Mechanics and Morphology of Proliferating Cell Collectives with Self-Inhibiting Growth

Scott Weady; Bryce Palmer; Adam Lamson; Taeyoon Kim; Reza Farhadifar; Michael J. Shelley

doi:10.1103/PhysRevLett.133.158402

Mechanics and Morphology of Proliferating Cell Collectives with Self-Inhibiting Growth

Scott Weady, Bryce Palmer, Adam Lamson, Taeyoon Kim, Reza Farhadifar, Michael J. Shelley

Mathematics

Research output: Contribution to journal › Article › peer-review

Abstract

We study the dynamics of proliferating cell collectives whose microscopic constituents' growth is inhibited by macroscopic growth-induced stress. Discrete particle simulations of a growing collective show the emergence of concentric-ring patterns in cell size whose spatiotemporal structure is closely tied to the individual cell's stress response. Motivated by these observations, we derive a multiscale continuum theory whose parameters map directly to the discrete model. Analytical solutions of this theory show the concentric patterns arise from anisotropically accumulated resistance to growth over many cell cycles. This Letter shows how purely mechanical processes can affect the internal patterning and morphology of cell collectives, and provides a concise theoretical framework for connecting the micro- to macroscopic dynamics of proliferating matter.

Original language	English (US)
Article number	158402
Journal	Physical Review Letters
Volume	133
Issue number	15
DOIs	https://doi.org/10.1103/PhysRevLett.133.158402
State	Published - Oct 11 2024

ASJC Scopus subject areas

General Physics and Astronomy

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10.1103/PhysRevLett.133.158402

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title = "Mechanics and Morphology of Proliferating Cell Collectives with Self-Inhibiting Growth",

abstract = "We study the dynamics of proliferating cell collectives whose microscopic constituents' growth is inhibited by macroscopic growth-induced stress. Discrete particle simulations of a growing collective show the emergence of concentric-ring patterns in cell size whose spatiotemporal structure is closely tied to the individual cell's stress response. Motivated by these observations, we derive a multiscale continuum theory whose parameters map directly to the discrete model. Analytical solutions of this theory show the concentric patterns arise from anisotropically accumulated resistance to growth over many cell cycles. This Letter shows how purely mechanical processes can affect the internal patterning and morphology of cell collectives, and provides a concise theoretical framework for connecting the micro- to macroscopic dynamics of proliferating matter.",

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AU - Palmer, Bryce

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AU - Farhadifar, Reza

AU - Shelley, Michael J.

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Mechanics and Morphology of Proliferating Cell Collectives with Self-Inhibiting Growth

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