Cellular Potts model simulations uncover multiscale orientational order, actin-driven flocking transitions, and phenotypic hysteresis in epithelial monolayers.
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Feedback between cytoskeletal activity and elastic stress in a vertex model drives an isotropic-nematic transition, yielding a soft elastic solid and a plastic nematic solid with long-range flow correlations at higher activity.
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Multiscale order, flocking and phenotypic hysteresis in the cellular Potts model of epithelia
Cellular Potts model simulations uncover multiscale orientational order, actin-driven flocking transitions, and phenotypic hysteresis in epithelial monolayers.
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Feedback-controlled epithelial mechanics: emergent soft elasticity and active yielding
Feedback between cytoskeletal activity and elastic stress in a vertex model drives an isotropic-nematic transition, yielding a soft elastic solid and a plastic nematic solid with long-range flow correlations at higher activity.