Metastability in networks of nonlinear stochastic integrate-and-fire neurons.

ArXiv Pub Date : 2024-12-12
Siddharth Paliwal, Gabriel Koch Ocker, Braden A W Brinkman
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Abstract

Neurons in the brain continuously process the barrage of sensory inputs they receive from the environment. A wide array of experimental work has shown that the collective activity of neural populations encodes and processes this constant bombardment of information. How these collective patterns of activity depend on single-neuron properties is often unclear. Single-neuron recordings have shown that individual neurons' responses to inputs are nonlinear, which prevents a straightforward extrapolation from single neuron features to emergent collective states. Here, we use a field-theoretic formulation of a stochastic leaky integrate-and-fire model to study the impact of single-neuron nonlinearities on macroscopic network activity. In this model, a neuron integrates spiking output from other neurons in its membrane voltage and emits spikes stochastically with an intensity depending on the membrane voltage, after which the voltage resets. We show that the interplay between nonlinear spike intensity functions and membrane potential resets can i) give rise to metastable active firing rate states in recurrent networks, and ii) can enhance or suppress mean firing rates and membrane potentials in the same or paradoxically opposite directions.

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非线性随机整合-发射神经元网络中的转移性
大脑中的神经元不断处理从环境中接收到的大量感官输入信息。大量实验工作表明,神经元群的集体活动编码并处理着这种持续不断的信息轰炸。这些集体活动模式如何依赖于单个神经元的特性往往还不清楚。单神经元记录显示,单个神经元对输入的反应是非线性的,这就阻碍了从单神经元特征直接推断出出现的集体状态。在这项工作中,我们使用随机泄漏整合-发射模型的场论表述来研究非线性强度函数对宏观网络活动的影响。我们的研究表明,非线性尖峰发射和膜电位复位之间的相互作用会 i) 引起活跃点燃率状态之间的可迁移转变,以及 ii) 以相反的方向增强或抑制平均点燃率和膜电位。
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