Roles for Sleep in Neural and Behavioral Plasticity: Reviewing Variation in the Consequences of Sleep Loss

Weiss, Jacqueline T.; Donlea, Jeffrey M.

doi:10.3389/fnbeh.2021.777799

Cited by 14 publications

(15 citation statements)

References 183 publications

(267 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…During wakefulness and learning, new synapses are formed, existing connections are strengthened and overall neural firing increases, thus, resulting in an accumulation of excitation with time spent awake (Maret et al, 2011; Vyazovskiy et al, 2008, 2009). Sleep has been proposed to counteract this progressive build-up of excitation to maintain healthy neural functioning, with sleep deprivation attenuating such homeostatic regulation and impairing cognitive processes and memory formation (Huber et al, 2013; Vyazovskiy et al, 2009; Weiss and Donlea, 2022).…”

Section: Discussionmentioning

confidence: 99%

“…Sleep has been proposed to counteract this progressive build-up of excitation to maintain healthy neural functioning, with sleep deprivation attenuating such homeostatic regulation and impairing cognitive processes and memory formation (Huber et al, 2013;Vyazovskiy et al, 2009;Weiss and Donlea, 2022).…”

Section: E/i-balance Tracks Neural Homeostasis During Sleepmentioning

confidence: 99%

“…Related, in vivo animals studies have revealed that wakefulness and learning lead to a progressive build-up of cellular synaptic potentiation and a net increase of excitability (Tononi and Cirelli, 2014; Vyazovskiy et al, 2008, 2009). In extreme, prolonged wakefulness using sleep deprivation in animal models impairs memory performance due to synaptic saturation (Huber et al, 2013; Weiss and Donlea, 2022). It has been proposed that, during sleep, a neural homeostatic process restores the optimal neural milieu for learning (Timofeev et al, 2001; Tononi and Cirelli, 2006, 2014).…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Human REM sleep controls neural excitability in support of memory formation

Lendner

Mander

Schuh‐Hofer

et al. 2022

Preprint

View full text Add to dashboard Cite

Sleep oscillations provide a key substrate to facilitate memory processing, the underlying mechanism of which may involve the overnight homeostatic regulation of plasticity at a synaptic and whole-network level. However, there remains a lack of human data demonstrating if and how sleep enhances memory consolidation and associated neural homeostasis. We combined intracranial recordings and scalp electroencephalography (EEG) in humans to reveal a new role for rapid eye movement (REM) sleep in promoting the homeostatic recalibration of optimal excitation/inhibition-balance. Moreover, the extent of this REM-sleep homeostatic recalibration predicted the success of overnight memory consolidation, expressly the modulation of hippocampal— neocortical excitability favoring remembering rather than forgetting. The findings describe a novel, fundamental role of human REM sleep in maintaining neural homeostasis, thereby enhancing long-term memory.

show abstract

Section: Discussionmentioning

confidence: 99%

Section: E/i-balance Tracks Neural Homeostasis During Sleepmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Human REM sleep controls neural excitability in support of memory formation

Lendner

Mander

Schuh‐Hofer

et al. 2022

Preprint

View full text Add to dashboard Cite

show abstract

“…Sleep is important for a number of processes in the brain, many of which are related to plastic changes, such as learning and memory or clearing of waste products 4, 14, 15 . Vice versa , the experience during wakefulness, in particular the duration of time spent awake, but also for example learning or injury, impact subsequent sleep across species 4, 15 . However, how neural circuits in the brain integrate the time spent awake as well as specific behaviors for homeostatic sleep regulation, is little understood 3–6 .…”

Section: Glia Activity Monitors Active and Rest Statesmentioning

confidence: 99%

“…Ensheathing glia therefore act as a system for sleep control distributed across brain areas. The structural arrangement of these glia suggests that sleep homeostasis differentially impacts large ensembles of cells at the same time.Sleep is important for a number of processes in the brain, many of which are related to plastic changes, such as learning and memory or clearing of waste products 4,14,15 . Vice versa, the experience during wakefulness, in particular the duration of time spent awake, but also for example learning or injury, impact subsequent sleep across species 4, 15 .…”

mentioning

confidence: 99%

Dynamics of sleep and feeding homeostasis inDrosophilaglia and neurons

Flores-Valle

Seelig

2022

Preprint

View full text Add to dashboard Cite

An animal's need to sleep grows with time spent awake and decays again during sleep. In the brain, a homeostatic process or signal has been proposed to represent sleep need, steadily increasing during wakefulness and gradually decreasing during sleep. However, such dynamics of a sleep homeostat, capturing the changing need to sleep in real time depending on behavior, has so far not been observed in identified cells. Here, using a system that we developed for monitoring calcium activity over multiple days in head-fixed, walking fruit flies, we find that a class of glia in the fly brain, called ensheathing glia, shows dynamics expected of a sleep homeostat. Calcium levels in these cells - monitored in a central brain area important for memory, navigation and sleep - integrate activity during wakefulness, reset during sleep, and saturate under sleep deprivation. Optogenetic activation of ensheathing glia induces sleep consistent with charging of the homeostat. The dynamics of the sleep homeostat, observed in glia of different brain compartments with similar but distinct dynamics, agree with conceptual model expectations. Ensheathing glia therefore act as a system for sleep control distributed across brain areas. The structural arrangement of these glia suggests that sleep homeostasis differentially impacts large ensembles of cells at the same time.

show abstract

Adenotonsillectomy for Snoring and Mild Sleep Apnea in Children

Redline,

Cook,

Chervin

et al. 2023

JAMA

View full text Add to dashboard Cite

ImportanceThe utility of adenotonsillectomy in children who have habitual snoring without frequent obstructive breathing events (mild sleep-disordered breathing [SDB]) is unknown.ObjectivesTo evaluate early adenotonsillectomy compared with watchful waiting and supportive care (watchful waiting) on neurodevelopmental, behavioral, health, and polysomnographic outcomes in children with mild SDB.Design, Setting, and ParticipantsRandomized clinical trial enrolling 459 children aged 3 to 12.9 years with snoring and an obstructive apnea-hypopnea index (AHI) less than 3 enrolled at 7 US academic sleep centers from June 29, 2016, to February 1, 2021, and followed up for 12 months.InterventionParticipants were randomized 1:1 to either early adenotonsillectomy (n = 231) or watchful waiting (n = 228).Main Outcomes and MeasuresThe 2 primary outcomes were changes from baseline to 12 months for caregiver-reported Behavior Rating Inventory of Executive Function (BRIEF) Global Executive Composite (GEC) T score, a measure of executive function; and a computerized test of attention, the Go/No-go (GNG) test d-prime signal detection score, reflecting the probability of response to target vs nontarget stimuli. Twenty-two secondary outcomes included 12-month changes in neurodevelopmental, behavioral, quality of life, sleep, and health outcomes.ResultsOf the 458 participants in the analyzed sample (231 adenotonsillectomy and 237 watchful waiting; mean age, 6.1 years; 230 female [50%]; 123 Black/African American [26.9%]; 75 Hispanic [16.3%]; median AHI, 0.5 [IQR, 0.2-1.1]), 394 children (86%) completed 12-month follow-up visits. There were no statistically significant differences in change from baseline between the 2 groups in executive function (BRIEF GEC T-scores: −3.1 for adenotonsillectomy vs −1.9 for watchful waiting; difference, −0.96 [95% CI, −2.66 to 0.74]) or attention (GNG d-prime scores: 0.2 for adenotonsillectomy vs 0.1 for watchful waiting; difference, 0.05 [95% CI, −0.18 to 0.27]) at 12 months. Behavioral problems, sleepiness, symptoms, and quality of life each improved more with adenotonsillectomy than with watchful waiting. Adenotonsillectomy was associated with a greater 12-month decline in systolic and diastolic blood pressure percentile levels (difference in changes, −9.02 [97% CI, −15.49 to −2.54] and −6.52 [97% CI, −11.59 to −1.45], respectively) and less progression of the AHI to greater than 3 events/h (1.3% of children in the adenotonsillectomy group compared with 13.2% in the watchful waiting group; difference, −11.2% [97% CI, −17.5% to −4.9%]). Six children (2.7%) experienced a serious adverse event associated with adenotonsillectomy.ConclusionsIn children with mild SDB, adenotonsillectomy, compared with watchful waiting, did not significantly improve executive function or attention at 12 months. However, children with adenotonsillectomy had improved secondary outcomes, including behavior, symptoms, and quality of life and decreased blood pressure, at 12-month follow-up.Trial RegistrationClinicalTrials.gov Identifier: NCT02562040

show abstract

Roles for Sleep in Neural and Behavioral Plasticity: Reviewing Variation in the Consequences of Sleep Loss

Cited by 14 publications

References 183 publications

Human REM sleep controls neural excitability in support of memory formation

Human REM sleep controls neural excitability in support of memory formation

Dynamics of sleep and feeding homeostasis inDrosophilaglia and neurons

Adenotonsillectomy for Snoring and Mild Sleep Apnea in Children

Contact Info

Product

Resources

About