Coupling tumor growth and bio distribution models

Raffaella Santagiuliana; Miljan Milosevic; Bogdan Milicevic; Giuseppe Sciumè; Vladimir Simic; Arturas Ziemys; Milos Kojic; Bernhard A. Schrefler

doi:10.1007/s10544-019-0368-y

Coupling tumor growth and bio distribution models

Raffaella Santagiuliana, Miljan Milosevic, Bogdan Milicevic, Giuseppe Sciumè, Vladimir Simic, Arturas Ziemys, Milos Kojic, Bernhard A. Schrefler

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

12 Scopus citations

Abstract

We couple a tumor growth model embedded in a microenvironment, with a bio distribution model able to simulate a whole organ. The growth model yields the evolution of tumor cell population, of the differential pressure between cell populations, of porosity of ECM, of consumption of nutrients due to tumor growth, of angiogenesis, and related growth factors as function of the locally available nutrient. The bio distribution model on the other hand operates on a frozen geometry but yields a much refined distribution of nutrient and other molecules. The combination of both models will enable simulating the growth of a tumor in a whole organ, including a realistic distribution of therapeutic agents and allow hence to evaluate the efficacy of these agents.

Original language	English (US)
Article number	33
Journal	Biomedical Microdevices
Volume	21
Issue number	2
DOIs	https://doi.org/10.1007/s10544-019-0368-y
State	Published - Jun 1 2019

Keywords

Angiogenesis
Biodistribution
Code coupling
Modeling
Multiphase
Smearded finite element

ASJC Scopus subject areas

Biomedical Engineering
Molecular Biology

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10.1007/s10544-019-0368-y

Cite this

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title = "Coupling tumor growth and bio distribution models",

abstract = "We couple a tumor growth model embedded in a microenvironment, with a bio distribution model able to simulate a whole organ. The growth model yields the evolution of tumor cell population, of the differential pressure between cell populations, of porosity of ECM, of consumption of nutrients due to tumor growth, of angiogenesis, and related growth factors as function of the locally available nutrient. The bio distribution model on the other hand operates on a frozen geometry but yields a much refined distribution of nutrient and other molecules. The combination of both models will enable simulating the growth of a tumor in a whole organ, including a realistic distribution of therapeutic agents and allow hence to evaluate the efficacy of these agents.",

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AU - Santagiuliana, Raffaella

AU - Milosevic, Miljan

AU - Milicevic, Bogdan

AU - Sciumè, Giuseppe

AU - Simic, Vladimir

AU - Ziemys, Arturas

AU - Kojic, Milos

AU - Schrefler, Bernhard A.

PY - 2019/6/1

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N2 - We couple a tumor growth model embedded in a microenvironment, with a bio distribution model able to simulate a whole organ. The growth model yields the evolution of tumor cell population, of the differential pressure between cell populations, of porosity of ECM, of consumption of nutrients due to tumor growth, of angiogenesis, and related growth factors as function of the locally available nutrient. The bio distribution model on the other hand operates on a frozen geometry but yields a much refined distribution of nutrient and other molecules. The combination of both models will enable simulating the growth of a tumor in a whole organ, including a realistic distribution of therapeutic agents and allow hence to evaluate the efficacy of these agents.

AB - We couple a tumor growth model embedded in a microenvironment, with a bio distribution model able to simulate a whole organ. The growth model yields the evolution of tumor cell population, of the differential pressure between cell populations, of porosity of ECM, of consumption of nutrients due to tumor growth, of angiogenesis, and related growth factors as function of the locally available nutrient. The bio distribution model on the other hand operates on a frozen geometry but yields a much refined distribution of nutrient and other molecules. The combination of both models will enable simulating the growth of a tumor in a whole organ, including a realistic distribution of therapeutic agents and allow hence to evaluate the efficacy of these agents.

KW - Angiogenesis

KW - Biodistribution

KW - Code coupling

KW - Modeling

KW - Multiphase

KW - Smearded finite element

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Coupling tumor growth and bio distribution models

Abstract

Keywords

ASJC Scopus subject areas

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