Low frequency oscillations drive EEG’s complexity changes during wakefulness and sleep

Low frequency oscillations drive EEG’s complexity changes during wakefulness and sleep

[Display omitted] •Low-frequency activity shapes EEG complexity during wakefulness and sleep.•These complexity patterns are recovered in micro, meso and macroscopic recordings.•Low-frequency sensory-motor integration decreases during REM sleep. Recently, the sleep-wake states have been analysed usin...

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Bibliographic Details
Published in:Neuroscience Vol. 494; pp. 1 - 11
Main Authors: González, Joaquín, Mateos, Diego, Cavelli, Matias, Mondino, Alejandra, Pascovich, Claudia, Torterolo, Pablo, Rubido, Nicolás
Format: Journal Article
Language:English
Published: United States Elsevier Ltd 01-07-2022
Subjects:
EEG
low frequency oscillations
sleep-wake cycle
sleep-wake cycle
low frequency oscillations
EEG
Online Access:Get full text
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Summary:[Display omitted] •Low-frequency activity shapes EEG complexity during wakefulness and sleep.•These complexity patterns are recovered in micro, meso and macroscopic recordings.•Low-frequency sensory-motor integration decreases during REM sleep. Recently, the sleep-wake states have been analysed using novel complexity measures, complementing the classical analysis of EEGs by frequency bands. This new approach consistently shows a decrease in EEG’s complexity during slow-wave sleep, yet it is unclear how cortical oscillations shape these complexity variations. In this work, we analyse how the frequency content of brain signals affects the complexity estimates in freely moving rats. We find that the low-frequency spectrum – including the Delta, Theta, and Sigma frequency bands – drives the complexity changes during the sleep-wake states. This happens because low-frequency oscillations emerge from neuronal population patterns, as we show by recovering the complexity variations during the sleep-wake cycle from micro, meso, and macroscopic recordings. Moreover, we find that the lower frequencies reveal synchronisation patterns across the neocortex, such as a sensory-motor decoupling that happens during REM sleep. Overall, our works shows that EEG’s low frequencies are critical in shaping the sleep-wake states’ complexity across cortical scales.
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ISSN:0306-4522
1873-7544
DOI:10.1016/j.neuroscience.2022.04.025