Bayesian calibration of a stochastic, multiscale agent-based model for predicting in vitro tumor growth.

Ernesto A B F Lima,Caleb M Phillips,Danial Faghihi,Russell Philley,Thomas E Yankeelov,Jianchen Yang,John Virostko,Stacey Finley

doi:10.1371/journal.pcbi.1008845

Abstract

Hybrid multiscale agent-based models (ABMs) are unique in their ability to simulate individual cell interactions and microenvironmental dynamics. Unfortunately, the high computational cost of modeling individual cells, the inherent stochasticity of cell dynamics, and numerous model parameters are fundamental limitations of applying such models to predict tumor dynamics. To overcome these challenges, we have developed a coarse-grained two-scale ABM (cgABM) with a reduced parameter space that allows for an accurate and efficient calibration using a set of time-resolved microscopy measurements of cancer cells grown with different initial conditions. The multiscale model consists of a reaction-diffusion type model capturing the spatio-temporal evolution of glucose and growth factors in the tumor microenvironment (at tissue scale), coupled with a lattice-free ABM to simulate individual cell dynamics (at cellular scale). The experimental data consists of BT474 human breast carcinoma cells initialized with different glucose concentrations and tumor cell confluences. The confluence of live and dead cells was measured every three hours over four days. Given this model, we perform a time-dependent global sensitivity analysis to identify the relative importance of the model parameters. The subsequent cgABM is calibrated within a Bayesian framework to the experimental data to estimate model parameters, which are then used to predict the temporal evolution of the living and dead cell populations. To this end, a moment-based Bayesian inference is proposed to account for the stochasticity of the cgABM while quantifying uncertainties due to limited temporal observational data. The cgABM reduces the computational time of ABM simulations by 93% to 97% while staying within a 3% difference in prediction compared to ABM. Additionally, the cgABM can reliably predict the temporal evolution of breast cancer cells observed by the microscopy data with an average error and standard deviation for live and dead cells being 7.61±2.01 and 5.78±1.13, respectively.

Highlights

Tumor growth and treatment response are governed by the complex interplay of numerous phenomena occurring at various spatial and temporal scales
Rocha et al [3] developed a hybrid three scale model consisting of a reactiondiffusion type continuum model of the tumor microenvironment, a lattice-free agent-based models (ABMs) of cell dynamics, and an inter- and intracellular signaling pathways model represented by a system of coupled nonlinear differential equations
We have developed a new hybrid, two-scale, stochastic agent-based model of tumor cell dynamics and investigated the model’s ability to simulate and predict in vitro experimental observations of live and dead cell numbers over time, given the initial conditions

Summary

Introduction

Tumor growth and treatment response are governed by the complex interplay of numerous phenomena occurring at various spatial and temporal scales. Compared to models governed by differential equations (see, e.g., [20,21,22,23,24]), the primary benefit of combining multiple models in ABMs is the ability to simulate coupled, multiscale processes and mechanisms responsible for tumor growth and treatment response [25]. This provides an opportunity to computationally test a range of hypotheses on the underlying biological phenomena driving cancer development. For a comprehensive review of discrete and hybrid tumor growth models and their applications, the interested reader is referred to [33], and the references cited therein

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Results

Discussion

Conclusion