Modelling non-local cell-cell adhesion: a multiscale approach

Anna Zhigun; Mabel Lizzy Rajendran

doi:10.1007/s00285-024-02079-8

Modelling non-local cell-cell adhesion: a multiscale approach

Anna Zhigun^*, Mabel Lizzy Rajendran

^*Corresponding author for this work

Mathematics

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Abstract

Cell-cell adhesion plays a vital role in the development and maintenance of multicellular organisms. One of its functions is regulation of cell migration, such as occurs, e.g. during embryogenesis or in cancer. In this work, we develop a versatile multiscale approach to modelling a moving self-adhesive cell population that combines a careful microscopic description of a deterministic adhesion-driven motion component with an efficient mesoscopic representation of a stochastic velocity-jump process. This approach gives rise to mesoscopic models in the form of kinetic transport equations featuring multiple non-localities. Subsequent parabolic and hyperbolic scalings produce general classes of equations with non-local adhesion and myopic diffusion, a special case being the classical macroscopic model proposed in Armstrong et al. (J Theoret Biol 243(1): 98–113, 2006). Our simulations show how the combination of the two motion effects can unfold. Cell-cell adhesion relies on the subcellular cell adhesion molecule binding. Our approach lends itself conveniently to capturing this microscopic effect. On the macroscale, this results in an additional non-linear integral equation of a novel type that is coupled to the cell density equation.

Original language	English
Article number	55
Number of pages	35
Journal	Journal of Mathematical Biology
Volume	88
Issue number	5
Early online date	3 Apr 2024
DOIs	https://doi.org/10.1007/s00285-024-02079-8
Publication status	E-pub ahead of print - 3 Apr 2024

Bibliographical note

Acknowledgements
The authors thank Christina Surulescu (RPTU Kaiserslautern-Landau) for stimulating discussions. The authors were supported by the Engineering and Physical Sciences Research Council [grant number EP/T03131X/1]. For the purpose of open access, the authors have applied a Creative Commons Attribution (CC BY) licence to any Author Accepted Manuscript version arising. All data is provided in full in Sect. 5 of this paper.

Keywords

Kinetic transport equations
Diffusion-adhesion equations
Non-local models
35B27
35Q49
35Q92
Cadherin binding
Multiscale modelling
Parabolic scaling
Cell movement
Cell adhesion molecule binding
45K05
92C17
Cell-cell adhesion
Myopic diffusion
Hyperbolic scaling

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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Cite this

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title = "Modelling non-local cell-cell adhesion: a multiscale approach",

abstract = "Cell-cell adhesion plays a vital role in the development and maintenance of multicellular organisms. One of its functions is regulation of cell migration, such as occurs, e.g. during embryogenesis or in cancer. In this work, we develop a versatile multiscale approach to modelling a moving self-adhesive cell population that combines a careful microscopic description of a deterministic adhesion-driven motion component with an efficient mesoscopic representation of a stochastic velocity-jump process. This approach gives rise to mesoscopic models in the form of kinetic transport equations featuring multiple non-localities. Subsequent parabolic and hyperbolic scalings produce general classes of equations with non-local adhesion and myopic diffusion, a special case being the classical macroscopic model proposed in Armstrong et al. (J Theoret Biol 243(1): 98–113, 2006). Our simulations show how the combination of the two motion effects can unfold. Cell-cell adhesion relies on the subcellular cell adhesion molecule binding. Our approach lends itself conveniently to capturing this microscopic effect. On the macroscale, this results in an additional non-linear integral equation of a novel type that is coupled to the cell density equation.",

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author = "Anna Zhigun and Rajendran, {Mabel Lizzy}",

note = "Acknowledgements The authors thank Christina Surulescu (RPTU Kaiserslautern-Landau) for stimulating discussions. The authors were supported by the Engineering and Physical Sciences Research Council [grant number EP/T03131X/1]. For the purpose of open access, the authors have applied a Creative Commons Attribution (CC BY) licence to any Author Accepted Manuscript version arising. All data is provided in full in Sect. 5 of this paper.",

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PY - 2024/4/3

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N2 - Cell-cell adhesion plays a vital role in the development and maintenance of multicellular organisms. One of its functions is regulation of cell migration, such as occurs, e.g. during embryogenesis or in cancer. In this work, we develop a versatile multiscale approach to modelling a moving self-adhesive cell population that combines a careful microscopic description of a deterministic adhesion-driven motion component with an efficient mesoscopic representation of a stochastic velocity-jump process. This approach gives rise to mesoscopic models in the form of kinetic transport equations featuring multiple non-localities. Subsequent parabolic and hyperbolic scalings produce general classes of equations with non-local adhesion and myopic diffusion, a special case being the classical macroscopic model proposed in Armstrong et al. (J Theoret Biol 243(1): 98–113, 2006). Our simulations show how the combination of the two motion effects can unfold. Cell-cell adhesion relies on the subcellular cell adhesion molecule binding. Our approach lends itself conveniently to capturing this microscopic effect. On the macroscale, this results in an additional non-linear integral equation of a novel type that is coupled to the cell density equation.

AB - Cell-cell adhesion plays a vital role in the development and maintenance of multicellular organisms. One of its functions is regulation of cell migration, such as occurs, e.g. during embryogenesis or in cancer. In this work, we develop a versatile multiscale approach to modelling a moving self-adhesive cell population that combines a careful microscopic description of a deterministic adhesion-driven motion component with an efficient mesoscopic representation of a stochastic velocity-jump process. This approach gives rise to mesoscopic models in the form of kinetic transport equations featuring multiple non-localities. Subsequent parabolic and hyperbolic scalings produce general classes of equations with non-local adhesion and myopic diffusion, a special case being the classical macroscopic model proposed in Armstrong et al. (J Theoret Biol 243(1): 98–113, 2006). Our simulations show how the combination of the two motion effects can unfold. Cell-cell adhesion relies on the subcellular cell adhesion molecule binding. Our approach lends itself conveniently to capturing this microscopic effect. On the macroscale, this results in an additional non-linear integral equation of a novel type that is coupled to the cell density equation.

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KW - Parabolic scaling

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KW - Cell adhesion molecule binding

KW - 45K05

KW - 92C17

KW - Cell-cell adhesion

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M1 - 55

ER -

Modelling non-local cell-cell adhesion: a multiscale approach

Abstract

Bibliographical note

Keywords

UN SDGs

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