Modeling tumor cell migration: From microscopic to macroscopic models

It has been shown experimentally that contact interactions may influence the migration of cancer cells. Previous works have modelized this thanks to stochastic, discrete models (cellular automata) at the cell level. However, for the study of the growth of real-size tumors with several million cells,...

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Published inPhysical review. E, Statistical, nonlinear, and soft matter physics Vol. 79; no. 3 Pt 1; p. 031917
Main Authors Deroulers, Christophe, Aubert, Marine, Badoual, Mathilde, Grammaticos, Basil
Format Journal Article
LanguageEnglish
Published United States 01.03.2009
Subjects
Cell Communication
Cell Count
Cell Movement
Diffusion
Kinetics
Models, Biological
Neoplasms - pathology
Nonlinear Dynamics
Reproducibility of Results
Stochastic Processes
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Summary:It has been shown experimentally that contact interactions may influence the migration of cancer cells. Previous works have modelized this thanks to stochastic, discrete models (cellular automata) at the cell level. However, for the study of the growth of real-size tumors with several million cells, it is best to use a macroscopic model having the form of a partial differential equation (PDE) for the density of cells. The difficulty is to predict the effect, at the macroscopic scale, of contact interactions that take place at the microscopic scale. To address this, we use a multiscale approach: starting from a very simple, yet experimentally validated, microscopic model of migration with contact interactions, we derive a macroscopic model. We show that a diffusion equation arises, as is often postulated in the field of glioma modeling, but it is nonlinear because of the interactions. We give the explicit dependence of diffusivity on the cell density and on a parameter governing cell-cell interactions. We discuss in detail the conditions of validity of the approximations used in the derivation, and we compare analytic results from our PDE to numerical simulations and to some in vitro experiments. We notice that the family of microscopic models we started from includes as special cases some kinetically constrained models that were introduced for the study of the physics of glasses, supercooled liquids, and jamming systems.
ISSN:1539-3755
DOI:10.1103/PhysRevE.79.031917