Multiscale modeling of glioma invasion: from receptor binding to flux-limited macroscopic PDEs

Anne Dietrich; Niklas Kolbe; Nikolaos Sfakianakis; Christina Surulescu

Multiscale modeling of glioma invasion: from receptor binding to flux-limited macroscopic PDEs

Anne Dietrich, Niklas Kolbe, Nikolaos Sfakianakis, Christina Surulescu

Applied Mathematics

Research output: Working paper

Abstract

We propose a novel approach to modeling cell migration in an anisotropic environment with biochemical heterogeneity and interspecies interactions, using as a paradigm glioma invasion in brain tissue under the influence of hypoxia-triggered angiogenesis. The multiscale procedure links single-cell and mesoscopic dynamics with population level behavior, leading on the macroscopic scale to flux-limited glioma diffusion and multiple taxis. We verify the non-negativity of regular solutions (provided they exist) to the obtained macroscopic PDE-ODE system and perform numerical simulations to illustrate the solution behavior under several scenarios.

Original language	English
Publication status	Published - 7 Oct 2020

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http://arxiv.org/abs/2010.03277v1

Multiscale modeling of glioma invasion: from receptor binding to flux-limited macroscopic PDEs
Dietrich, A., Kolbe, N., Sfakianakis, N. & Surulescu, C., 24 Jun 2022, In: Multiscale Modeling and Simulation. 20, 2, p. 685-713 29 p.
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abstract = "We propose a novel approach to modeling cell migration in an anisotropic environment with biochemical heterogeneity and interspecies interactions, using as a paradigm glioma invasion in brain tissue under the influence of hypoxia-triggered angiogenesis. The multiscale procedure links single-cell and mesoscopic dynamics with population level behavior, leading on the macroscopic scale to flux-limited glioma diffusion and multiple taxis. We verify the non-negativity of regular solutions (provided they exist) to the obtained macroscopic PDE-ODE system and perform numerical simulations to illustrate the solution behavior under several scenarios. ",

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AU - Surulescu, Christina

PY - 2020/10/7

Y1 - 2020/10/7

N2 - We propose a novel approach to modeling cell migration in an anisotropic environment with biochemical heterogeneity and interspecies interactions, using as a paradigm glioma invasion in brain tissue under the influence of hypoxia-triggered angiogenesis. The multiscale procedure links single-cell and mesoscopic dynamics with population level behavior, leading on the macroscopic scale to flux-limited glioma diffusion and multiple taxis. We verify the non-negativity of regular solutions (provided they exist) to the obtained macroscopic PDE-ODE system and perform numerical simulations to illustrate the solution behavior under several scenarios.

AB - We propose a novel approach to modeling cell migration in an anisotropic environment with biochemical heterogeneity and interspecies interactions, using as a paradigm glioma invasion in brain tissue under the influence of hypoxia-triggered angiogenesis. The multiscale procedure links single-cell and mesoscopic dynamics with population level behavior, leading on the macroscopic scale to flux-limited glioma diffusion and multiple taxis. We verify the non-negativity of regular solutions (provided they exist) to the obtained macroscopic PDE-ODE system and perform numerical simulations to illustrate the solution behavior under several scenarios.

M3 - Working paper

BT - Multiscale modeling of glioma invasion

ER -

Multiscale modeling of glioma invasion: from receptor binding to flux-limited macroscopic PDEs

Abstract

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Multiscale modeling of glioma invasion: from receptor binding to flux-limited macroscopic PDEs

Cite this