Solutions for the Cell Cycle in Cell Lines Derived from Human Tumors

B. Zubik-Kowal

doi:10.1080/10273660601017254

Solutions for the Cell Cycle in Cell Lines Derived from Human Tumors

B. Zubik-Kowal

Mathematics Department

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

13 Scopus citations

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Abstract

The goal of the paper is to compute efficiently solutions for model equations that have the potential to describe the growth of human tumor cells and their responses to radiotherapy or chemotherapy. The mathematical model involves four unknown functions of two independent variables: the time variable t and dimensionless relative DNA content x . The unknown functions can be thought of as the number density of cells and are solutions of a system of four partial differential equations. We construct solutions of the system, which allow us to observe the number density of cells for different t and x values. We present results of our experiments which simulate population kinetics of human cancer cells in vitro . Our results show a correspondence between predicted and experimental data.

Original language	American English
Pages (from-to)	215-228
Number of pages	14
Journal	Computational and Mathematical Methods in Medicine
Volume	7
Issue number	4
DOIs	https://doi.org/10.1080/10273660601017254
State	Published - Dec 2006

Keywords

cell cycle dynamics
human tumor cells
mathematical model
population kinetics of human cancer cells in vitro

EGS Disciplines

Mathematics

UN SDGs

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

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10.1080/10273660601017254

Solutions for the Cell Cycle in Cell Lines Derived from Human TumFinal published version, 1.25 MBLicense: Unspecified

Cite this

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title = "Solutions for the Cell Cycle in Cell Lines Derived from Human Tumors",

abstract = " The goal of the paper is to compute efficiently solutions for model equations that have the potential to describe the growth of human tumor cells and their responses to radiotherapy or chemotherapy. The mathematical model involves four unknown functions of two independent variables: the time variable t and dimensionless relative DNA content x . The unknown functions can be thought of as the number density of cells and are solutions of a system of four partial differential equations. We construct solutions of the system, which allow us to observe the number density of cells for different t and x values. We present results of our experiments which simulate population kinetics of human cancer cells in vitro . Our results show a correspondence between predicted and experimental data.",

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AU - Zubik-Kowal, B.

PY - 2006/12

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N2 - The goal of the paper is to compute efficiently solutions for model equations that have the potential to describe the growth of human tumor cells and their responses to radiotherapy or chemotherapy. The mathematical model involves four unknown functions of two independent variables: the time variable t and dimensionless relative DNA content x . The unknown functions can be thought of as the number density of cells and are solutions of a system of four partial differential equations. We construct solutions of the system, which allow us to observe the number density of cells for different t and x values. We present results of our experiments which simulate population kinetics of human cancer cells in vitro . Our results show a correspondence between predicted and experimental data.

AB - The goal of the paper is to compute efficiently solutions for model equations that have the potential to describe the growth of human tumor cells and their responses to radiotherapy or chemotherapy. The mathematical model involves four unknown functions of two independent variables: the time variable t and dimensionless relative DNA content x . The unknown functions can be thought of as the number density of cells and are solutions of a system of four partial differential equations. We construct solutions of the system, which allow us to observe the number density of cells for different t and x values. We present results of our experiments which simulate population kinetics of human cancer cells in vitro . Our results show a correspondence between predicted and experimental data.

KW - cell cycle dynamics

KW - human tumor cells

KW - mathematical model

KW - population kinetics of human cancer cells in vitro

UR - https://www.scopus.com/pages/publications/34547428408

UR - https://scholarworks.boisestate.edu/math_facpubs/238

U2 - 10.1080/10273660601017254

DO - 10.1080/10273660601017254

M3 - Article

SN - 1748-670X

VL - 7

SP - 215

EP - 228

JO - Computational and Mathematical Methods in Medicine

JF - Computational and Mathematical Methods in Medicine

IS - 4

ER -

Solutions for the Cell Cycle in Cell Lines Derived from Human Tumors

Abstract

Keywords

EGS Disciplines

UN SDGs

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