Gradient matching accelerates mixed-effects inference for biochemical networks.

IF 5.4 Bioinformatics (Oxford, England) Pub Date : 2025-03-29 DOI:10.1093/bioinformatics/btaf154

Yulan B van Oppen, Andreas Milias-Argeitis

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Abstract

Motivation: Single-cell time series data often exhibit significant variability within an isogenic cell population. When modeling intracellular processes, it is therefore more appropriate to infer parameter distributions that reflect this variability, rather than fitting the population average to obtain a single point estimate. The Global Two-Stage (GTS) approach for nonlinear mixed-effects (NLME) models is a simple and modular method commonly used for this purpose. However, this method is computationally intensive due to its repeated use of nonconvex optimization and numerical integration of the underlying system.

Results: We propose the Gradient Matching GTS (GMGTS) method as an efficient alternative to GTS. Gradient matching offers an integration-free approach to parameter estimation that is particularly powerful for systems that are linear in the unknown parameters, such as biochemical networks modeled by mass action kinetics. By incorporating gradient matching into the GTS framework, we expand its capabilities through uncertainty propagation calculations and an iterative estimation scheme for partially observed systems. Comparisons between GMGTS and GTS across various inference setups show that our method significantly reduces computational demands, facilitating the application of complex NLME models in systems biology.

Availability and implementation: A Matlab implementation of GMGTS is provided at https://github.com/yulanvanoppen/GMGTS (DOI: http://doi.org/10.5281/zenodo.14884457).

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梯度匹配加速生化网络的混合效应推理。

动机：单细胞时间序列数据通常在等基因细胞群体中表现出显著的可变性。因此，在对细胞内过程建模时，更适合推断反映这种可变性的参数分布，而不是拟合总体平均值以获得单点估计。非线性混合效应（NLME）模型的全局两阶段（GTS）方法是一种简单的模块化方法，通常用于此目的。然而，该方法由于反复使用非凸优化和底层系统的数值积分，计算量很大。结果：我们提出了梯度匹配GTS （GMGTS）方法作为GTS的有效替代方法。梯度匹配提供了一种无积分的参数估计方法，对于未知参数为线性的系统，例如由质量作用动力学建模的生化网络，这种方法尤其强大。通过将梯度匹配纳入GTS框架，我们通过不确定性传播计算和部分观测系统的迭代估计方案扩展了其能力。GMGTS和GTS在各种推理设置上的比较表明，我们的方法显着减少了计算需求，促进了复杂NLME模型在系统生物学中的应用。可用性和实现：GMGTS的Matlab实现提供于https://github.com/yulanvanoppen/GMGTS (DOI: http://doi.org/10.5281/zenodo.14884457).Supplementary)信息：补充信息可在线获取，包含表S1-S4，图S1-S21，方法，数学推导和软件实现细节。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Bioinformatics (Oxford, England)

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