Tumor-induced neoneurogenesis and perineural tumor growth: a mathematical approach

Primary tumors infrequently lead to demise of cancer patients; instead, mortality and a significant degree of morbidity result from the growth of secondary tumors in distant organs (metastasis). It is well-known that malignant tumors induce the formation of a lymphatic and a blood vascular network around themselves. A similar but far less studied process occurs in relation to the nervous system and is referred to as \emph{neoneurogenesis}; in fact, recent studies have demonstrated that tumors initiate their own innervation. However, the relationship between tumor progression and the nervous system is still poorly understood. This process is most likely regulated by a multitude of factors in the tumor-nerve microenvironment and it is therefore important to study the interactions between the nervous system and tumor cells through mathematical/computational modelling: this may reveal the most significant factors of the plethora of interacting elements regulating neoneurogenesis. The present work is a first attempt to model the neurobiological aspect of cancer development through a (simple) system of differential equations. The model confirms the experimental observations that a tumor is able to promote nerve formation/elongation around itself, and that high levels of nerve growth factor (NGF) and axon guidance molecules (AGMs) are recorded in the presence of a tumor. Our results also reflect the observation that high stress levels (represented by higher norepinephrine release by sympathetic nerves) contribute to tumor development and spread, indicating a mutually beneficial relationship between tumor cells and neurons. The model predictions suggest novel therapeutic strategies, aimed at blocking the stress effects on tumor growth and dissemination.