How do children fall asleep? A high-density EEG study of slow waves in the transition from wake to sleep.
Détails
Télécharger: 29758338AM.pdf (10279.39 [Ko])
Etat: Public
Version: Author's accepted manuscript
Etat: Public
Version: Author's accepted manuscript
Document(s) secondaire(s)
Télécharger: Figure 1, revised.pdf (15.49 [Ko])
Etat: Public
Version: Supplementary document
Etat: Public
Version: Supplementary document
Télécharger: Supplemental tables.pdf (204.67 [Ko])
Etat: Public
Version: Supplementary document
Etat: Public
Version: Supplementary document
ID Serval
serval:BIB_508D8683B090
Type
Article: article d'un périodique ou d'un magazine.
Collection
Publications
Institution
Titre
How do children fall asleep? A high-density EEG study of slow waves in the transition from wake to sleep.
Périodique
NeuroImage
ISSN
1095-9572 (Electronic)
ISSN-L
1053-8119
Statut éditorial
Publié
Date de publication
09/2018
Peer-reviewed
Oui
Volume
178
Pages
23-35
Langue
anglais
Notes
Publication types: Journal Article ; Research Support, Non-U.S. Gov't
Publication Status: ppublish
Publication Status: ppublish
Résumé
Slow waves, the hallmarks of non-rapid eye-movement (NREM) sleep, are thought to reflect maturational changes that occur in the cerebral cortex throughout childhood and adolescence. Recent work in adults has revealed evidence for two distinct synchronization processes involved in the generation of slow waves, which sequentially come into play in the transition to sleep. In order to understand how these two processes are affected by developmental changes, we compared slow waves between children and young adults in the falling asleep period.
The sleep onset period (starting 30s before end of alpha activity and ending at the first slow wave sequence) was extracted from 72 sleep onset high-density EEG recordings (128 electrodes) of 49 healthy subjects (age 8-25). Using an automatic slow wave detection algorithm, the number, amplitude and slope of slow waves were analyzed and compared between children (age 8-11) and young adults (age 20-25).
Slow wave number and amplitude increased linearly in the falling asleep period in children, while in young adults, isolated high-amplitude slow waves (type I) dominated initially and numerous smaller slow waves (type II) with progressively increasing amplitude occurred later. Compared to young adults, children displayed faster increases in slow wave amplitude and number across the falling asleep period in central and posterior brain regions, respectively, and also showed larger slow waves during wakefulness immediately prior to sleep.
Children do not display the two temporally dissociated slow wave synchronization processes in the falling asleep period observed in adults, suggesting that maturational factors underlie the temporal segregation of these two processes. Our findings provide novel perspectives for studying how sleep-related behaviors and dreaming differ between children and adults.
The sleep onset period (starting 30s before end of alpha activity and ending at the first slow wave sequence) was extracted from 72 sleep onset high-density EEG recordings (128 electrodes) of 49 healthy subjects (age 8-25). Using an automatic slow wave detection algorithm, the number, amplitude and slope of slow waves were analyzed and compared between children (age 8-11) and young adults (age 20-25).
Slow wave number and amplitude increased linearly in the falling asleep period in children, while in young adults, isolated high-amplitude slow waves (type I) dominated initially and numerous smaller slow waves (type II) with progressively increasing amplitude occurred later. Compared to young adults, children displayed faster increases in slow wave amplitude and number across the falling asleep period in central and posterior brain regions, respectively, and also showed larger slow waves during wakefulness immediately prior to sleep.
Children do not display the two temporally dissociated slow wave synchronization processes in the falling asleep period observed in adults, suggesting that maturational factors underlie the temporal segregation of these two processes. Our findings provide novel perspectives for studying how sleep-related behaviors and dreaming differ between children and adults.
Mots-clé
Adolescent, Adult, Age Factors, Brain Waves/physiology, Child, Child Development/physiology, Electroencephalography/methods, Female, Humans, Male, Sleep Stages/physiology, Wakefulness/physiology, Young Adult
Pubmed
Web of science
Création de la notice
17/05/2018 17:33
Dernière modification de la notice
21/11/2022 8:24