Litcius/Paper detail

Region-specific complexity of the intracranial EEG in the sleeping human brain

Elzbieta Olejarczyk, Jean Gotman, Birgit Frauscher

2022Scientific Reports29 citationsDOIOpen Access PDF

Abstract

As the brain is a complex system with occurrence of self-similarity at different levels, a dedicated analysis of the complexity of brain signals is of interest to elucidate the functional role of various brain regions across the various stages of vigilance. We exploited intracranial electroencephalogram data from 38 cortical regions using the Higuchi fractal dimension (HFD) as measure to assess brain complexity, on a dataset of 1772 electrode locations. HFD values depended on sleep stage and topography. HFD increased with higher levels of vigilance, being highest during wakefulness in the frontal lobe. HFD did not change from wake to stage N2 in temporo-occipital regions. The transverse temporal gyrus was the only area in which the HFD did not differ between any two vigilance stages. Interestingly, HFD of wakefulness and stage R were different mainly in the precentral gyrus, possibly reflecting motor inhibition in stage R. The fusiform and parahippocampal gyri were the only areas showing no difference between wakefulness and N2. Stages R and N2 were similar only for the postcentral gyrus. Topographical analysis of brain complexity revealed that sleep stages are clearly differentiated in fronto-central brain regions, but that temporo-occipital regions sleep differently.

Topics & Concepts

WakefulnessHuman brainPostcentral gyrusNeuroscienceElectroencephalographySleep StagesPrecentral gyrusElectrocorticographyVigilance (psychology)Sleep (system call)Parahippocampal gyrusBrain activity and meditationPsychologyNeocortexBrain mappingAudiologySupplementary motor areaSlow-wave sleepFractal dimensionMedicineCerebral cortexThalamusFractal analysisSleep onsetIctalGyrusMotor areaMotor cortexEEG-fMRISuperior frontal gyrusNon-rapid eye movement sleepFunctional Brain Connectivity StudiesEEG and Brain-Computer InterfacesNeural dynamics and brain function