用生物信息神经网络预测和预报随机代理模型数据。

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
John T Nardini
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引用次数: 0

摘要

集体迁移是许多生物过程的重要组成部分,包括伤口愈合、肿瘤发生和胚胎发育。基于空间代理的模型(ABM)经常被用来模拟集体迁移,但由于其随机性和计算密集性,要彻底预测这些模型在整个参数空间的行为具有挑战性。建模者通常将 ABM 规则粗粒化为均值场微分方程(DE)模型。虽然这些均值场微分方程模型模拟速度快,但在参数空间的某些区域,它们的 ABM 预测能力较差(甚至是有问题的)。在这项工作中,我们介绍了如何通过训练生物信息神经网络(BINN)来学习可解释的 BINN 引导的 DE 模型,从而能够准确预测 ABM 行为。特别是,我们展示了 BINN 引导的部分 DE(PDE)模拟可以(1)预测模型训练期间未见的未来空间 ABM 数据,以及(2)预测之前未探索过的参数值下的 ABM 数据。后一项任务是通过将 BINN 引导的 PDE 仿真与多变量插值相结合来实现的。我们使用三个模仿细胞生物学实验的集体迁移 ABM 案例来演示我们的方法,并发现当均值场 PDE 存在问题或需要两个分区时,BINN 引导的 PDE 可以准确预测单分区 PDE 的 ABM 数据。这项工作表明,BINN 引导的 PDE 可以让建模者有效地探索参数空间,这可能会使 ABM 的数据驱动任务成为可能,例如从实验数据中估计参数。我们研究的所有代码和数据可在 https://github.com/johnnardini/Forecasting_predicting_ABMs 上获取。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Forecasting and Predicting Stochastic Agent-Based Model Data with Biologically-Informed Neural Networks.

Collective migration is an important component of many biological processes, including wound healing, tumorigenesis, and embryo development. Spatial agent-based models (ABMs) are often used to model collective migration, but it is challenging to thoroughly predict these models' behavior throughout parameter space due to their random and computationally intensive nature. Modelers often coarse-grain ABM rules into mean-field differential equation (DE) models. While these DE models are fast to simulate, they suffer from poor (or even ill-posed) ABM predictions in some regions of parameter space. In this work, we describe how biologically-informed neural networks (BINNs) can be trained to learn interpretable BINN-guided DE models capable of accurately predicting ABM behavior. In particular, we show that BINN-guided partial DE (PDE) simulations can (1) forecast future spatial ABM data not seen during model training, and (2) predict ABM data at previously-unexplored parameter values. This latter task is achieved by combining BINN-guided PDE simulations with multivariate interpolation. We demonstrate our approach using three case study ABMs of collective migration that imitate cell biology experiments and find that BINN-guided PDEs accurately forecast and predict ABM data with a one-compartment PDE when the mean-field PDE is ill-posed or requires two compartments. This work suggests that BINN-guided PDEs allow modelers to efficiently explore parameter space, which may enable data-driven tasks for ABMs, such as estimating parameters from experimental data. All code and data from our study is available at https://github.com/johnnardini/Forecasting_predicting_ABMs .

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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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