突触功能如何控制尖峰神经元网络中的临界转换:仓本模型还原的启示

L. Smirnov, V. O. Munyayev, M. Bolotov, Grigory V. Osipov, I. Belykh
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引用次数: 0

摘要

尖峰神经元网络中突触相互作用的动力学在形成突发性集体行为方面起着根本性的作用。本文研究了一个有限大小的二次整合-发射神经元网络,该网络通过一般突触函数相互连接,该函数考虑了突触动力学和时间延迟。通过渐近分析,我们将这种积分-发射网络转化为仓本-阪口模型,其参数通过突触函数特征明确表达。这种简化产生了突触激活率和时间延迟的分析条件,决定了突触耦合是吸引性还是排斥性的。我们的分析揭示了同步和部分同步发射的交替稳定区域,这取决于缓慢的突触激活和时间延迟。我们还证明,还原的微观模型能很好地预测原始积分点火网络及其对应的θ神经元中同步、弱稳定环状状态和非稳态的出现。我们的还原方法有望为严格分析具有突触适应性和可塑性的网络中的节奏发生打开一扇大门。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
How synaptic function controls critical transitions in spiking neuron networks: insight from a Kuramoto model reduction
The dynamics of synaptic interactions within spiking neuron networks play a fundamental role in shaping emergent collective behavior. This paper studies a finite-size network of quadratic integrate-and-fire neurons interconnected via a general synaptic function that accounts for synaptic dynamics and time delays. Through asymptotic analysis, we transform this integrate-and-fire network into the Kuramoto-Sakaguchi model, whose parameters are explicitly expressed via synaptic function characteristics. This reduction yields analytical conditions on synaptic activation rates and time delays determining whether the synaptic coupling is attractive or repulsive. Our analysis reveals alternating stability regions for synchronous and partially synchronous firing, dependent on slow synaptic activation and time delay. We also demonstrate that the reduced microscopic model predicts the emergence of synchronization, weakly stable cyclops states, and non-stationary regimes remarkably well in the original integrate-and-fire network and its theta neuron counterpart. Our reduction approach promises to open the door to rigorous analysis of rhythmogenesis in networks with synaptic adaptation and plasticity.
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