Paper detail

Assessment of intra-tumor heterogeneity in a two-dimensional vascular tumor growth model

We present a two-dimensional continuum model of tumor growth, which treats the tissue as a composition of six distinct fluid phases; their dynamics are governed by the equations of mass and momentum conservation. Our model divides the cancer cells phase into two sub-phases depending on their maturity state. The same approach is also applied for the vasculature phase, which is divided into young sprouts (products of angiogenesis), and fully formed-mature vessels. The remaining two phases correspond to healthy cells and extracellular material (ECM). Furthermore, the model foresees the existence of nutrient chemical species, which are transferred within the tissue through diffusion or supplied by the vasculature (blood vessels). The model is numerically solved with the Finite Elements Method and computations are performed with the commercial software Comsol Multiphysics. The numerical simulations predict that mature cancer cells are well separated from young cancer cells, which form a protective shield for the growing tumor. We study the effect of different mitosis and death rates for mature and young cancer cells on the tumor growth rate, and predict accelerated rates when the mitosis rate of young cancer cells is higher compared to mature cancer cells.