Cells sense and respond to the rigidity of their microenvironment by altering their morphology and migration behavior. To examine this response, hydrogels with a range of moduli or mechanical gradients have been developed. Here, we show that edge effects inherent in hydrogels supported on rigid substrates also influence cell behavior. A Matrigel hydrogel was supported on a rigid glass substrate, an interface which computational techniques revealed to yield relative stiffening close to the rigid substrate support. To explore the influence of these gradients in 3D, hydrogels of varying Matrigel content were synthesized and the morphology, spreading, actin organization, and migration of glioblastoma multiforme (GBM) tumor cells were examined at the lowest (<50 µm) and highest (>500 µm) gel positions. GBMs adopted bipolar morphologies, displayed actin stress fiber formation, and evidenced fast, mesenchymal migration close to the substrate, whereas away from the interface, they adopted more rounded or ellipsoid morphologies, displayed poor actin architecture, and evidenced slow migration with some amoeboid characteristics. Mechanical gradients produced via edge effects could be observed with other hydrogels and substrates and permit observation of responses to multiple mechanical environments in a single hydrogel. Thus, hydrogel-support edge effects could be used to explore mechanosensitivity in a single 3D hydrogel system and should be considered in 3D hydrogel cell culture systems.
Over the last 15 years, research on canid cognition has revealed that domestic dogs possess a surprising array of complex sociocognitive skills pointing to the possibility that the domestication process might have uniquely altered their brains; however, we know very little about how evolutionary processes (natural or artificial) might have modified underlying neural structure to support species‐specific behaviors. Evaluating the degree of cortical folding (i.e., gyrification) within canids may prove useful, as this parameter is linked to functional variation of the cerebral cortex. Using quantitative magnetic resonance imaging to investigate the impact of domestication on the canine cortical surface, we compared the gyrification index (GI) in 19 carnivore species, including six wild canid and 13 domestic dog individuals. We also explored correlations between global and local GI with brain mass, cortical thickness, white and gray matter volume and surface area. Our results indicated that GI values for domestic dogs are largely consistent with what would be expected for a canid of their given brain mass, although more variable than that observed in wild canids. We also found that GI in canids is positively correlated with cortical surface area, cortical thickness and total cortical gray matter volumes. While we found no evidence of global differences in GI between domestic and wild canids, certain regional differences in gyrification were observed.
With their high degree of specificity
and investigator control,
in vitro disease models provide a natural complement to in vivo models.
Especially in organs such as the brain, where anatomical limitations
make in vivo experiments challenging, in vitro models have been increasingly
used to mimic disease pathology. However, brain mimetic models may
not fully replicate the mechanical environment in vivo, which has
been shown to influence a variety of cell behaviors. Specifically,
many disease models consider only the linear elastic modulus of brain,
which describes the stiffness of a material with the assumption that
mechanical behavior is independent of loading rate. Here, we characterized
porcine brain tissue using a modified stress relaxation test, and
across a panel of viscoelastic models, showed that stiffness depends
on loading rate. As such, the linear elastic modulus does not accurately
reflect the viscoelastic properties of native brain. Among viscoelastic
models, the Maxwell model was selected for further analysis because
of its simplicity and excellent curve fit (R
2 = 0.99 ± 0.0006). Thus, mechanical response of native
brain and hydrogel mimetic models was analyzed using the Maxwell model
and the linear elastic model to evaluate the effects of strain rate,
time post mortem, region, tissue type (i.e., bulk brain vs white matter),
and in brain mimetic models, hydrogel composition, on observed mechanical
properties. In comparing the Maxwell and linear elastic models, linear
elastic modulus is consistently lower than the Maxwell elastic modulus
across all brain regions. Additionally, the Maxwell model is sensitive
to changes in viscosity and small changes in elasticity, demonstrating
improved fidelity. These findings demonstrate the insufficiency of
linear elastic modulus as a primary mechanical characterization for
brain mimetic materials and provide quantitative information toward
the future design of materials that more closely mimic mechanical
features of brain.
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