A hybrid three-scale model of tumor growth
Authored by H L Rocha, R C Almeida, E A B F Lima, A C M Resende, J T Oden, T E Yankeelov
Date Published: 2018
DOI: 10.1142/s0218202518500021
Sponsors:
Brazilian National Council for Scientific and Technological Development (CNPq)
United States National Institutes of Health (NIH)
United States National Science Foundation (NSF)
Platforms:
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Abstract
Cancer results from a complex interplay of different biological,
chemical, and physical phenomena that span a wide range of time and
length scales. Computational modeling may help to unfold the role of
multiple evolving factors that exist and interact in the tumor
microenvironment. Understanding these complex multiscale interactions is
a crucial step toward predicting cancer growth and in developing
effective therapies. We integrate different modeling approaches in a
multiscale, avascular, hybrid tumor growth model encompassing tissue,
cell, and sub-cell scales. At the tissue level, we consider the
dispersion of nutrients and growth factors in the tumor
microenvironment, which are modeled through reaction-diffusion
equations. At the cell level, we use an agent-based model (ABM) to
describe normal and tumor cell dynamics, with normal cells kept in
homeostasis and cancer cells differentiated into quiescent,
proliferative,migratory, apoptotic, hypoxic, and necrotic states. Cell
movement is driven by the balance of a variety of forces according to
Newton's second law, including those related to growth-induced stresses.
Phenotypic transitions are defined by specific rule of behaviors that
depend on microenvironment stimuli. We integrate in each cell/agent a
branch of the epidermal growth factor receptor (EGFR) pathway. This
pathway is modeled by a system of coupled nonlinear differential
equations involving the mass laws of 20 molecules. The rates of change
in the concentration of some key molecules trigger proliferation or
migration advantage response. The bridge between cell and tissue scales
is built through the reaction and source terms of the partial
differential equations. Our hybrid model is built in a modular way,
enabling the investigation of the role of different mechanisms at
multiple scales on tumor progression. This strategy allows representing
both the collective behavior due to cell assembly as well as microscopic
intracellular phenomena described by signal transduction pathways. Here,
we investigate the impact of some mechanisms associated with sustained
proliferation on cancer progression. Specifically, we focus on the
intracellular proliferation/migration-advantage-response driven by the
EGFR pathway and on proliferation inhibition due to accumulation of
growth-induced stresses. Simulations demonstrate that the model can
adequately describe some complex mechanisms of tumor dynamics, including
growth arrest in avascular tumors. Both the sub-cell model and
growth-induced stresses give rise to heterogeneity in the tumor
expansion and a rich variety of tumor behaviors.
Tags
cancer
patterns
progression
Tissue
Cell-populations
Spheroids
Hallmarks
Solid stress
Signaling pathway
Hybrid multiscale model
Cell-agent-based model
Clinical oncology
Kinase cascade