Abstract
Tumor progression modeling offers the potential to predict tumor-spreading behavior to improve prognostic accuracy and guide therapy development. Common simulation methods include continuous reaction-diffusion (RD) approaches that capture mean spatio-temporal tumor spreading behavior and discrete agent-based (AB) approaches which capture individual cell events such as proliferation or migration. The brain cancer glioblastoma (GBM) is especially appropriate for such proliferation-migration modeling approaches because tumor cells seldom metastasize outside of the central nervous system and cells are both highly proliferative and migratory. In glioblastoma research, current RD estimates of proliferation and migration parameters are derived from computed tomography or magnetic resonance images. However, these estimates of glioblastoma cell migration rates, modeled as a diffusion coefficient, are approximately 1-2 orders of magnitude larger than single-cell measurements in animal models of this disease. To identify possible sources for this discrepancy, we evaluated the fundamental RD simulation assumptions that cells are point-like structures that can overlap. To give cells physical size (~10 μm), we used a Brownian dynamics approach that simulates individual single-cell diffusive migration, growth, and proliferation activity via a gridless, off-lattice, AB method where cells can be prohibited from overlapping each other. We found that for realistic single-cell parameter growth and migration rates, a non-overlapping model gives rise to a jammed configuration in the center of the tumor and a biased outward diffusion of cells in the tumor periphery, creating a quasi-ballistic advancing tumor front. The simulations demonstrate that a fast-progressing tumor can result from minimally diffusive cells, but at a rate that is still dependent on single-cell diffusive migration rates. Thus, modeling with the assumption of physically-grounded volume conservation can account for the apparent discrepancy between estimated and measured diffusion of GBM cells and provide a new theoretical framework that naturally links single-cell growth and migration dynamics to tumor-level progression.
Highlights
Tumor modeling is rapidly developing as an approach to understand and predict cancer progression [1,2,3,4,5]
Comparison of glioma migration parameter estimates obtained from estimates of bulk tumor growth to single cell migration parameters obtained by fluorescence microscopy shows a disconnect between single-cell behavior and RD model-estimated diffusivity
Using a 1D Brownian dynamics (BD) modeling approach that accounts for single-cell stochastic movements, we found that the inclusion of volume has a significant impact on overall tumor spreading dynamics
Summary
Tumor modeling is rapidly developing as an approach to understand and predict cancer progression [1,2,3,4,5]. Many computational cancer models of progression have been established, each with variable predictability and applications. The simplest model describing tumor progression is an exponential growth model. While this type of model is helpful for predicting proliferative growth of benign tumors [7], it lacks spatial information and does not capture the invasive behavior of malignant tumors. Other non-spatial models have been explored to describe tumor growth, such as the Gompertz model or a power law function [8], but have the same limitations of only describing changes in cell number and not tumor spread
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