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Autori principali: Ma, Tianxiang, Grudtsyna, Valeriia, Bölsterli, Robin V., Doostmohammadi, Amin
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2508.17974
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author Ma, Tianxiang
Grudtsyna, Valeriia
Bölsterli, Robin V.
Doostmohammadi, Amin
author_facet Ma, Tianxiang
Grudtsyna, Valeriia
Bölsterli, Robin V.
Doostmohammadi, Amin
contents Understanding how biomechanical reorganization governs key biological processes, such as morphogenesis and development, requires predictive insights into stress distributions and cellular behavior. While traditional approaches focused on cell motion as a response to stress, we demonstrate that Lagrangian coherent structures (LCSs) -- robust attractors and repellers in cellular flows -- precede and drive long-term intercellular stress reorganization, physically governed by the mechanical properties of intercellular junctions. We show that this hidden flow skeleton correlates strongly with biomechanical metrics, bridging microscopic cell motion with mesoscopic biomechanics. Specifically, attractors and repellers mark hotspots of compressive and tensile stress enrichment (exceeding tenfold), alongside heterogeneities in cell packing. Notably, these connections remain robust across varying strengths of cell-cell and cell-substrate force transmission. Finally, by linking the attracting regions in the flow skeleton to future cell extrusion spots, we establish a direct link between cell motion and biologically significant outcomes. Together, these findings establish a framework for using cell motion to independently infer biomechanical metrics and bridge the scale mismatch between cell motion and biomechanics, potentially offering a new route to interpret mechanosensitive biological processes directly from cell trajectories.
format Preprint
id arxiv_https___arxiv_org_abs_2508_17974
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Cellular Flow Architecture Exposes the Hidden Mechanics of Biological Matter
Ma, Tianxiang
Grudtsyna, Valeriia
Bölsterli, Robin V.
Doostmohammadi, Amin
Biological Physics
Soft Condensed Matter
Understanding how biomechanical reorganization governs key biological processes, such as morphogenesis and development, requires predictive insights into stress distributions and cellular behavior. While traditional approaches focused on cell motion as a response to stress, we demonstrate that Lagrangian coherent structures (LCSs) -- robust attractors and repellers in cellular flows -- precede and drive long-term intercellular stress reorganization, physically governed by the mechanical properties of intercellular junctions. We show that this hidden flow skeleton correlates strongly with biomechanical metrics, bridging microscopic cell motion with mesoscopic biomechanics. Specifically, attractors and repellers mark hotspots of compressive and tensile stress enrichment (exceeding tenfold), alongside heterogeneities in cell packing. Notably, these connections remain robust across varying strengths of cell-cell and cell-substrate force transmission. Finally, by linking the attracting regions in the flow skeleton to future cell extrusion spots, we establish a direct link between cell motion and biologically significant outcomes. Together, these findings establish a framework for using cell motion to independently infer biomechanical metrics and bridge the scale mismatch between cell motion and biomechanics, potentially offering a new route to interpret mechanosensitive biological processes directly from cell trajectories.
title Cellular Flow Architecture Exposes the Hidden Mechanics of Biological Matter
topic Biological Physics
Soft Condensed Matter
url https://arxiv.org/abs/2508.17974