A data-motivated density-dependent diffusion model of in vitro glioblastoma growth

Tracy L. Stepien; Erica M. Rutter; Yang Kuang

doi:10.3934/mbe.2015.12.1157

A data-motivated density-dependent diffusion model of in vitro glioblastoma growth

Tracy L. Stepien, Erica M. Rutter, Yang Kuang

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

26 Scopus citations

Abstract

Glioblastoma multiforme is an aggressive brain cancer that is extremely fatal. It is characterized by both proliferation and large amounts of migration, which contributes to the difficulty of treatment. Previous models of this type of cancer growth often include two separate equations to model proliferation or migration. We propose a single equation which uses densitydependent diffusion to capture the behavior of both proliferation and migration. We analyze the model to determine the existence of traveling wave solutions. To prove the viability of the density-dependent diffusion function chosen, we compare our model with well-known in vitro experimental data.

Original language	English (US)
Pages (from-to)	1157-1172
Number of pages	16
Journal	Mathematical Biosciences and Engineering
Volume	12
Issue number	6
DOIs	https://doi.org/10.3934/mbe.2015.12.1157
State	Published - Dec 1 2015

Keywords

Biomathematical modeling
Glioblastoma
Traveling waves
Tumor growth simulation

ASJC Scopus subject areas

Modeling and Simulation
General Agricultural and Biological Sciences
Computational Mathematics
Applied Mathematics

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10.3934/mbe.2015.12.1157

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abstract = "Glioblastoma multiforme is an aggressive brain cancer that is extremely fatal. It is characterized by both proliferation and large amounts of migration, which contributes to the difficulty of treatment. Previous models of this type of cancer growth often include two separate equations to model proliferation or migration. We propose a single equation which uses densitydependent diffusion to capture the behavior of both proliferation and migration. We analyze the model to determine the existence of traveling wave solutions. To prove the viability of the density-dependent diffusion function chosen, we compare our model with well-known in vitro experimental data.",

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AU - Rutter, Erica M.

AU - Kuang, Yang

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N2 - Glioblastoma multiforme is an aggressive brain cancer that is extremely fatal. It is characterized by both proliferation and large amounts of migration, which contributes to the difficulty of treatment. Previous models of this type of cancer growth often include two separate equations to model proliferation or migration. We propose a single equation which uses densitydependent diffusion to capture the behavior of both proliferation and migration. We analyze the model to determine the existence of traveling wave solutions. To prove the viability of the density-dependent diffusion function chosen, we compare our model with well-known in vitro experimental data.

AB - Glioblastoma multiforme is an aggressive brain cancer that is extremely fatal. It is characterized by both proliferation and large amounts of migration, which contributes to the difficulty of treatment. Previous models of this type of cancer growth often include two separate equations to model proliferation or migration. We propose a single equation which uses densitydependent diffusion to capture the behavior of both proliferation and migration. We analyze the model to determine the existence of traveling wave solutions. To prove the viability of the density-dependent diffusion function chosen, we compare our model with well-known in vitro experimental data.

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KW - Traveling waves

KW - Tumor growth simulation

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A data-motivated density-dependent diffusion model of in vitro glioblastoma growth

Abstract

Keywords

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