Dubna, Moscow, Russian Federation
Dubna, Moscow, Russian Federation
Dubna, Moscow, Russian Federation
Dubna, Moscow, Russian Federation
. In this work, we propose a model approach for analysis of the properties of hippocampal neural networks containing modified glutamate receptors. Molecular dynamics modeling of NMDA and AMPA receptors containing damage caused by the action of free radicals was carried out. The study of network activity of neurons with altered receptor structure was carried out in models of neural network CA3 of the hippocampus region. As a result of studying the properties of the neural network of the hippocampus with a modified structure of glutamate receptors, the electrophysiological characteristics of the known model of neural networks were obtained depending on the structure of the ion channel of the receptor. Based on the analysis of changes in the conductance of the ion channel, differences in the amplitude of the theta and gamma frequency ranges in neural networks with different model structures of AMPA and NMDA receptors were revealed. During the analysis of the network activity of neurons, changes in the conductance of the ion channel of glutamate receptors and local potential were revealed depending on the type of damage. With a significant decrease in the conductivity of the ion channel of the glutamate receptor in the neural network, a decrease in the amplitude of the theta-frequency and an increase in the gamma-frequency ranges is observed. In the case of damage to the TYR731 and CYS765 NMDA receptor in the neural network, an increase in the amplitude of the theta and gamma frequency ranges takes place.
hippocampus, NMDA receptor, Alzheimer’s disease, molecular dynamics, neural network
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