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Free BoundaryProblems Associated with Multiscale Tumor Models

Published online by Cambridge University Press:  05 June 2009

A. Friedman*
Affiliation:
Mathematical Biosciences Institute, The Ohio State University, Columbus, OH 43210, USA
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Abstract

The present paper introduces a tumormodel with two time scales, the time t during which the tumorgrows and the cycle time of individual cells. The model alsoincludes the effects of gene mutations on the population densityof the tumor cells. The model is formulated as a free boundaryproblem for a coupled system of elliptic, parabolic and hyperbolicequations within the tumor region, with nonlinear and nonlocalterms. Existence and uniqueness theorems are proved, andproperties of the free boundary are established.

Type
Research Article
Copyright
© EDP Sciences, 2009

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References

Ayati, B.P., Webb, G.F., Anderson, A.R.A. Computational methods and results for structured mutliscale methods of tumor invasion. Multiscale Model. Simul., 5 (2006), 120. CrossRef
Byrne, H.M.. The importance of intercellular adhesion in the development of carcinomas. I. MA J. Math. Appl. Med. Biol., 14 (1997), 305323. CrossRef
Byrne, H.M., Chaplain, M.A.J.. Growth of nonnecrotic tumors in the presence and absence of inhibitors. Math. Biosci., 130 (1995), 130151. CrossRef
Byrne, H.M., Chaplain, M.A.J.. Modelling the role of cell-cell adhesion in the growth and development of carcinomas. Math. Comput. Modeling, 24 (1996), 117. CrossRef
Chen, X., Cui, S., Friedman, A.. A hyperbolic free boundary problem modeling tumor growth: Asymptotic behavior. Trans. Amer. Math. Soc., 357 (2005), 47714804. CrossRef
Chen, X., Friedman, A.. A free boundary problem for elliptic-hyperbolic system: An application to tumor growth. SIAM J. Math. Anal., 35 (2003), 974986. CrossRef
Cui, S., Friedman, A.. A free boundary problem for a singular system of differential equations: An application to a model of tumor growth. Trans. Amer. Math. Soc., 355 (2003), 35373590. CrossRef
S. Cui, A. Friedman. A hyperbolic free boundary problem modeling tumor growth. Interfaces Free Bound., 5 (2003) , 159–182.
Franks, S.J.H., Byrne, H.M., King, J.P., Underwood, J.C.E., Lewis, C.E.. Modelling the early growth of ductal carcinoma in situ of the breast. J. Math. Biology, 47 (2003), 424452. CrossRef
Franks, S.J.H., Byrne, H.M., King, J.P., Underwood, J.C.E., Lewis, C.E.. Modelling the growth of comedo ductal carcinoma in situ. Mathematical Medicine & Biology, 20 (2003), 277308. CrossRef
Franks, S.J.H., Byrne, H.M., Underwood, J.C.E., Lewis, C.E.. Biological inferences from a mathematical model of comedo ductal carcinoma in situ of the breast. J. Theoretical Biology, 232 (2005), 523543. CrossRef
Franks, S.J.H., King, J.P.. Interactions between a uniformly proliferating tumour and its surroundings: Uniform material properties. Mathematical Medicine & Biology, 20 (2003), 4789. CrossRef
A. Friedman. Cancer models and their mathematical analysis. In: Tutorials in Mathematical Biosciences III. Lecture Notes in Mathematics, 1872, 223-246. Springer, Berlin, 2006.
Friedman, A.. A free boundary problem for a coupled system of elliptic, hyperbolic, and Stokes equations modeling tumor growth. Interfaces and Free Boundaries, 8 (2006), 247261. CrossRef
Friedman, A.. Mathematical analysis and challenges arising from models of tumor growth. Math. Models & Methods in Applied Sciences, 17 (2007), 17511772. CrossRef
Friedman, A.. A multiscale tumor model. Interfaces and Free Boundaries, 10 (2008), 245262. CrossRef
Friedman, A., Hu, B.. The role of oxygen in tissue maintenance: Mathematical modeling and qualitative analysis. Math. Mod. Meth. Appl. Sci., 18 (2008), 133. CrossRef
A. Friedman, B. Hu, C-Y. Kao. Cell cycle control at the first restriction point and its effect on tissue growth. Submitted for publication.
Friedman, A., Reitich, F.. Quasi-static motion of a capillary drop, II: The three-dimensional case. J. Diff. Eqs., 186 (2002), 509557. CrossRef
Jiang, Y., Pjesivac-Grbovic, J., Cantrell, C., Freyer, J.P.. A multiscale model for avascular tumor growth. Biophysical Journal, 89 (2005), 38843894. CrossRef
Komaraova, N.. Stochastic modeling of loss- and gain-of-function mutation in cancer. Bull. Math. Biology, 17 (2007), 16471673.
Levine, H.A., Pamuk, S.L., Sleeman, B.D., Nilsen-Hamilton, M.. Mathematical modeling of capillary formation and development in tumor angiogenesis: penetration into the stroma. Bull. Math. Biology, 63 (2001), 801863. CrossRef
G. Lolas. Mathematical modelling of proteolysis and cancer cell invasion of tissue. In: Tutorials in Mathematical Biosciences III, Lecture Notes in Mathematics, 1872, 77–130. Springer, Berlin, 2006.
Mantzaris, N., Webb, S., Othmer, H.G.. Mathematical modeling of tumor-induced angiogenesis. J. Math. Biol., 49 (2004), 87111. CrossRef
Nowak, M.A., Sigmund, K.. Evolutionary dynamics of biological games. Science, 303 (2004), 793799. CrossRef
Pettet, G.J., Please, C.P., Tindall, M.J., McElwain, D.L.S.. The migration of cells in multicell tumor spheroids. Bull. Math. Biol., 63 (2001), 231257. CrossRef
Ribba, R., Colin, T., Schnell, S.. A multiscale model of cancer, and its use in analyzing irradiation therapies. Theoretical Biology and Medical Modeling, 3 (2006), No. 7, 119.
V.A. Solonnikov. On quasistationary approximation in the problem of a capillary drop. In: J. Escher & G. Simonett (Eds.), Progress in Nonlinear Differential Equations and Their Applications, 35, 643-671. Birkhäuser Verlag, Basel, 1999.
M.M. Vainberg, V.A. Trenogin. Theory of branching solutions of non-linear equations. Nordhoff International Publishing, Leyden, 1974.