Biomedical Engineering Reference
In-Depth Information
25. J. Ewing, Neoplastic Diseases, Saunders, Philadelphia, PA, 1940.
26. J.P. Freyer, P.L. Scholar, and A.G. Saponara, Partial purication of a pro-
tein growth inhibitor from multicellular spheroids, Biochem. Biophys. Res.
Comm., 152 (1988), 463-368.
27. J. Freyer, and R. Sutherland, Selective dissociation and characterization of
cells from dierent regions of multicell spheroids during growth, Cancer Re-
search, 40 (1980), 3956-3965.
28. J. Freyer, and R. Sutherland, Regulation of growth saturation and develop-
ment of necrosis in EMT6/RO multicellular spheroids induced by the glucose
and oxygen supply, Cancer Research, 46 (1988), 3504-3512.
29. A. Friedman, A hierarchy of cancer models and their mathematical chal-
lenges, Discr. Contin. Dyn. Systems, 4 (2004), 147-159.
30. H.P. Greenspan, Models for the growth of a solid tumour by diusion, Stud.
Appl. Math., 52 (1972),317-340.
31. C. Guiot, P.P. Delsanto, A. Carpintari, N. Pugno, Y. Mansury, and T.S. Deis-
boeck, The dynamic evolution of the power exponent in a universal growth
model of tumors, J. Theor. Biol., 240 (2006), 459-463.
32. C. Guiot, P.G. Delsanto, P. Gabriele, and T.S. Deisboeck, Does tumor growth
follow a \Universal law"? J. Theor. Biol., 225 (2003), 147-151.
33. D. Hanahan, and R. Weinberg, The hallmarks of cancer, Cell, 100 (2000),
57-70.
34. G. Helmlinger, P.A. Netti, H.C. Lichtenbeld, R.J. Melder, and R.K. Jain,
Solid stress inhibits the growth of multicellular tumor spheroids, Nature
Biotech., 15 (1997), 778-783.
35. L. Hlatky, R.K. Sachs, and E.L. Alpen, Joint oxygen-glucose deprivation as
the cause of necrosis in a tumor analog, J. Cell. Physiol., 134 (1988), 167-168.
36. T.L. Jackson, Vascular tumor growth and treatment: consequences of poly-
clonality, competition and dynamic vascular support, J. Math. Biol.,
44
(2002), 201-226.
37. T.L. Jackson, and H.M. Byrne, A mathematical model of tumour encapsu-
lation. J. Math. Biosc., 180 (2002), 307-328.
38. Y. Jiang, J.P. Grbovic, C. Cantrell, and J.P. Freyer, A Multiscale Model for
Avascular Tumor Growth, Biophys. J., 89 (2005), 3884-3894.
39. A.R. Kansal, S. Torquato, G.R. Harsh IV, E.A. Chioca, T.S. Deisboeck,
Simulated brain tumor growth dynamics using a three-dimensional cellular
automaton, J. theor. Biol., 203 (2000), 367-382.
40. A.R. Kansal, S. Torquato, E.A. Chiocca, and T.S. Deisboeck, Simulated
Brain Tumor Growth Dynamics Using a Three-Dimensional Cellular Au-
tomaton, J. theor. Biol., 207 (2000), 431-382.
41. K. Kiberstis, and et al., Frontiers in cancer research, Science,
278(1977),
1035.
42. J.E. Klaunig, and L.M. Kamendulus, The role of oxidative stress in carcino-
genesis, Ann. Rev. Pharmacol. Toxxixol., 44 (2004), 239-267.
43. M. Lachowicz, Describing competitive systems at the level of interacting in-
dividuals, Proc. of the Eight Nat. Confer. Appl. Math. Biol. Medicine, Lajs,
pp. 95-100, 2002.
Search WWH ::
Custom Search