2014
DOI: 10.3389/fnsys.2014.00208
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Enhancement of sleep slow waves: underlying mechanisms and practical consequences

Abstract: Even modest sleep restriction, especially the loss of sleep slow wave activity (SWA), is invariably associated with slower electroencephalogram (EEG) activity during wake, the occurrence of local sleep in an otherwise awake brain, and impaired performance due to cognitive and memory deficits. Recent studies not only confirm the beneficial role of sleep in memory consolidation, but also point to a specific role for sleep slow waves. Thus, the implementation of methods to enhance sleep slow waves without unwante… Show more

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Cited by 206 publications
(218 citation statements)
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References 207 publications
(283 reference statements)
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“…In older subjects with SDB, treatment with CPAP improves sleep architecture including SWS. 41 In older subjects without SDB, transcranial magnetic stimulation 42 and existing medications 43,44 may increase or trigger SWS and reduce Aβ42 production. Whether such interventions affect Aβ42 metabolism and/or disease progression remains to be tested, but our current findings support further investigation.…”
Section: Discussionmentioning
confidence: 99%
“…In older subjects with SDB, treatment with CPAP improves sleep architecture including SWS. 41 In older subjects without SDB, transcranial magnetic stimulation 42 and existing medications 43,44 may increase or trigger SWS and reduce Aβ42 production. Whether such interventions affect Aβ42 metabolism and/or disease progression remains to be tested, but our current findings support further investigation.…”
Section: Discussionmentioning
confidence: 99%
“…Deficits in slow-wave sleep are particularly troubling as slow-wave sleep time is typically preserved despite significant sleep restriction (Van Dongen et al, 2003). Furthermore, such deficits are associated both with clinical disorders and impairments in a wide range of cognitive functions including sensory, motor, and declarative learning, as well as executive function and alertness (e.g., Bellesi et al, 2014; Roth et al, 2010). Unfortunately, most pharmacological interventions that target sleep do not affect slow-wave sleep, or actually diminish slow-wave sleep while increasing the time spent in lighter sleep (e.g., Achermann and Borbely, 1987).…”
Section: Introductionmentioning
confidence: 99%
“…Triggering slow waves can also deepen the sleep (Huber et al, 2008) and the amount of slow waves is positively correlated with post-sleep performance improvement (Huber, Ghilardi, Massimini, & Tononi, 2004). Enhancing slow waves might be beneficial in many patient groups with decreased slow wave sleep, for instance patients with chronic sleep restriction and insomnia (Bellesi, Riedner, Garcia-Molina, Cirelli, & Tononi, 2014;Massimini et al, 2007). The present paired-pulse paradigm elicited slow waves by stimulation of a brain area that is normally not involved in the generation of slow wave activity (Murphy et al, 2009).…”
Section: Discussionmentioning
confidence: 87%