In silico Effects of Synaptic Connections in the Visual Thalamocortical Pathway

IF 2.7 Q3 ENGINEERING, BIOMEDICAL Frontiers in medical technology Pub Date : 2022-04-05 DOI:10.3389/fmedt.2022.856412
Swapna Sasi, Basabdatta Sen Bhattacharya
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Abstract

We have studied brain connectivity using a biologically inspired in silico model of the visual pathway consisting of the lateral geniculate nucleus (LGN) of the thalamus, and layers 4 and 6 of the primary visual cortex. The connectivity parameters in the model are informed by the existing anatomical parameters from mammals and rodents. In the base state, the LGN and layer 6 populations in the model oscillate with dominant alpha frequency, while the layer 4 oscillates in the theta band. By changing intra-cortical hyperparameters, specifically inhibition from layer 6 to layer 4, we demonstrate a transition to alpha mode for all the populations. Furthermore, by increasing the feedforward connectivities in the thalamo-cortico-thalamic loop, we could transition into the beta band for all the populations. On looking closely, we observed that the origin of this beta band is in the layer 6 (infragranular layers); lesioning the thalamic feedback from layer 6 removed the beta from the LGN and the layer 4. This agrees with existing physiological studies where it is shown that beta rhythm is generated in the infragranular layers. Lastly, we present a case study to demonstrate a neurological condition in the model. By changing connectivities in the network, we could simulate the condition of significant (P < 0.001) decrease in beta band power and a simultaneous increase in the theta band power, similar to that observed in Schizophrenia patients. Overall, we have shown that the connectivity changes in a simple visual thalamocortical in silico model can simulate state changes in the brain corresponding to both health and disease conditions.
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视觉丘脑皮质通路突触连接的计算机效应
我们已经研究了大脑连接使用一个生物学启发的视觉通路的计算机模型,该模型由丘脑的外侧膝状核(LGN)和初级视觉皮层的第4层和第6层组成。模型中的连通性参数由哺乳动物和啮齿动物的现有解剖参数提供。在基本状态下,模型中的LGN和第6层种群以α频带为主振荡,而第4层在θ频带振荡。通过改变皮质内高参数,特别是从第6层到第4层的抑制,我们证明了所有种群都向α模式过渡。此外,通过增加丘脑-皮质-丘脑回路的前馈连接,我们可以在所有人群中过渡到β波段。通过仔细观察,我们观察到这个β带的起源在第6层(小颗粒层);从第6层的丘脑反馈中删除了LGN和第4层的β。这与现有的生理学研究一致,研究表明β节律是在小颗粒层中产生的。最后,我们提出了一个案例研究,以证明在模型神经条件。通过改变网络中的连接,我们可以模拟出β波段功率显著(P < 0.001)下降而θ波段功率同时增加的情况,类似于在精神分裂症患者中观察到的情况。总的来说,我们已经证明,在一个简单的视觉丘脑皮质计算机模型中,连接的变化可以模拟大脑中与健康和疾病状况相对应的状态变化。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
3.70
自引率
0.00%
发文量
0
审稿时长
13 weeks
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