koko体育app

栏目: 文献综述

摘要
• 摘要: 睡眠剥夺的发生率逐年攀升，人们也越发关注睡眠剥夺对躯体与认知的影响。同时，工作记忆也是许多高级认知功能的基石，因此本文从睡眠剥夺对工作记忆的影响，影响睡眠剥夺对工作记忆作用的相关因素及可能存在的作用机制入手，整理回顾近年来的相关文献，旨在更加完整地了解睡眠剥夺对工作记忆的影响，并为制定科学合理的睡眠策略提供依据。

  关键词:
  • 睡眠剥夺 / 
  • 工作记忆 / 
  • 脑皮质功能 / 
  • koko体育app: 电生理机制 
  Abstract: The incidence of sleep deprivation is increasing year by year and people are also paying more attention to the effects of sleep deprivation on the human body and on cognition. In addition, working memory is the foundation of many advanced cognitive functions. Therefore, we reviewed, herein, the relevant research literature on the influence of sleep deprivation on working memory, the relevant influencing factors, and possible mechanisms of action, intending to acquire a more thorough understanding of the effects of sleep deprivation on working memory and to provide evidence for scientific and sound strategies of sleep.

  Key words:
  • koko体育app: Sleep deprivation / 
  • Working memory / 
  • koko体育app: 🌱 🎃 Cerebral cortical function / 
  • koko体育app: Electrophysiolꦰogic𝄹al mechanism 
HTML全文
koko体育app: 参考文献(59)

• [1]	WIGGINS E, MOTTARELLA M, GOOD K, et al. 24-h sleep deprivation impairs early attentional modulation of neural processing: an event-related brain potential study. Neurosci Lett,2018,677: 32–36. doi:
  [2]	LIU H, CHEN A. Roles of sleep deprivation in cardiovascular dysfunctions. Life Sci,2019,219: 231–237. doi:
  [3]	OLSSON M, ARLIG J, HEDNER J, et al. Sleep deprivation and cerebrospinal fluid biomarkers for Alzheimer's disease. Sleep,2018,41(5): zsy025. doi:
  [4]	KATSUNUMA R, OBA K, KITAMURA S, et al. Unrecognized sleep loss ccumulated in daily life can promote brain hyperreactivity to food cue. Sleep,2017,40(10): zsx137. doi:
  [5]	张如意, 游秋云, 张舜波, 等. 睡眠及睡眠剥夺与人体免疫系统的相关性探讨. 中华中医药杂志,2016,31(10): 4169–4171.
  [6]	麦子峰, 许鸿燕, 马宁. 急性睡眠剥夺对认知与情绪功能的影响及其神经机制的研究进展. 中国全科医学,2021,24(29): 3653–3659. doi:
  [7]	ZHANG Y, YANG Y, YANG Y, et al. Alterations incerebellar functional connectivity are correlated with decreased psychomotor vigilance following total sleep deprivation. Front Neurosci,2019,13: 134. doi:
  [8]	HUDSON A N, Van DONGEN H P A, HONN K A. Sleep deprivation, vigilant attention, and brain function: a review. Neuropsychopharmacology,2020,45(1): 21–30. doi:
  [9]	COUSINS J N, WONG K F, CHEE M W L. Multi-night sleep restriction impairs long-term retention of factual knowledge in adolescents. J Adolesc Health,2019,65(4): 549–557. doi:
  [10]	KUSZTOR A, RAUD L, JUEL B E, et al. Sleep deprivation differentially affects subcomponents of cognitive control. Sleep,2019,42(4): zsz016. doi:
  [11]	BARTEL P, OFFERMEIER W, SMITH F, et al. Attention and working memory in resident anaesthetists after night duty: group and individual effects. Occup Environ Med,2004,61(2): 167–170. doi:
  [12]	GOEL N, RAO H, DURMER J S, et al. Neurocognitive consequences of sleep deprivation. Semin Neurol,2009,29(4): 320–339. doi:
  [13]	PENG Z, DAI C, BA Y, et al. Effect of sleep deprivation on the working memory-related N2-P3 components of the event-related potential waveform. Front Neurosci,2020,14: 469. doi:
  [14]	MA N, DINGES D F, BASNER M, et al. How acute total sleep loss affects the attending brain: a meta-analysis of neuroimaging studies. Sleep,2015,38(2): 233–240. doi:
  [15]	ZHANG L, SHAO Y, LIU Z, et al. Decreased information replacement of working memory after sleep deprivation: evidence from an event-related potential study. Front Neurosci,2019,13: 408. doi:
  [16]	CASEMENT M D, BROUSSARD J L, MULLINGTON J M, et al. The contribution of sleep to improvements in working memory scanning speed: a study of prolonged sleep restriction. Biol Psychol,2006,72(2): 208–212. doi:
  [17]	GERHARDSSON A, AKERSTEDT T, AXELSSON J, et al. Effect of sleep deprivation on emotional working memory. J Sleep Res,2019,28(1): e12744. doi:
  [18]	LIM J, DINGES D F. A meta-analysis of the impact of short-term sleep deprivation on cognitive variables. Psychol Bull,2010,136(3): 375–389. doi:
  [19]	TEMPESTA D, GENNARO L, PRESAGHI F, et al. Emotional working memory during sustained wakefulness. J Sleep Res,2014,23(6): 646–656. doi:
  [20]	SANTISTEBAN J A, BROWN T G, OUIMET M C, et al. Cumulative mild partial sleep deprivation negatively impacts working memory capacity but not sustained attention, response inhibition, or decision making: a randomized controlled trial. Sleep Health,2019,5(1): 101–108. doi:
  [21]	LO J C, GROEGER J A, SANTHI N, et al. Effects of partial and acute total sleep deprivation on performance across cognitive domains, individuals and circadian phase. PLoS One,2012,7(9): e45987. doi:
  [22]	HENNECKE E, LANGE D, STEENBERGEN F, et al. Adverse interaction effects of chronic and acute sleep deficits on spatial working memory but not on verbal working memory or declarative memory. J Sleep Res,2021,30(4): e13225. doi:
  [23]	LAMBEK R, SHEVLIN M. Working memory and response inhibition in children and adolescents: age and organization issues. Scand J Psychol,2011,52(5): 427–432. doi:
  [24]	SCHWARZ J, AXELSSON J, GERHARDSSON A, et al. Mood impairment is stronger in young than in older adults after sleep deprivation. J Sleep Res,2019,28(4): e12801. doi:
  [25]	GERHARDSSON A, FISCHER H, LEKANDER M, et al. Positivity effect and working memory performance remains intact in older adults after sleep deprivation. Front Psychol,2019,10: 605. doi:
  [26]	SCHWEIZER S, SATPUTE A, ATZIL S, et al. The impact of affective information on working memory: a pair of meta-analytic reviews of behavioral and neuroimaging evidence. Psychological Bulletin,2019,145(6): 566–609. doi:
  [27]	PASULA E Y, BROWN G G, MCKENNA B S, et al. Effects of sleep deprivation on component processes of working memory in younger and older adults. Sleep,2018,41(3): zsx213. doi:
  [28]	LEJBAK L, CROSSLEY M, VRBANCIC M. A male advantage for spatial and object but not verbal working memory using the n-back task. Brain Cogn,2011,76(1): 191–196. doi:
  [29]	SPECK O, ERNST T, BRAUN J, et al. Gender differences in the functional organization of the brain for working memory. Neuroreport,2000,11(11): 2581–2585. doi:
  [30]	DZAJA A, ARBER S, HISLOP J, et al. Women's sleep in health and disease. J Psychiatr Res,2005,39(1): 55–76. doi:
  [31]	RANGTELL F H, KARAMCHEDU S, ANDERSSON P, et al. A single night of sleep loss impairs objective but not subjective working memory performance in a sex-dependent manner. J Sleep Res,2019,28(1): e12651. doi:
  [32]	SANTHI N, LAZAR A S, MCCABE P J, et al. Sex differences in the circadian regulation of sleep and waking cognition in humans. Proc Natl Acad Sci U S A,2016,113(19): E2730–2739. doi:
  [33]	GOLDSTEIN J M, JERRAM M, POLDRACK R, et al. Sex differences in prefrontal cortical brain activity during fMRI of auditory verbal working memory. Neuropsychology,2005,19(4): 509–519. doi:
  [34]	LIMA C N C, Da SILVA F E R, CHAVES FILHO A J M, et al. High exploratory phenotype rats exposed to environmental stressors present memory deficits accompanied by immune-inflammatory/oxidative alterations: relevance to the relationship between temperament and mood disorders. Front Psychiatry,2019,10: 547. doi:
  [35]	HERMAN A M, CRITCHLEY H D, DUKA T. Risk-taking and impulsivity: the role of mood states and interoception. Front Psychol,2018,9: 1625. doi:
  [36]	VERMEULEN M C M, ASTILL R G, BENJAMINS J S, et al. Temperament moderates the association between sleep duration and cognitive performance in children. J Exp Child Psychol,2016,144: 184–198. doi:
  [37]	HAGEMANN D, HEWIG J, WALTER C, et al. Positive evidence for Eysenck's arousal hypothesis: a combined EEG and MRI study with multiple measurement occasions. Personality Individual Differences,2009,47(7): 717–721. doi:
  [38]	TEMPESTA D, SOCCI V, De GENNARO L, et al. Sleep and emotional processing. Sleep Med Rev,2018,40: 183–195. doi:
  [39]	LINDSTROM B R, BOHLIN G. Emotion processing facilitates working memory performance. Cogn Emot,2011,25(7): 1196–1204. doi:
  [40]	LEVENS S A, PHELPS E A. Emotion processing effects on interference resolution in working memory. Emotion,2008,8(2): 267–280. doi:
  [41]	OSAKA M, YAOI K, MINAMOTO T, et al. When do negative and positive emotions modulate working memory performance? Sci Rep,2013,3: 1375. doi:
  [42]	PERLSTEIN W M, ELBERT T, STENGER V A. Dissociation in human prefrontal cortex of affective influences on working memory-related activity. Proc Natl Acad Sci U S A,2002,99(3): 1736–1741. doi:
  [43]	CHUAH L Y M, DOLCOS F, CHEN A K, et al. Sleep deprivation and interference by emotional distracters. Sleep,2010,33(10): 1305–1313. doi:
  [44]	GUJAR N, YOO S S, HU P, et al. Sleep deprivation amplifies reactivity of brain reward networks, biasing the appraisal of positive emotional experiences. J Neurosci,2011,31(12): 4466–4474. doi:
  [45]	CARPENTER S M, PETERS E, VASTFJALL D, et al. Positive feelings facilitate working memory and complex decision making among older adults. Cogn Emot,2013,27(1): 184–192. doi:
  [46]	DAI C, ZHANG Y, CAI X, et al. Effects of sleep deprivation on working memory: change in functional connectivity between the dorsal attention, default mode, and fronto-parietal networks. Front Hum Neurosci,2020,14: 360. doi:
  [47]	YEUNG M K, SZE S L, WOO J, et al. Reduced frontal activations at high working memory load in mild cognitive impairment: near-infrared spectroscopy. Dement Geriatr Cogn Disord,2016,42(5/6): 278–296. doi:
  [48]	YEUNG M K, LEE T L, CHEUNG W K, et al. Frontal underactivation during working memory processing in adults with acute partial sleep deprivation: a near-infrared spectroscopy study. Front Psychol,2018,9: 742. doi:
  [49]	FORNITO A, HARRISON B J, ZALESKY A, et al. Competitive and cooperative dynamics of large-scale brain functional networks supporting recollection. Proc Natl Acad Sci U S A,2012,109(31): 12788–12793. doi:
  [50]	TAMBER-ROSENAU B J, ASPLUND C L, MAROIS R. Functional dissociation of the inferior frontal junction from the dorsal attention network in top-down attentional control. J Neurophysiol,2018,120(5): 2498–2512. doi:
  [51]	LEI X, ZHAO Z Y, CHEN H. Extraversion is encoded by scale-free dynamics of default mode network. Neuroimage,2013,74: 52–57. doi:
  [52]	MORAN J M, KELLEY W M, HEATHERTON T F. What can the organization of the brain's default mode network tell us about self-knowledge? Front Hum Neurosci,2013,7: 391. doi:
  [53]	QIN P M, NORTHOFF G. How is our self related to midline regions and the default-mode network? Neuroimage,2011,57(3): 1221–1233. doi:
  [54]	SEO J, KIM S H, KIM Y T, et al. Working memory impairment in fibromyalgia patients associated with altered frontoparietal memory network. PLoS One,2012,7(6): e37808. doi:
  [55]	THOMPSON J M, NEUGEBAUER V. Cortico-limbic pain mechanisms. N Neurosci Lett,2019,702: 15–23. doi:
  [56]	CHAMPOD A S, PETRIDES M. Dissociation within the frontoparietal network in verbal working memory: a parametric functional magnetic resonance imaging study. J Neurosci,2010,30(10): 3849–3856. doi:
  [57]	SONG T, YU K, WANG L, et al. Total sleep deprivation triggers greater activation in the parietal brain in the visual working memory updating processes: an event-related potentials study. Front Neurosci,2022,16: 736437. doi:
  [58]	KRAUSE A J, BEN SIMON E, MANDER B A, et al. The sleep-deprived human brain. Nat Rev Neurosci,2017,18(7): 404–418. doi:
  [59]	LI C Y, HUANG D Q, QI J L, et al. Short-term memory deficits correlate with hippocampal-thalamic functional connectivity alterations following acute sleep restriction. Brain Imaging Behav,2017,11(4): 954–963. doi:

koko体育app相关的文章
koko体育app: 施引文献
资源附件(0)
访问统计
•