A Method to Coarse-Grain MultiAgent Stochastic Systems with Regions of Multistability

D. Stepanova, H. Byrne, P. Maini, T. Alarc'on
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Abstract

Hybrid multiscale modelling has emerged as a useful framework for modelling complex biological phenomena. However, when accounting for stochasticity in the internal dynamics of agents, these models frequently become computationally expensive. Traditional techniques to reduce the computational intensity of such models can lead to a reduction in the richness of the dynamics observed, compared to the original system. Here we use large deviation theory to decrease the computational cost of a spatially-extended multi-agent stochastic system with a region of multi-stability by coarse-graining it to a continuous time Markov chain on the state space of stable steady states of the original system. Our technique preserves the original description of the stable steady states of the system and accounts for noise-induced transitions between them. We apply the method to a bistable system modelling phenotype specification of cells driven by a lateral inhibition mechanism. For this system, we demonstrate how the method may be used to explore different pattern configurations and unveil robust patterns emerging on longer timescales. We then compare the full stochastic, coarse-grained and mean-field descriptions via pattern quantification metrics and in terms of the numerical cost of each method. Our results show that the coarse-grained system exhibits the lowest computational cost while preserving the rich dynamics of the stochastic system. The method has the potential to reduce the computational complexity of hybrid multiscale models, making them more tractable for analysis, simulation and hypothesis testing.
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具有多稳定域的粗粒多智能体随机系统的一种方法
混合多尺度模型已成为模拟复杂生物现象的有用框架。然而,当考虑到代理内部动态的随机性时,这些模型往往会变得计算昂贵。与原始系统相比,降低此类模型计算强度的传统技术可能导致所观察到的动力学丰富性的减少。本文利用大偏差理论,将具有多稳定区域的空间扩展多智能体随机系统粗粒化为原系统稳定稳态状态空间上的连续时间马尔可夫链,从而降低了系统的计算成本。我们的技术保留了系统稳定稳定状态的原始描述,并解释了它们之间由噪声引起的转换。我们将该方法应用于由侧抑制机制驱动的细胞的双稳态系统建模表型规范。对于这个系统,我们演示了如何使用该方法来探索不同的模式配置,并揭示在更长的时间尺度上出现的鲁棒模式。然后,我们通过模式量化度量和每种方法的数值成本来比较全随机、粗粒度和平均场描述。我们的研究结果表明,粗粒度系统在保持随机系统丰富动态特性的同时具有最低的计算成本。该方法有可能降低混合多尺度模型的计算复杂度,使其更易于分析、模拟和假设检验。
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