Modelling cortical network dynamics.

IF 2.8 Q2 MULTIDISCIPLINARY SCIENCES
SN Applied Sciences Pub Date : 2024-01-01 Epub Date: 2024-01-29 DOI:10.1007/s42452-024-05624-8
Gerald Kaushallye Cooray, Richard Ewald Rosch, Karl John Friston
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Abstract

We have investigated the theoretical constraints of the interactions between coupled cortical columns. Each cortical column consists of a set of neural populations where each population is modelled as a neural mass. The existence of semi-stable states within a cortical column is dependent on the type of interaction between the neuronal populations, i.e., the form of the synaptic kernels. Current-to-current coupling has been shown, in contrast to potential-to-current coupling, to create semi-stable states within a cortical column. The interaction between semi-stable states of the cortical columns is studied where we derive the dynamics for the collected activity. For small excitations the dynamics follow the Kuramoto model; however, in contrast to previous work we derive coupled equations between phase and amplitude dynamics with the possibility of defining connectivity as a stationary and dynamic variable. The turbulent flow of phase dynamics which occurs in networks of Kuramoto oscillators would indicate turbulent changes in dynamic connectivity for coupled cortical columns which is something that has been recorded in epileptic seizures. We used the results we derived to estimate a seizure propagation model which allowed for inversions using the Laplace assumption (Dynamic Causal Modelling). The seizure propagation model was trialed on simulated data, and future work will investigate the estimation of the connectivity matrix from empirical data. This model can be used to predict changes in seizure evolution after virtual changes in the connectivity network, something that could be of clinical use when applied to epilepsy surgical cases.

皮层网络动态建模
我们研究了耦合皮层列之间相互作用的理论约束。每个皮质柱由一组神经群组成,其中每个神经群被模拟为一个神经块。皮质柱内半稳定状态的存在取决于神经元群之间的相互作用类型,即突触核的形式。与电位-电流耦合相反,电流-电流耦合被证明能在皮质柱内产生半稳定状态。我们研究了大脑皮层柱半稳定状态之间的相互作用,并在此基础上推导出收集活动的动力学。对于小激励,动力学遵循 Kuramoto 模型;然而,与之前的工作不同,我们推导出了相位和振幅动力学之间的耦合方程,并有可能将连接性定义为一个静态和动态变量。库拉莫托振荡器网络中出现的相位动态湍流将表明耦合皮质柱的动态连接性发生了湍流变化,而这正是癫痫发作中记录到的。我们利用得出的结果估算了癫痫发作传播模型,该模型允许使用拉普拉斯假设进行反演(动态因果建模)。癫痫发作传播模型在模拟数据上进行了试验,未来的工作将研究从经验数据中估算连接矩阵。该模型可用于预测连通性网络发生虚拟变化后癫痫发作演变的变化,这在应用于癫痫手术病例时可能会有临床用途。
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来源期刊
SN Applied Sciences
SN Applied Sciences MULTIDISCIPLINARY SCIENCES-
自引率
3.80%
发文量
292
审稿时长
22 weeks
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