MOTOR CONTROL AND COGNITIVE FUNCTIONS RECOVERY DURING FORCED AWAKENING FROM SLOW-WAVE DAYTIME SLEEP

A. K. Soloveva; Соловьева А. К.; N. K. Solovev; Соловьев Н. К.; A. O. Mokrousova; Мокроусова А. О.; Yu. V. Ukraintseva; Украинцева Ю. В.

doi:10.31857/S0044467723060096

MOTOR CONTROL AND COGNITIVE FUNCTIONS RECOVERY DURING FORCED AWAKENING FROM SLOW-WAVE DAYTIME SLEEP

Authors: Soloveva A.K.¹^,2, Solovev N.K.³, Mokrousova A.O.⁴, Ukraintseva Y.V.²
Affiliations:
1. Lomonosov Moscow State University
2. Institute of Higher Nervous Activity and Neurophysiology RAS
3. MIREA – Russian Technological University
4. Novosibirsk State University
Issue: Vol 73, No 6 (2023)
Pages: 785-799
Section: ФИЗИОЛОГИЯ ВЫСШЕЙ НЕРВНОЙ (КОГНИТИВНОЙ) ДЕЯТЕЛЬНОСТИ ЧЕЛОВЕКА
URL: https://journals.rcsi.science/0044-4677/article/view/233004
DOI: https://doi.org/10.31857/S0044467723060096
EDN: https://elibrary.ru/ULAEPC
ID: 233004

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Abstract
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Abstract

The recovery mechanisms of various forms of behavior upon awakening from sleep are still not well understood. In this work, we investigated the recovery of simple motor reactions to visual stimuli, fine hand-eye coordination, and abstract thinking upon awakening from the deepest, SWS stage of daytime sleep. Subjects were offered two types of tasks: visual-motor tasks in which it was necessary to control a moving object; and arithmetic, in which it was necessary to determine the correctness of the proposed equalities in wakefulness before sleep and during the first 2 minutes of awakening from sleep. The results obtained showed that the speed of a simple motor reaction to the appearance of a visual stimulus reached the wakefulness level almost immediately after awakening (within 4 seconds), while the restoration of the ability to determine the correctness or incorrectness of arithmetic equalities, as well as the ability to accurately control the trajectory of a moving object required much more time: about 40 seconds (in the arithmetic task) and 60 seconds (in the visual-motor task). The power of the alpha-rhythm upon awakening was higher than in wakefulness. Delta-rhythm power was increased only at the beginning of awakening while task performing was difficult, and in the second minute of awakening the delta-rhythm decreased when task performing was restored. Our data indicate that simple and complex forms of behavior upon awakening are not restored simultaneously.

Keywords

daytime sleep, hand-eye coordination, abstract thinking, SWS stage of sleep, awakening, EEG, alpha-rhythm, delta-rhythm

References

Ковальзон В.М. Основы Сомнологии: Физиология и нейрохимия цикла “бодрствование-сон”. М.: Бином. Лаборатория знаний, 2012. 239 с.
Левкович К.М. Восстановление сознания при пробуждении от ортодоксального и парадоксального сна. Электрофизиологическое исследование: автореф… дис. канд. биол. наук. М.: 2022. 26 с.
Украинцева Ю.В., Соловьева А.К. Феномен пробуждения от сна. Нейрофизиологические и вегетативные процессы, его обеспечивающие. Журнал неврологии и психиатрии им. С.С. Корсакова. 2023. 123 (5): 21–27.
Alcaide S., Sitt J., Horikawa T., Romano A., Maldonado A.C., Ibanez A., Sigman M., Kamitani Y., Barttfeld P. fMRI lag structure during waking up from early sleep stages. Cortex. 2021. 142 (3): 94–103.
Bassetti C., Vella S., Donati F., Wielepp P. SPECT during sleepwalking. Lancet. 2000. 356 (9228): 484–485.
Braun A.R., Balkin T.J., Wesenten N.J., Carson R.E., Varga M., Baldwin P., Selbie S., Belenky G., Herscovitch P. (1997). Regional Cerebral Blood Flow throughout the Sleep-Wake Cycle. An H2(15)O PET Study. Brain 120 (Pt 7), 1173–1197. https://doi.org/10.1093/brain/120.7.1173
De Carli F., Proserpio P., Morrone E., Sartori I., Ferrara M., Gibbs S.A., De Gennaro L., Lo Russo G., Nobili L. Activation of the motor cortex during phasic rapid eye movement sleep. Ann. Neurol. 2016. 79 (2): 326–330.
Horner R.L., Sanford L.D., Pack A.I., Morrison A.R. Activation of a distinct arousal state immediately after spontaneous awakening from sleep. Brain Res. 1997. 778 (1): 127–134.
Iber C., Ancoli-Israel S., Chesson A., Quan S.F. for the American Academy of Sleep Medicine. The AASM manual for the scoring of sleep and associated events: rules, terminology and technical specification. 1st ed.: Wenstchester, Illinois: American Academy of Sleep Medicine, 2007. 59 p.
Latreille V., von Ellenrieder N., Peter-Derex L., Dubeau F., Gotman J., Frauscher B. The human K-complex: insights from combined scalp-intracranial EEG recordings. Neuroimage. 2020. 213: e116748.
Liaukovich K., Sazhin S., Bobrov P., Ukraintseva Y. Event-related potential study of recovery of consciousness during forced awakening from slow-wave sleep and rapid eye movement sleep. Int. J. Mol. Sci. 2022. 23 (19): e11785.
Makeig S., Bell A., Jung T.P., Sejnowski T.J. Independent component analysis of electroencephalographic data. Advances in neural information processing systems. 1995. 8: 145–151.
Marzano C., Ferrara M., Curcio G., De Gennaro L. The effects of sleep deprivation in humans: topographical electroencephalogram changes in non-rapid eye movement (NREM) sleep versus REM sleep. J. Sleep Res. 2010. 19 (2): 260–268.
Müller-Putz G.R. Electroencephalography. Handb. Clin. Neurol. 2020. 168 (2007): 249–262.
Mylonas D., Tocc C., Coon W.G., Baran B., Kohnke E.J., Zhu L., Vange M.G., Stickgold R., Manoach D.S. Naps reliably estimate nocturnal sleep spindle density in health and schizophrenia. Journal of sleep research. 2020. 29 (5): e12968.
Nobili L., Ferrara M., Moroni F., De Gennaro L., Russo G. Lo, Campus C., Cardinale F., De Carli F. Dissociated wake-like and sleep-like electro-cortical activity during sleep. Neuroimage. 2011. 58 (2): 612–619.
Peter-Derex L., Magnin M., Bastuji H. Heterogeneity of arousals in human sleep: a stereo-electroencephalographic study. Neuroimage. 2015. 123: 229–244.
Shah S., Ghosh S., Nagarajan L. Is sleep captured during a standard daytime EEG sufficient to diagnose Electrical Status Epilepticus in Sleep. Epilepsy Behav. Reports. 2023. 23: e100611.
Simon K.C., McDevitt E.A., Ragano R., Mednick S.C. Progressive muscle relaxation increases slow-wave sleep during a daytime nap. J. Sleep Res. 2022. 31 (5): 1–10.
Steriade M., Timofeev I., Grenier F. Natural waking and sleep states: a view from inside neocortical neurons. J. Neurophysiol. 2001. 85 (5): 1969–1985.
Terzaghi M., Sartori I., Tassi L., Didato G., Rustioni V., LoRusso G., Manni R., Nobili L. Evidence of dissociated arousal states during NREM parasomnia from an intracerebral neurophysiological study. Sleep. 2009. 32 (3): 409–412.
Trotti L.M. Waking up is the hardest thing I do all day: sleep inertia and sleep drunkenness. Sleep Med. Rev. 2017. 35: 76–84.