Modelling brain metabolism with interacting nonautonomous phase oscillators.

IF 3

Frontiers in network physiology Pub Date : 2026-02-20 eCollection Date: 2026-01-01 DOI:10.3389/fnetp.2026.1720336

Samuel J K Barnes, Anaí Echeverría, Joshua Hawley, Yevhen F Suprunenko, Aneta Stefanovska

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Abstract

Traditional brain models have focused primarily on electrical signalling, offering valuable insights but often overlooking the crucial role of metabolism within the neurovascular unit. Existing metabolic models tend to be highly detailed and mass-based, relying on strict conservation laws that limit their applicability to the brain's thermodynamically open environment. In this study, we present a novel, phenomenological model of neuronal energy metabolism using a network of coupled Kuramoto oscillators. This nonautonomous phase dynamics framework captures complex, time-dependent interactions and allows for multiple synchronization states among metabolic processes. Our model captures key features consistent with healthy neurovascular dynamics, despite not being directly fitted to empirical data from resting-state brains and reveals how disruptions in metabolic synchrony may contribute to dementia-related pathology. By emphasizing the importance of metabolic coordination in the neurovascular unit, this work provides a versatile methodological foundation for future brain modelling efforts.

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用相互作用的非自治相位振荡器模拟脑代谢。

传统的脑模型主要关注电信号，提供了有价值的见解，但往往忽视了神经血管单位内代谢的关键作用。现有的代谢模型往往是非常详细和基于质量的，依赖于严格的守恒定律，限制了它们对大脑热力学开放环境的适用性。在这项研究中，我们提出了一个新的，现象学模型的神经元能量代谢使用一个网络的耦合Kuramoto振荡器。这种非自治相动力学框架捕获复杂的、依赖于时间的相互作用，并允许代谢过程之间的多个同步状态。我们的模型捕获了与健康神经血管动力学一致的关键特征，尽管没有直接适用于静息状态大脑的经验数据，并揭示了代谢同步的中断如何导致痴呆相关病理。通过强调代谢协调在神经血管单元中的重要性，这项工作为未来的大脑建模工作提供了一个通用的方法学基础。

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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来源期刊

Frontiers in network physiology

CiteScore

2.70

自引率

0.00%

发文量