神经元网络中巡回复杂性的生物物理调节和稳健性。

Frontiers in network physiology Pub Date : 2024-03-07 eCollection Date: 2024-01-01 DOI:10.3389/fnetp.2024.1302499
Siva Venkadesh, Asmir Shaikh, Heman Shakeri, Ernest Barreto, John Darrell Van Horn
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引用次数: 0

摘要

神经元网络中爆发活动的瞬时同步是体内观察到的网络动力学的一个显著特点,它以神经元之间可移动的巡回相位关系模式出现。然而,神经元网络中这种动态复杂性的形成机制还不甚明了。大脑皮层区域的局部回路由具有不同内在振荡特征的神经元群组成。在这项研究中,我们用数值方法证明,当抑制性神经元群的固有快速尖峰动态受到来自兴奋性神经元群的较慢输入的适当调节时,抑制性神经元群中就会出现瞬时同步现象,这种现象也被称为可迁移性。我们的研究使用了一个由兴奋性锥体神经元和抑制性快速尖峰神经元组成的介观尺度网络的紧凑模型,证明了锥体神经元群振荡频率与抑制性神经元群中出现的可迁移性特征之间的关系。此外,我们还介绍了一种表征可代谢网络中集体转换的方法。最后,我们讨论了这项研究在从机理上理解皮层网络动力学方面的潜在应用。
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Biophysical modulation and robustness of itinerant complexity in neuronal networks.

Transient synchronization of bursting activity in neuronal networks, which occurs in patterns of metastable itinerant phase relationships between neurons, is a notable feature of network dynamics observed in vivo. However, the mechanisms that contribute to this dynamical complexity in neuronal circuits are not well understood. Local circuits in cortical regions consist of populations of neurons with diverse intrinsic oscillatory features. In this study, we numerically show that the phenomenon of transient synchronization, also referred to as metastability, can emerge in an inhibitory neuronal population when the neurons' intrinsic fast-spiking dynamics are appropriately modulated by slower inputs from an excitatory neuronal population. Using a compact model of a mesoscopic-scale network consisting of excitatory pyramidal and inhibitory fast-spiking neurons, our work demonstrates a relationship between the frequency of pyramidal population oscillations and the features of emergent metastability in the inhibitory population. In addition, we introduce a method to characterize collective transitions in metastable networks. Finally, we discuss potential applications of this study in mechanistically understanding cortical network dynamics.

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