Mathematical Models for Self-Adaptive Response to Cancer Dynamics

Abstract

We consider two minimal mathematical models for cancer dynamics and self-adaptation. We aim to capture the interplay between the rapid progression of cancer growth and the possibility to leverage and enhance self-adaptive defense mechanisms of an organism, e.g., motivated by immunotherapy. Yet, our two models are more abstract and generic encapsulating the essence of competition between rapid cancer growth and the speed of adaptation. First, we propose a four-dimensional ordinary differential equation model on a macroscopic level. The model has three main parameter regimes and its most important features can be studied analytically. At small external stimulation of adaptation, cancer progresses to a deadly level. At intermediate external input, a bifurcation is observed leaving behind only a locally stable cancer-free steady state. Unfortunately, in a large parameter regime after the bifurcation, a transient cancer density spike is observed. Only for a combination of external input and speeding up adaptation, cancer does not reach critical levels. To study the adaptation speed-up in the initial dynamics phase, we switch to a microscopic probabilistic model, which we study numerically. The microscopic model undergoes a sharp transition under variation of the self-adaptation probability. It is shown that a combination of temporal memory and rare stochastic positive adaptation events is crucial to move the sharp transition point to a desired regime. Despite their extreme simplicity, the two models already provide remarkably deep insight into the challenges one has to overcome to leverage/enhance the self-adaptation of an organism in fighting cancer.

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