The role of topology and mechanics in uniaxially growing cell networks

Alexander Erlich; Gareth Jones; Francoise Tisseur; Derek E. Moulton; Alain Goriely

doi:10.1098/rspa.2019.0523

The role of topology and mechanics in uniaxially growing cell networks

Alexander Erlich, Gareth Jones, Francoise Tisseur, Derek E. Moulton, Alain Goriely

Applied Mathematics

Oxford University

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

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Abstract

In biological systems, the growth of cells, tissues and organs is influenced by mechanical cues. Locally, cell growth leads to a mechanically heterogeneous environment as cells pull and push their neighbours in a cell network. Despite this local heterogeneity, at the tissue level, the cell network is remarkably robust, as it is not easily perturbed by changes in the mechanical environment or the network connectivity. Through a network model, we relate global tissue structure (i.e. the cell network topology) and local growth mechanisms (growth laws) to the overall tissue response. Within this framework, we investigate the two main mechanical growth laws that have been proposed: stress-driven or strain-driven growth. We show that in order to create a robust and stable tissue environment, networks with predominantly series connections are naturally driven by stress-driven growth, whereas networks with predominantly parallel connections are associated with strain-driven growth.

Original language	English
Article number	20190523
Journal	Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences
Volume	476
Issue number	2233
Early online date	29 Jan 2020
DOIs	https://doi.org/10.1098/rspa.2019.0523
Publication status	Published - Jan 2020

Keywords

Biological tissues
Cell mechanics
Growth modelling
Network structure
Self-organization

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Growth-Network-RSPA-AcceptedAccepted author manuscript, 3.1 MB

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title = "The role of topology and mechanics in uniaxially growing cell networks",

abstract = "In biological systems, the growth of cells, tissues and organs is influenced by mechanical cues. Locally, cell growth leads to a mechanically heterogeneous environment as cells pull and push their neighbours in a cell network. Despite this local heterogeneity, at the tissue level, the cell network is remarkably robust, as it is not easily perturbed by changes in the mechanical environment or the network connectivity. Through a network model, we relate global tissue structure (i.e. the cell network topology) and local growth mechanisms (growth laws) to the overall tissue response. Within this framework, we investigate the two main mechanical growth laws that have been proposed: stress-driven or strain-driven growth. We show that in order to create a robust and stable tissue environment, networks with predominantly series connections are naturally driven by stress-driven growth, whereas networks with predominantly parallel connections are associated with strain-driven growth.",

keywords = "Biological tissues, Cell mechanics, Growth modelling, Network structure, Self-organization",

author = "Alexander Erlich and Gareth Jones and Francoise Tisseur and Moulton, {Derek E.} and Alain Goriely",

note = "Funding Information: Data accessibility. All data needed to evaluate the results and conclusions are present in the paper. The associated datasets and codes can be accessed via the Figshare repository (https://doi.org/10.6084/m9. figshare.10315775). Authors{\textquoteright} contributions. A.G., D.E.M. and A.E. devised the study, A.E. conducted the analysis, G.W.J. and A.E. devised the network description, F.T. and A.E. formulated the algebraic theorems and proofs; all authors contributed to the writing of the paper. Competing interests. We have no competing interests. Funding. This work was supported by Engineering and Physical Sciences Research Council grant no. EP/R020205/1 to A.G. Publisher Copyright: {\textcopyright} 2020 Royal Society Publishing. All rights reserved. Copyright: Copyright 2020 Elsevier B.V., All rights reserved.",

year = "2020",

month = jan,

doi = "10.1098/rspa.2019.0523",

language = "English",

volume = "476",

journal = "Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences",

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AU - Erlich, Alexander

AU - Jones, Gareth

AU - Tisseur, Francoise

AU - Moulton, Derek E.

AU - Goriely, Alain

N1 - Funding Information: Data accessibility. All data needed to evaluate the results and conclusions are present in the paper. The associated datasets and codes can be accessed via the Figshare repository (https://doi.org/10.6084/m9. figshare.10315775). Authors’ contributions. A.G., D.E.M. and A.E. devised the study, A.E. conducted the analysis, G.W.J. and A.E. devised the network description, F.T. and A.E. formulated the algebraic theorems and proofs; all authors contributed to the writing of the paper. Competing interests. We have no competing interests. Funding. This work was supported by Engineering and Physical Sciences Research Council grant no. EP/R020205/1 to A.G. Publisher Copyright: © 2020 Royal Society Publishing. All rights reserved. Copyright: Copyright 2020 Elsevier B.V., All rights reserved.

PY - 2020/1

Y1 - 2020/1

N2 - In biological systems, the growth of cells, tissues and organs is influenced by mechanical cues. Locally, cell growth leads to a mechanically heterogeneous environment as cells pull and push their neighbours in a cell network. Despite this local heterogeneity, at the tissue level, the cell network is remarkably robust, as it is not easily perturbed by changes in the mechanical environment or the network connectivity. Through a network model, we relate global tissue structure (i.e. the cell network topology) and local growth mechanisms (growth laws) to the overall tissue response. Within this framework, we investigate the two main mechanical growth laws that have been proposed: stress-driven or strain-driven growth. We show that in order to create a robust and stable tissue environment, networks with predominantly series connections are naturally driven by stress-driven growth, whereas networks with predominantly parallel connections are associated with strain-driven growth.

AB - In biological systems, the growth of cells, tissues and organs is influenced by mechanical cues. Locally, cell growth leads to a mechanically heterogeneous environment as cells pull and push their neighbours in a cell network. Despite this local heterogeneity, at the tissue level, the cell network is remarkably robust, as it is not easily perturbed by changes in the mechanical environment or the network connectivity. Through a network model, we relate global tissue structure (i.e. the cell network topology) and local growth mechanisms (growth laws) to the overall tissue response. Within this framework, we investigate the two main mechanical growth laws that have been proposed: stress-driven or strain-driven growth. We show that in order to create a robust and stable tissue environment, networks with predominantly series connections are naturally driven by stress-driven growth, whereas networks with predominantly parallel connections are associated with strain-driven growth.

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KW - Cell mechanics

KW - Growth modelling

KW - Network structure

KW - Self-organization

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The role of topology and mechanics in uniaxially growing cell networks

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