Inference for the stochastic FitzHugh-Nagumo model from real action potential data via approximate Bayesian computation

Adeline Samson, Massimiliano Tamborrino, Irene Tubikanec
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Abstract

The stochastic FitzHugh-Nagumo (FHN) model considered here is a two-dimensional nonlinear stochastic differential equation with additive degenerate noise, whose first component, the only one observed, describes the membrane voltage evolution of a single neuron. Due to its low dimensionality, its analytical and numerical tractability, and its neuronal interpretation, it has been used as a case study to test the performance of different statistical methods in estimating the underlying model parameters. Existing methods, however, often require complete observations, non-degeneracy of the noise or a complex architecture (e.g., to estimate the transition density of the process, "recovering" the unobserved second component), and they may not (satisfactorily) estimate all model parameters simultaneously. Moreover, these studies lack real data applications for the stochastic FHN model. Here, we tackle all challenges (non-globally Lipschitz drift, non-explicit solution, lack of available transition density, degeneracy of the noise, and partial observations) via an intuitive and easy-to-implement sequential Monte Carlo approximate Bayesian computation algorithm. The proposed method relies on a recent computationally efficient and structure-preserving numerical splitting scheme for synthetic data generation, and on summary statistics exploiting the structural properties of the process. We succeed in estimating all model parameters from simulated data and, more remarkably, real action potential data of rats. The presented novel real-data fit may broaden the scope and credibility of this classic and widely used neuronal model.
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通过近似贝叶斯计算从真实动作电位数据推断随机菲茨休-纳古莫模型
本文所考虑的随机菲茨休-纳古莫(FHN)模型是一个二维非线性随机微分方程,带有附加生成噪声,其第一个分量(唯一观测到的分量)描述了单个神经元的膜电压演变。由于其维度低、分析和数值上的可操作性以及对神经元的解释,该方程被用作案例研究,以测试不同统计方法在估计基础模型参数方面的性能。然而,现有方法往往需要完整的观测数据、噪声的非退化性或复杂的结构(例如,估计过程的过渡密度,"恢复 "未观测到的第二分量),而且它们可能无法(令人满意地)同时估计所有模型参数。此外,这些研究缺乏随机 FHN 模型的实际数据应用。在此,我们通过一种直观且易于实现的顺序蒙特卡洛近似贝叶斯计算算法,解决了所有难题(非全局 Lipschitz 漂移、非显式解、缺乏可用的过渡密度、噪声退化和部分观测)。所提出的方法依赖于新近提出的计算高效、结构保留的数值分裂方案来生成合成数据,并依赖于利用过程结构特性的汇总统计。我们成功地从模拟数据和大鼠的真实动作电位数据中估算出了所有模型参数。所提出的新颖的真实数据拟合方法可能会扩大这一经典和广泛应用的神经元模型的范围和可信度。
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