Increased cortical excitability but stable effective connectivity index during attentional lapses.

[en] Modern lifestyle curtails sleep and increases night-time work and leisure activities. This has a deleterious impact on vigilance and attention, exacerbating chances of committing attentional lapses, with potential dramatic outcomes. Here, we investigated the brain signature of attentional lapses and assessed whether cortical excitability and brain response propagation were modified during lapses and whether these modifications changed with aging. We compared electroencephalogram (EEG) responses to transcranial magnetic stimulation (TMS) during lapse and no-lapse periods while performing a continuous attentional/vigilance task at night, after usual bedtime. Data were collected in healthy younger (N=12; 18-30 y) and older individuals (N=12; 50-70 y) of both sexes. The amplitude and slope of the first component of the TMS-Evoked Potential (TEP) were larger during lapses. In contrast, TMS response scattering over the cortical surface, as well as EEG response complexity, did not significantly vary between lapse and no-lapse periods. Importantly, despite qualitative differences, age did not significantly affect any of the TMS-EEG measures. These results demonstrate that attentional lapses are associated with a transient increase of cortical excitability. This initial change is not associated with detectable changes in subsequent effective connectivity - as indexed by response propagation - and are not markedly different between younger and older adults. These findings could contribute to develop models aimed to predicting and preventing lapses in real life situations.

Disciplines :

Neurosciences & behavior

Author, co-author :

Cardone, Paolo ; Université de Liège - ULiège > Stem Cells-Developmental Neurobiology

Van Egroo, Maxime

Chylinski, Daphné ; Université de Liège - ULiège > CRC In vivo Imaging-Sleep and chronobiology

Narbutas, Justinas ; Université de Liège - ULiège > Département de Psychologie > Neuropsychologie

Gaggioni, Giulia

Vandewalle, Gilles ; Université de Liège - ULiège > CRC In vivo Imaging-Sleep and chronobiology

Language :

English

Title :

Increased cortical excitability but stable effective connectivity index during attentional lapses.

Publication date :

2020

Journal title :

Sleep

ISSN :

0161-8105

eISSN :

1550-9109

Publisher :

The American Academy of Sleep Medicine, United States - Illinois

Peer reviewed :

Peer Reviewed verified by ORBi

Commentary :

Available on ORBi :

since 11 February 2021

Statistics

Number of views

106 (16 by ULiège)

Number of downloads

67 (6 by ULiège)

More statistics

Scopus citations^®

Scopus citations^®
without self-citations

OpenCitations

Bibliography

Lim J, et al. Sleep deprivation and vigilant attention. Ann N Y Acad Sci. 2008;1129:305-322.
Cajochen C, et al. EEG and ocular correlates of circadian melatonin phase and human performance decrements during sleep loss. Am J Physiol. 1999;277(3 Pt 2):R640-R649.
Philip P, et al. Transport and industrial safety, how are they affected by sleepiness and sleep restriction? Sleep Med Rev. 2006;10(5):347-356.
Meisel C, et al. The interplay between long- and short-range temporal correlations shapes cortex dynamics across vigilance States. J Neurosci. 2017;37(42):10114-10124.
Vyazovskiy VV, et al. Local sleep in awake rats. Nature. 2011;472(7344):443-447.
Nir Y, et al. Selective neuronal lapses precede human cognitive lapses following sleep deprivation. Nat Med. 2017;23(12):1474-1480.
Dinges DF, et al. Microcomputer analyses of performance on a portable, simple visual RT task during sustained operations. Behav Res Methods Instrum Comput. 1985;17:652-655.
Chee MWL, et al. Lapsing during sleep deprivation is associated with distributed changes in brain activation. J Neurosci. 2008;28(21):5519-5528.
Rosanova M, et al. Combining transcranial magnetic stimulation with electroencephalography to study human cortical excitability and effective connectivity. Neuromethods. 2012;67:435-457.
Huber R, et al. Human cortical excitability increases with time awake. Cereb Cortex. 2013;23(2):332-338.
Ly JQM, et al. Circadian regulation of human cortical excitability. Nat Commun. 2016;7:11828.
Massimini M, et al. Breakdown of cortical effective connectivity during sleep. Science. 2005;309(5744):2228-2232.
Gaggioni G, et al. Human fronto-parietal response scattering subserves vigilance at night. Neuroimage. 2018;175:354-364.
Casali AG, et al. A theoretically based index of consciousness independent of sensory processing and behavior. Sci Transl Med. 2013;5(198):198ra105.
Van Egroo M, et al. Preserved wake-dependent cortical excitability dynamics predict cognitive fitness beyond age-related brain alterations. Commun Biol. 2019;2:449.
Van Egroo M, et al. Sleep-wake regulation and the hallmarks of the pathogenesis of Alzheimer's disease. Sleep. 2019;42(4). doi:10.1093/sleep/zsz017
Hoel EP, et al. Synaptic refinement during development and its effect on slow-wave activity: a computational study. J Neurophysiol. 2016;115(4):2199-2213.
Carrier J, et al. Sleep slow wave changes during the middle years of life. Eur J Neurosci. 2011;33(4):758-766.
Valentinuzzi VS, et al. Effects of aging on the circadian rhythm of wheel-running activity in C57BL/6 mice. Am J Physiol. 1997;273(6):R1957-R1964.
Schmidt C, et al. Age-related changes in sleep and circadian rhythms: impact on cognitive performance and underlying neuroanatomical networks. Front Neurol. 2012;3:118.
Duffy JF, et al. Healthy older adults better tolerate sleep deprivation than young adults. J Am Geriatr Soc. 2009;57(7):1245-1251.
Gaggioni G, et al. Age-related decrease in cortical excitability circadian variations during sleep loss and its links with cognition. Neurobiol Aging. 2019;78:52-63.
Beck AT, et al. An inventory for measuring clinical anxiety: psychometric properties. J Consult Clin Psychol. 1988;56(6):893-897.
Beck AT, et al. Psychometric properties of the Beck Depression Inventory: twenty-five years of evaluation. Clin Psychol Rev. 1988;8(1):77-100.
Mattis S. Dementia Rating Scale: Professional Manual. Psychological Assessment Resources, Incorporated; 1988.
Folstein MF, et al. "Mini-mental state". A practical method for grading the cognitive state of patients for the clinician. J Psychiatr Res. 1975;12(3):189-198.
Virtanen J, et al. Instrumentation for the measurement of electric brain responses to transcranial magnetic stimulation. Med Biol Eng Comput. 1999;37(3):322-326.
Maquet P, et al. Sleep-related consolidation of a visuomotor skill: brain mechanisms as assessed by functional magnetic resonance imaging. J Neurosci. 2003;23(4):1432-1440.
Poudel GR, et al. Distinct neural correlates of time-on-task and transient errors during a visuomotor tracking task after sleep restriction. Neuroimage. 2013;77:105-113.
Makeig S, et al. Comptrack.pdf. Tech Doc 96-3C. San Diego, CA: Naval Health Research Center; 1996. https://apps.dtic.mil/docs/citations/ADA311977. Accessed July 11, 2019.
Leonowicz Z, et al. Trimmed estimators for robust averaging of event-related potentials. J Neurosci Methods. 2005;142(1):17-26.
Comolatti R, et al. A fast and general method to empirically estimate the complexity of brain responses to transcranial and intracranial stimulations. Brain Stimul. 2019;12(5):1280-1289.
Sadegh M, et al. Multivariate Copula Analysis Toolbox (MvCAT): describing dependence and underlying uncertainty using a Bayesian framework. Water Resour Res. 2017;53(6):5166-5183.
Jaeger BC, et al. An R 2 statistic for fixed effects in the generalized linear mixed model. J Appl Stat. 2017;44(6):1086-1105.
Wagenmakers EJ, et al. Bayesian inference for psychology. Part I: theoretical advantages and practical ramifications. Psychon Bull Rev. 2018;25(1):35-57.
Noreika V, et al. Alertness fluctuations when performing a task modulate cortical evoked responses to transcranial magnetic stimulation. NeuroImage. 2020;223:117305. doi:10.1016/j.neuroimage.2020.117305. ISSN: 1053-8119.
Parikh V, et al. Prefrontal acetylcholine release controls cue detection on multiple timescales. Neuron. 2007;56(1):141-154.
Mittner M, et al. A neural model of mind wandering. Trends Cogn Sci. 2016;20(8):570-578.
Steriade M, et al. Natural waking and sleep states: a view from inside neocortical neurons. J Neurophysiol. 2001;85(5):1969-1985.
Steriade M, et al. Thalamocortical oscillations in the sleeping and aroused brain. Science. 1993;262(5134):679-685.
Landolt HP, et al. Reduced neurobehavioral impairment from sleep deprivation in older adults: contribution of adenosinergic mechanisms. Front Neurol. 2012;3:62. doi:10.3389/fneur.2012.00062. PMID: 22557989; PMCID: PMC3338069.
Draganski B, et al. Regional specificity of MRI contrast parameter changes in normal ageing revealed by voxel-based quantification (VBQ). Neuroimage. 2011;55(4):1423-1434.
Legon W, et al. Altered prefrontal excitation/inhibition balance and prefrontal output: markers of aging in human memory networks. Cereb Cortex. 2016;26(11):4315-4326.
Chellappa SL, et al. Circadian dynamics in measures of cortical excitation and inhibition balance. Sci Rep. 2016;6:33661.
Landolt HP, et al. Effect of age on the sleep EEG: slowwave activity and spindle frequency activity in young and middle-aged men. Brain Res. 1996;738(2):205-212.
Munch M, et al. The frontal predominance in human EEG delta activity after sleep loss decreases with age. Eur J Neurosci. 2004;20(5):1402-1410.
Massimini M, et al. Cortical reactivity and effective connectivity during REM sleep in humans. Cogn Neurosci. 2010;1(3):176-183.
Kawagoe T, et al. The neural correlates of "mind blanking": when the mind goes away. Hum Brain Mapp. 2019;40(17):4934-4940.
Cajochen C, et al. Dynamics of frontal EEG activity, sleepiness and body temperature under high and low sleep pressure. Neuroreport. 2001;12(10):2277-2281.
Maric A, et al. Intraindividual increase of homeostatic sleep pressure across acute and chronic sleep loss: a high-density EEG study. Sleep. 2017;40(9). doi:10.1093/sleep/zsx122
McIntosh JR, et al. Estimation of phase in EEG rhythms for real-time applications. J Neural Eng. 2020;17(3):034002.
Bergmann TO. Brain state-dependent brain stimulation. Front Psychol. 2018;9:2108.