated as regulators of
mesenchymal stem cell (MSC)
differentiation
during regenerative events
in vivo
.
However
,
in vitro
studies have identified several other
physical and biochemical
environmental
cues
, such as substrate
stiffness and oxygen availability,
as key regulators of
stem cell fate
.
Hypotheses for how MSC
differentiation is regulated
in vivo
can be either corroborated or rejected based on the ability of
in
silico
models to accurately predic
t spatial and temporal patterns of tissue differentiation observed
experimentally
.
The goal of this study was to
employ a previously
de
veloped
computational
framework
to
test the hypothesis that substrate stiffness and oxygen availability regulate stem cel
l
differentiation
during
t
issue regeneration
within
an
implanted
bone chamber.
To enable a prediction
of the oxygen levels within the bone chamber, a lattice model of angiogenesis was implemented
where blood vessel progression was depend
e
nt on the local me
chanical environment
.
The
model
successfully predict
ed
key aspects of MSC differentiation, including the
correct
spatial
development
of bone, marrow and fibrous
tissue
within the
unloaded
bone
chamber
. The model also successfully
predicted
chondrogenesis
w
ithin the chamber
upon the application of
mechanical
loading.
This study
provides further support for the hypothesis that substrate stiffness and oxygen availability regulate
stem cell differentiation
in vivo
.
Th
ese simulations
also
highlight the indirect
role that mechanics may
play in regulating MSC fate by inhibiting blood vessel progression and hence disrupting oxygen
availability within regenerating tissues
Description
PUBLISHED
Endorsement
Review
Supplemented By
Referenced By
Author's Homepage: http://people.tcd.ie/kellyd9
Type of material: Journal Article

