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Main Authors: Fioretto, Gabriele, Lucci, Giulio, Giverso, Chiara, Preziosi, Luigi
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2512.19755
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author Fioretto, Gabriele
Lucci, Giulio
Giverso, Chiara
Preziosi, Luigi
author_facet Fioretto, Gabriele
Lucci, Giulio
Giverso, Chiara
Preziosi, Luigi
contents We develop a general continuum mechanics framework for active anisotropic plates within the Föppl-von Kármán limit, incorporating a preferential direction and inelastic active contractions in geometrically nonlinear plate theory. Through asymptotic expansion, we derive coupled equilibrium equations for plates with transversely isotropic and possibly inhomogeneous reinforcement undergoing spatially varying active contractions through their thickness. The framework highlights the coupling between material anisotropy and active deformations, with target curvatures that compete with imposed geometric constraints. To demonstrate its capabilities, we apply the model to curvature-induced cell alignment, where substrate geometry, cytoskeletal anisotropy, and contractility interact to determine orientation. For cylindrical substrates, the model predicts a supercritical bifurcation in preferred orientation, from perpendicular to parallel, through an oblique orientation governed by the ratio of active contractility to substrate curvature and modulated by material stiffness. For ellipsoidal geometries, we capture stable parallel, perpendicular, and oblique configurations depending on principal curvatures, whereas spherical substrates do not show preferred alignments. These predictions qualitatively reproduce experimental observations across cell types, explaining divergent behaviors between contractile epithelial cells and stiffer fibroblasts in a rigorous context. Beyond cellular mechanics, this framework applies broadly to thin fiber-reinforced active structures in soft robotics, morphogenesis, and tissue engineering.
format Preprint
id arxiv_https___arxiv_org_abs_2512_19755
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle The mechanics of anisotropic active plates with applications to cell alignment on curved substrates
Fioretto, Gabriele
Lucci, Giulio
Giverso, Chiara
Preziosi, Luigi
Soft Condensed Matter
Mathematical Physics
We develop a general continuum mechanics framework for active anisotropic plates within the Föppl-von Kármán limit, incorporating a preferential direction and inelastic active contractions in geometrically nonlinear plate theory. Through asymptotic expansion, we derive coupled equilibrium equations for plates with transversely isotropic and possibly inhomogeneous reinforcement undergoing spatially varying active contractions through their thickness. The framework highlights the coupling between material anisotropy and active deformations, with target curvatures that compete with imposed geometric constraints. To demonstrate its capabilities, we apply the model to curvature-induced cell alignment, where substrate geometry, cytoskeletal anisotropy, and contractility interact to determine orientation. For cylindrical substrates, the model predicts a supercritical bifurcation in preferred orientation, from perpendicular to parallel, through an oblique orientation governed by the ratio of active contractility to substrate curvature and modulated by material stiffness. For ellipsoidal geometries, we capture stable parallel, perpendicular, and oblique configurations depending on principal curvatures, whereas spherical substrates do not show preferred alignments. These predictions qualitatively reproduce experimental observations across cell types, explaining divergent behaviors between contractile epithelial cells and stiffer fibroblasts in a rigorous context. Beyond cellular mechanics, this framework applies broadly to thin fiber-reinforced active structures in soft robotics, morphogenesis, and tissue engineering.
title The mechanics of anisotropic active plates with applications to cell alignment on curved substrates
topic Soft Condensed Matter
Mathematical Physics
url https://arxiv.org/abs/2512.19755