The migration of cells in multicell tumor spheroids

A mathematical model is proposed to explain the observed internalization of microspheres and 3H-thymidine labelled cells in steady-state multicellular spheroids. The model uses the conventional ideas of nutrient diffusion and consumption by the cells. In addition, a very simple model of the progress of the cells through the cell cycle is considered. Cells are divided into two classes, those proliferating (being in G1, S, G2 or M phases) and those that are quiescent (being in G0). Furthermore, the two categories are presumed to have different chemotactic responses to the nutrient gradient. The model accounts for the spatial and temporal variations in the cell categories together with mitosis, conversion between categories and cell death. Numerical solutions demonstrate that the model predicts the behavior similar to existing models but has some novel effects. It allows for spheroids to approach a steady-state size in a non-monotonic manner, it predicts self-sorting of the cell classes to produce a thin layer of rapidly proliferating cells near the outer surface and significant numbers of cells within the spheroid stalled in a proliferating state. The model predicts that overall tumor growth is not only determined by proliferation rates but also by the ability of cells to convert readily between the classes. Moreover, the steady-state structure of the spheroid indicates that if the outer layers are removed then the tumor grows quickly by recruiting cells stalled in a proliferating state. Questions are raised about the chemotactic response of cells in differing phases and to the dependency of cell cycle rates to nutrient levels.

[1]  H. Byrne,et al.  Modelling the internalization of labelled cells in tumour spheroids , 1999, Bulletin of mathematical biology.

[2]  R F Kallman,et al.  Migration and internalization of cells and polystyrene microsphere in tumor cell spheroids. , 1982, Experimental cell research.

[3]  John R. King,et al.  Mathematical Modelling of the Effects of Mitotic Inhibitors on Avascular Tumour Growth , 1999 .

[4]  R. Knüchel,et al.  Importance of tyrosine phosphatases in the effects of cell‐cell contact and microenvironments on EGF‐stimulated tyrosine phosphorylation , 1992, Journal of cellular physiology.

[5]  B. Adelmann-Grill,et al.  Differentiation stage and cell cycle position determine the chemotactic response of fibroblasts. , 1996, Folia histochemica et cytobiologica.

[6]  W. Mueller‐Klieser Three-dimensional cell cultures: from molecular mechanisms to clinical applications. , 1997, American journal of physiology. Cell physiology.

[7]  M. Chaplain Avascular growth, angiogenesis and vascular growth in solid tumours: The mathematical modelling of the stages of tumour development , 1996 .

[8]  Helen M. Byrne,et al.  The role of growth factors in avascular tumour growth , 1997 .

[9]  C. Please,et al.  Tumour dynamics and necrosis: surface tension and stability. , 2001, IMA journal of mathematics applied in medicine and biology.

[10]  H M Byrne,et al.  Growth of nonnecrotic tumors in the presence and absence of inhibitors. , 1995, Mathematical biosciences.

[11]  J. King,et al.  Mathematical modelling of avascular-tumour growth. II: Modelling growth saturation. , 1999, IMA journal of mathematics applied in medicine and biology.

[12]  Stanley Osher,et al.  Large-scale computations in fluid mechanics , 1985 .

[13]  J. P. Freyer,et al.  Influence of glucose and oxygen supply conditions on the oxygenation of multicellular spheroids. , 1986, British Journal of Cancer.

[14]  Eleuterio F. Toro,et al.  A weighted average flux method for hyperbolic conservation laws , 1989, Proceedings of the Royal Society of London. A. Mathematical and Physical Sciences.

[15]  H. Greenspan On the growth and stability of cell cultures and solid tumors. , 1976, Journal of theoretical biology.

[16]  Graeme J. Pettet,et al.  AVASCULAR TUMOUR DYNAMICS AND NECROSIS , 1999 .

[17]  R F Kallman,et al.  Effect of cytochalasin B, nocodazole and irradiation on migration and internalization of cells and microspheres in tumor cell spheroids. , 1986, Experimental cell research.

[18]  G J Pettet,et al.  Cell migration in multicell spheroids: swimming against the tide. , 1993, Bulletin of mathematical biology.

[19]  Burton Ac,et al.  Rate of growth of solid tumours as a problem of diffusion. , 1966, Growth.

[20]  R. Sutherland,et al.  A move for the better. , 1994, Environmental health perspectives.

[21]  M. Tubiana The kinetics of tumour cell proliferation and radiotherapy. , 1971, The British journal of radiology.

[22]  N F Britton,et al.  On the concentration profile of a growth inhibitory factor in multicell spheroids. , 1993, Mathematical biosciences.

[23]  H. Greenspan Models for the Growth of a Solid Tumor by Diffusion , 1972 .

[24]  Graeme J. Pettet,et al.  A new approach to modelling the formation of necrotic regions in tumours , 1998 .

[25]  C. McCulloch,et al.  Quantification of chemotactic response of quiescent and proliferating fibroblasts in Boyden chambers by computer-assisted image analysis. , 1991, Journal of Histochemistry and Cytochemistry.

[26]  R. Knuechel,et al.  Multicellular spheroids: a three‐dimensional in vitro culture system to study tumour biology , 1998, International journal of experimental pathology.

[27]  R. Sutherland Cell and environment interactions in tumor microregions: the multicell spheroid model. , 1988, Science.