Finite-Difference and Pseudo-Sprectral Methods for the Numerical Simulations of In Vitro Human Tumor Cell Population Kinetics

Z. Jackiewicz; Barbara Zubik-Kowal; B. Basse

Finite-Difference and Pseudo-Sprectral Methods for the Numerical Simulations of In Vitro Human Tumor Cell Population Kinetics

Z. Jackiewicz, Barbara Zubik-Kowal, B. Basse

Mathematics Department

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Abstract

Pseudo-spectral approximations are constructed for the model equations which describe the population kinetics of human tumor cells in vitro and their responses to radiotherapy or chemotherapy. These approximations are more efficient than finite-difference approximations. The spectral accuracy of the pseudo-spectral method allows us to resolve the model with a much smaller number of spatial grid-points than required for the finite-difference method to achieve comparable accuracy. This is demonstrated by numerical experiments which show a good agreement between predicted and experimental data.

Original language	American English
Journal	Mathematical Biosciences and Engineering
State	Published - 1 Jun 2009

Keywords

Population kinetics of human cancer cells in vitro
cell cycle dynamics
finite-difference methods
human tumor cells
mathematical model
pseudo-spectral methods

EGS Disciplines

Mathematics

UN SDGs

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

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Finite-Difference and Pseudo-Sprectral Methods for the NumericalFinal published version, 335 KBLicense: Unspecified

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title = "Finite-Difference and Pseudo-Sprectral Methods for the Numerical Simulations of In Vitro Human Tumor Cell Population Kinetics",

abstract = " Pseudo-spectral approximations are constructed for the model equations which describe the population kinetics of human tumor cells in vitro and their responses to radiotherapy or chemotherapy. These approximations are more efficient than finite-difference approximations. The spectral accuracy of the pseudo-spectral method allows us to resolve the model with a much smaller number of spatial grid-points than required for the finite-difference method to achieve comparable accuracy. This is demonstrated by numerical experiments which show a good agreement between predicted and experimental data.",

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T1 - Finite-Difference and Pseudo-Sprectral Methods for the Numerical Simulations of In Vitro Human Tumor Cell Population Kinetics

AU - Jackiewicz, Z.

AU - Zubik-Kowal, Barbara

AU - Basse, B.

PY - 2009/6/1

Y1 - 2009/6/1

N2 - Pseudo-spectral approximations are constructed for the model equations which describe the population kinetics of human tumor cells in vitro and their responses to radiotherapy or chemotherapy. These approximations are more efficient than finite-difference approximations. The spectral accuracy of the pseudo-spectral method allows us to resolve the model with a much smaller number of spatial grid-points than required for the finite-difference method to achieve comparable accuracy. This is demonstrated by numerical experiments which show a good agreement between predicted and experimental data.

AB - Pseudo-spectral approximations are constructed for the model equations which describe the population kinetics of human tumor cells in vitro and their responses to radiotherapy or chemotherapy. These approximations are more efficient than finite-difference approximations. The spectral accuracy of the pseudo-spectral method allows us to resolve the model with a much smaller number of spatial grid-points than required for the finite-difference method to achieve comparable accuracy. This is demonstrated by numerical experiments which show a good agreement between predicted and experimental data.

KW - Population kinetics of human cancer cells in vitro

KW - cell cycle dynamics

KW - finite-difference methods

KW - human tumor cells

KW - mathematical model

KW - pseudo-spectral methods

UR - https://scholarworks.boisestate.edu/math_facpubs/5

M3 - Article

SN - 1547-1063

JO - Mathematical Biosciences and Engineering

JF - Mathematical Biosciences and Engineering

ER -

Finite-Difference and Pseudo-Sprectral Methods for the Numerical Simulations of In Vitro Human Tumor Cell Population Kinetics

Abstract

Keywords

EGS Disciplines

UN SDGs

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