将具有非线性电压依赖性镁阻滞的慢速 NMDA 型受体纳入下一代神经质量模型:推导与动力学。

IF 1.5 4区 医学 Q3 MATHEMATICAL & COMPUTATIONAL BIOLOGY
Journal of Computational Neuroscience Pub Date : 2024-08-01 Epub Date: 2024-07-05 DOI:10.1007/s10827-024-00874-2
Hiba Sheheitli, Viktor Jirsa
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引用次数: 0

摘要

我们推导了一个下一代神经群模型,该模型由二次整合-发射神经元群组成,具有慢适应性,以及基于电导的 AMPAR、GABAR 和非线性 NMDAR 突触。我们证明,通过引入 NMDAR 电流的非线性电压依赖性镁阻滞的片断多项式近似,可以满足洛伦兹方差假设。我们针对兴奋性皮层神经元和抑制性纹状体神经元这两个实例,研究了由此产生的系统动力学。与线性 NMDAR 电流的情况相比,分岔图显示了不同的动力学机制,并通过样本比较模拟时间序列展示了不同的可能振荡解决方案。忽略 NMDAR 电流的非线性会导致恒定高发射率机制的范围发生变化(甚至可能消失),同时振荡的振幅和频率功率谱也会发生调制。此外,非线性 NMDAR 作用与状态有关,根据神经元的类型和接收到的输入发射率水平的不同,会产生相反的效果。所提出的模型可作为全脑网络模型中计算效率较高的构建模块,用于研究不同类型的突触在神经调节影响或特定受体失灵情况下的差异调制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Incorporating slow NMDA-type receptors with nonlinear voltage-dependent magnesium block in a next generation neural mass model: derivation and dynamics.

Incorporating slow NMDA-type receptors with nonlinear voltage-dependent magnesium block in a next generation neural mass model: derivation and dynamics.

We derive a next generation neural mass model of a population of quadratic-integrate-and-fire neurons, with slow adaptation, and conductance-based AMPAR, GABAR and nonlinear NMDAR synapses. We show that the Lorentzian ansatz assumption can be satisfied by introducing a piece-wise polynomial approximation of the nonlinear voltage-dependent magnesium block of NMDAR current. We study the dynamics of the resulting system for two example cases of excitatory cortical neurons and inhibitory striatal neurons. Bifurcation diagrams are presented comparing the different dynamical regimes as compared to the case of linear NMDAR currents, along with sample comparison simulation time series demonstrating different possible oscillatory solutions. The omission of the nonlinearity of NMDAR currents results in a shift in the range (and possible disappearance) of the constant high firing rate regime, along with a modulation in the amplitude and frequency power spectrum of oscillations. Moreover, nonlinear NMDAR action is seen to be state-dependent and can have opposite effects depending on the type of neurons involved and the level of input firing rate received. The presented model can serve as a computationally efficient building block in whole brain network models for investigating the differential modulation of different types of synapses under neuromodulatory influence or receptor specific malfunction.

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来源期刊
CiteScore
2.00
自引率
8.30%
发文量
32
审稿时长
3 months
期刊介绍: The Journal of Computational Neuroscience provides a forum for papers that fit the interface between computational and experimental work in the neurosciences. The Journal of Computational Neuroscience publishes full length original papers, rapid communications and review articles describing theoretical and experimental work relevant to computations in the brain and nervous system. Papers that combine theoretical and experimental work are especially encouraged. Primarily theoretical papers should deal with issues of obvious relevance to biological nervous systems. Experimental papers should have implications for the computational function of the nervous system, and may report results using any of a variety of approaches including anatomy, electrophysiology, biophysics, imaging, and molecular biology. Papers investigating the physiological mechanisms underlying pathologies of the nervous system, or papers that report novel technologies of interest to researchers in computational neuroscience, including advances in neural data analysis methods yielding insights into the function of the nervous system, are also welcomed (in this case, methodological papers should include an application of the new method, exemplifying the insights that it yields).It is anticipated that all levels of analysis from cognitive to cellular will be represented in the Journal of Computational Neuroscience.
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