A new set of composite, non-redundant electroencephalogram measures of non-rapid eye movement sleep based on the power law scaling of the Fourier spectrum

Bódizs, Róbert; Szalárdy, Orsolya; Horváth, Csenge G.; Peter, Ujma Przemyslaw; Gombos, Ferenc; Simor, Péter; Pótári, Adrián; Zeising, Marcel; Steiger, Axel; Dresler, Martin

doi:10.1101/2020.04.09.035113

Cited by 2 publications

(1 citation statement)

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“…We calculated Rüger area global significance as follows: 1/3 of the descriptive significances at p=.05/3 =.017 AND/OR half of descriptive significances at p=.05/2=.025. In this study, we considered data Rüger area significant under the "AND” condition (65, 66).…”

Section: Methodsmentioning

confidence: 99%

Topographical relocation of adolescent sleep spindles reveals a new maturational pattern in the human brain

Gombos

Bódizs

Pótári

et al. 2021

Preprint

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Current theories of human neural development and brain maturation emphasize the posterior-to-anterior or back-to-front pattern as an unequivocal ontogenetic feature that is largely due to the late maturing frontal lobes. The back-to-front pattern has received substantial support from both anatomical and electrophysiological studies, the latter looking at the age-related changes in the topography of sleep slow waves. However, the above scenario of a unidirectional developmental and anatomical route disregards the major hub of the so-called default-mode network, which is a human-specific and late maturing neural structure of the brain, undergoing significant differentiation during adolescence: the precuneus. In order to understand how the late maturation of the precuneus might modify the presently accepted large-scale maturational pattern of the human brain, here we focus on sleep spindles that are known to be involved in neural plasticity with major sources in the precuneus in adults. We provide evidence for the posteriorization in the prevailing anatomical localization of fast sleep spindles. The predominantly central maxima in density and amplitude of fast spindles at the age of 12 years becomes gradually shifted to the parietal regions until the age of 20. Similar changes, albeit at a smaller anatomical distance take place in terms of fast sleep spindle frequency. These findings indicate a front-to-back pattern of brain maturation and correspond with reports on an increased differentiation of the precuneus during adolescence.

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Section: Methodsmentioning

confidence: 99%

Topographical relocation of adolescent sleep spindles reveals a new maturational pattern in the human brain

Gombos

Bódizs

Pótári

et al. 2021

Preprint

Self Cite

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The timescale and magnitude of 1/f aperiodic activity decrease with cortical depth in humans, macaques, and mice

Halgren

Kang

Voytek

et al. 2021

Preprint

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Cortical dynamics obey a 1/f power law, exhibiting an exponential decay of spectral power with increasing frequency. The slope and offset of this 1/f decay reflect the timescale and magnitude of aperiodic neural activity, respectively. These properties are tightly linked to cellular and circuit mechanisms (e.g. excitation:inhibition balance, firing rates) as well as cognitive processes (perception, memory, state). However, the physiology underlying the 1/f power law in cortical dynamics is not well understood. Here, we compared laminar recordings from human, macaque and mouse cortex to evaluate how 1/f aperiodic dynamics vary across cortical layers and species. We report that 1/f slope is steepest in superficial layers and flattest in deep layers in each species. Additionally, the magnitude of this 1/f decay is greatest in superficial cortex and decreases with depth. Both of these findings can be accounted for by a simple model in which transmembrane currents have longer time constants and greater densities in superficial cortical layers. Together, our results provide novel mechanistic insight into aperiodic dynamics in cortex and suggest that the timescale and magnitude of aperiodic cortical currents decrease with cortical depth.

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A new set of composite, non-redundant electroencephalogram measures of non-rapid eye movement sleep based on the power law scaling of the Fourier spectrum

Cited by 2 publications

References 50 publications

Topographical relocation of adolescent sleep spindles reveals a new maturational pattern in the human brain

Topographical relocation of adolescent sleep spindles reveals a new maturational pattern in the human brain

The timescale and magnitude of 1/f aperiodic activity decrease with cortical depth in humans, macaques, and mice

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