A Minimal Model of Tumor Growth Inhibition

The preclinical development of antitumor drugs greatly benefits from the availability of models capable of predicting tumor growth as a function of the drug administration schedule. For being of practical use, such models should be simple enough to be identifiable from standard experiments conducted on animals. In the present paper, a stochastic model is derived from a set of minimal assumptions formulated at cellular level. Tumor cells are divided in two groups: proliferating and nonproliferating. The probability that a proliferating cell generates a new cell is a function of the tumor weight. The probability that a proliferating cell becomes nonproliferating is a function of the plasma drug concentration. The time-to-death of a nonproliferating cell is a random variable whose distribution reflects the nondeterministic delay between drug action and cell death. The evolution of the expected value of tumor weight obeys two differential equations (an ordinary and a partial differential one), whereas the variance is negligible. Therefore, the tumor growth dynamics can be well approximated by the deterministic evolution of its expected value. The tumor growth inhibition model, which is a lumped parameter model that in the last few years has been successfully applied to several antitumor drugs, is shown to be a special case of the minimal model presented here.

[1]  C. Harley,et al.  Cancer treatment by telomerase inhibitors: predictions by a kinetic model. , 2003, Mathematical biosciences.

[2]  M Rocchetti,et al.  A mathematical model to study the effects of drugs administration on tumor growth dynamics. , 2006, Mathematical biosciences.

[3]  R. Wasserman,et al.  A patient-specific in vivo tumor model. , 1996, Mathematical biosciences.

[4]  H M Byrne,et al.  A mathematical model to study the effects of drug resistance and vasculature on the response of solid tumors to chemotherapy. , 2000, Mathematical biosciences.

[5]  X. Zheng,et al.  A cellular automaton model of cancerous growth. , 1993, Journal of theoretical biology.

[6]  P Forouhi,et al.  Identification of long-term survivors in primary breast cancer by dynamic modelling of tumour response , 2000, British Journal of Cancer.

[7]  Z. Agur,et al.  A theoretical analysis of interval drug dosing for cell-cycle-phase-specific drugs. , 1992, Mathematical biosciences.

[8]  Alessandro Torricelli,et al.  Modelling the balance between quiescence and cell death in normal and tumour cell populations. , 2006, Mathematical biosciences.

[9]  D. Liberati,et al.  A non-parametric method for the analysis of experimental tumour growth data , 2006, Medical & Biological Engineering & Computing.

[10]  Janet Dyson,et al.  Asynchronous exponential growth in an age structured population of proliferating and quiescent cells. , 2002, Mathematical biosciences.

[11]  Paolo Magni,et al.  Predictive Pharmacokinetic-Pharmacodynamic Modeling of Tumor Growth Kinetics in Xenograft Models after Administration of Anticancer Agents , 2004, Cancer Research.

[12]  M. Volm,et al.  Human tumor xenografts as model for drug testing , 1988, Cancer and Metastasis Reviews.

[13]  John G. Proakis,et al.  Probability, random variables and stochastic processes , 1985, IEEE Trans. Acoust. Speech Signal Process..

[14]  E K Rowinsky,et al.  Enhanced antitumour activity of 6-hydroxymethylacylfulvene in combination with topotecan or paclitaxel in the MV522 lung carcinoma xenograft model. , 2000, European journal of cancer.

[15]  L Aarons,et al.  Role of modelling and simulation in Phase I drug development. , 2001, European journal of pharmaceutical sciences : official journal of the European Federation for Pharmaceutical Sciences.

[16]  John A. Adam,et al.  A mathematical model of cycle-specific chemotherapy , 1995 .

[17]  N. Komarova Mathematical modeling of tumorigenesis: mission possible , 2005, Current opinion in oncology.

[18]  Bruno O. Shubert,et al.  Random variables and stochastic processes , 1979 .

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

[20]  Zeljko Bajzer,et al.  Combining Gompertzian growth and cell population dynamics. , 2003, Mathematical biosciences.