Tumor growth modeling from the perspective of multiphase porous media mechanics

G. Sciumè; S. E. Shelton; W. G. Gray; C. T. Miller; F. Hussain; M. Ferrari; P. Decuzzi; B. A. Schrefler

Tumor growth modeling from the perspective of multiphase porous media mechanics

G. Sciumè, S. E. Shelton, W. G. Gray, C. T. Miller, F. Hussain, M. Ferrari, P. Decuzzi, B. A. Schrefler

Mechanical Engineering

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

21 Scopus citations

Abstract

Multiphase porous media mechanics is used for modeling tumor growth, using governing equations obtained via the Thermodynamically Constrained Averaging Theory (TCAT). This approach incorporates the interaction of more phases than legacy tumor growth models. The tumor is treated as a multiphase system composed of an extracellular matrix, tumor cells which may become necrotic depending on nutrient level and pressure, healthy cells and an interstitial fluid which transports nutrients. The governing equations are numerically solved within a Finite Element framework for predicting the growth rate of the tumor mass, and of its individual components, as a function of the initial tumor-to-healthy cell ratio, nutrient concentration, and mechanical strain. Preliminary results are shown.

Original language	English
Pages (from-to)	193-212
Number of pages	20
Journal	MCB Molecular and Cellular Biomechanics
Volume	9
Issue number	3
State	Published - 2012

Keywords

Finite Elements
Necrosis
Porous media mechanics
TCAT
Tumor growth

Cite this

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abstract = "Multiphase porous media mechanics is used for modeling tumor growth, using governing equations obtained via the Thermodynamically Constrained Averaging Theory (TCAT). This approach incorporates the interaction of more phases than legacy tumor growth models. The tumor is treated as a multiphase system composed of an extracellular matrix, tumor cells which may become necrotic depending on nutrient level and pressure, healthy cells and an interstitial fluid which transports nutrients. The governing equations are numerically solved within a Finite Element framework for predicting the growth rate of the tumor mass, and of its individual components, as a function of the initial tumor-to-healthy cell ratio, nutrient concentration, and mechanical strain. Preliminary results are shown.",

keywords = "Finite Elements, Necrosis, Porous media mechanics, TCAT, Tumor growth",

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T1 - Tumor growth modeling from the perspective of multiphase porous media mechanics

AU - Sciumè, G.

AU - Shelton, S. E.

AU - Gray, W. G.

AU - Miller, C. T.

AU - Hussain, F.

AU - Ferrari, M.

AU - Decuzzi, P.

AU - Schrefler, B. A.

PY - 2012

Y1 - 2012

N2 - Multiphase porous media mechanics is used for modeling tumor growth, using governing equations obtained via the Thermodynamically Constrained Averaging Theory (TCAT). This approach incorporates the interaction of more phases than legacy tumor growth models. The tumor is treated as a multiphase system composed of an extracellular matrix, tumor cells which may become necrotic depending on nutrient level and pressure, healthy cells and an interstitial fluid which transports nutrients. The governing equations are numerically solved within a Finite Element framework for predicting the growth rate of the tumor mass, and of its individual components, as a function of the initial tumor-to-healthy cell ratio, nutrient concentration, and mechanical strain. Preliminary results are shown.

AB - Multiphase porous media mechanics is used for modeling tumor growth, using governing equations obtained via the Thermodynamically Constrained Averaging Theory (TCAT). This approach incorporates the interaction of more phases than legacy tumor growth models. The tumor is treated as a multiphase system composed of an extracellular matrix, tumor cells which may become necrotic depending on nutrient level and pressure, healthy cells and an interstitial fluid which transports nutrients. The governing equations are numerically solved within a Finite Element framework for predicting the growth rate of the tumor mass, and of its individual components, as a function of the initial tumor-to-healthy cell ratio, nutrient concentration, and mechanical strain. Preliminary results are shown.

KW - Finite Elements

KW - Necrosis

KW - Porous media mechanics

KW - TCAT

KW - Tumor growth

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AN - SCOPUS:84872473098

SN - 1556-5297

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JO - MCB Molecular and Cellular Biomechanics

JF - MCB Molecular and Cellular Biomechanics

IS - 3

ER -

Tumor growth modeling from the perspective of multiphase porous media mechanics

Abstract

Keywords

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