Mechanisms of the action of endogenous electrotonic influences and exogenous factors on biological rhythms of neurons

Автор: Orlov Valery I., Sukhov Aleksandr G., Kit Oleg I., Shikhlyarova Alla I., Rudenko Mikhail Y., Kirichenko Evgeniya Y., Fillipova Svetlana Y., Pashintsev Germany Gieen Ludwigstrae, Protasova Tatiana

Журнал: Cardiometry @cardiometry

Рубрика: Original research

Статья в выпуске: 12, 2018 года.

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Subjects of our experimental studies were neurons in the snail Helix Pomatia, from which continuous intracellular recordings according to our specific microelectrode recording technique were produced. We have carried out original investigations of the processes of control and regulation of endogenous biological rhythms of neurons, observing them both under their background activity (free of stimulation) and under the action of the exogenous factors within a chronic experiment, which involved continuous recordings of activity from the neurons that covered periods from 50 to 60 hours, with an incubated ganglion cell life span up to four 24-hour days. In the neurophysiological experimental studies with recordings of intracellular activity of the identified CNS neurons in the Roman snail Helix Pomatia, we conducted a research into identification of a contribution of potential-dependent ion (K+, Ca2+, Na+) channels to formation of pacemaking oscillatory activity of the neurons and an interplay of the AP generation loci unequally or irregularly spaced. It has been shown that it is possible to activate at the same time 2-3 individual loci of generation of the Na+ spikes, differing in their amplitudes, which appear at different segments of the axo-dendritic axis of the neurons in the snail Helix Pomatia.

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Neuron, rhythm genesis, biological intracellular rhythm, synapse, potential-dependent ion channels, functional state, electromagnetic radiation

Короткий адрес: https://sciup.org/148308841

IDR: 148308841   |   DOI: 10.12710/cardiometry.2018.12.3953

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