Analysis of a new multispecies tumor growth model coupling 3D phase-fields with a 1D vascular network

Marvin Fritz; Prashant K. Jha; Tobias Köppl; J. Tinsley Oden; Barbara Wohlmuth

doi:10.1016/j.nonrwa.2021.103331

Analysis of a new multispecies tumor growth model coupling 3D phase-fields with a 1D vascular network

Marvin Fritz, Prashant K. Jha, Tobias Köppl, J. Tinsley Oden, Barbara Wohlmuth

Chair of Numerical Analysis

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

21 Scopus citations

Abstract

In this work, we present and analyze a mathematical model for tumor growth incorporating ECM erosion, interstitial flow, and the effect of vascular flow and nutrient transport. The model is of phase-field or diffused-interface type in which multiple phases of cell species and other constituents are separated by smooth evolving interfaces. The model involves a mesoscale version of Darcy's law to capture the flow mechanism in the tissue matrix. Modeling flow and transport processes in the vasculature supplying the healthy and cancerous tissue, one-dimensional (1D) equations are considered. Since the models governing the transport and flow processes are defined together with cell species models on a three-dimensional (3D) domain, we obtain a 3D–1D coupled model.

Original language	English
Article number	103331
Journal	Nonlinear Analysis: Real World Applications
Volume	61
DOIs	https://doi.org/10.1016/j.nonrwa.2021.103331
State	Published - Oct 2021

Keywords

3D–1D coupled blood flow models
ECM degradation
Energy inequality
Existence of weak solutions
Galerkin method
Tumor growth

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

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10.1016/j.nonrwa.2021.103331

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title = "Analysis of a new multispecies tumor growth model coupling 3D phase-fields with a 1D vascular network",

abstract = "In this work, we present and analyze a mathematical model for tumor growth incorporating ECM erosion, interstitial flow, and the effect of vascular flow and nutrient transport. The model is of phase-field or diffused-interface type in which multiple phases of cell species and other constituents are separated by smooth evolving interfaces. The model involves a mesoscale version of Darcy's law to capture the flow mechanism in the tissue matrix. Modeling flow and transport processes in the vasculature supplying the healthy and cancerous tissue, one-dimensional (1D) equations are considered. Since the models governing the transport and flow processes are defined together with cell species models on a three-dimensional (3D) domain, we obtain a 3D–1D coupled model.",

keywords = "3D–1D coupled blood flow models, ECM degradation, Energy inequality, Existence of weak solutions, Galerkin method, Tumor growth",

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AU - Fritz, Marvin

AU - Jha, Prashant K.

AU - Köppl, Tobias

AU - Oden, J. Tinsley

AU - Wohlmuth, Barbara

PY - 2021/10

Y1 - 2021/10

N2 - In this work, we present and analyze a mathematical model for tumor growth incorporating ECM erosion, interstitial flow, and the effect of vascular flow and nutrient transport. The model is of phase-field or diffused-interface type in which multiple phases of cell species and other constituents are separated by smooth evolving interfaces. The model involves a mesoscale version of Darcy's law to capture the flow mechanism in the tissue matrix. Modeling flow and transport processes in the vasculature supplying the healthy and cancerous tissue, one-dimensional (1D) equations are considered. Since the models governing the transport and flow processes are defined together with cell species models on a three-dimensional (3D) domain, we obtain a 3D–1D coupled model.

AB - In this work, we present and analyze a mathematical model for tumor growth incorporating ECM erosion, interstitial flow, and the effect of vascular flow and nutrient transport. The model is of phase-field or diffused-interface type in which multiple phases of cell species and other constituents are separated by smooth evolving interfaces. The model involves a mesoscale version of Darcy's law to capture the flow mechanism in the tissue matrix. Modeling flow and transport processes in the vasculature supplying the healthy and cancerous tissue, one-dimensional (1D) equations are considered. Since the models governing the transport and flow processes are defined together with cell species models on a three-dimensional (3D) domain, we obtain a 3D–1D coupled model.

KW - 3D–1D coupled blood flow models

KW - ECM degradation

KW - Energy inequality

KW - Existence of weak solutions

KW - Galerkin method

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Analysis of a new multispecies tumor growth model coupling 3D phase-fields with a 1D vascular network

Abstract

Keywords

UN SDGs

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