about
Human central auditory plasticity associated with tone sequence learningUMTS base station-like exposure, well-being, and cognitive performanceNon-rapid eye movement sleep with low muscle tone as a marker of rapid eye movement sleep regulationGlobal field synchronization reveals rapid eye movement sleep as most synchronized brain state in the human EEGIncreased Sleep Depth in Developing Neural Networks: New Insights from Sleep Restriction in ChildrenCognitive performance measures in bioelectromagnetic research--critical evaluation and recommendations.Different Effects of Sleep Deprivation and Torpor on EEG Slow-Wave Characteristics in Djungarian Hamsters.Impaired postural control in healthy men at moderate altitude (1630 m and 2590 m): data from a randomized trial.Dissipation of sleep pressure is stable across adolescence.Topographical aspects in the dynamics of sleep homeostasis in young men: individual patterns.Developmental changes in brain connectivity assessed using the sleep EEG.Triangular relationship between sleep spindle activity, general cognitive ability and the efficiency of declarative learning.Random number generation during sleep deprivation: effects of caffeine on response maintenance and stereotypy.Electromagnetic fields, such as those from mobile phones, alter regional cerebral blood flow and sleep and waking EEG.Exposure to pulse-modulated radio frequency electromagnetic fields affects regional cerebral blood flow.Mathematical models of sleep regulation.Effect of Rocking Movements on Respiration.Actigraphy of Wrist and Ankle for Measuring Sleep Duration in Altitude Travelers.Developmental Changes in Sleep Spindle Characteristics and Sigma Power across Early ChildhoodAnalysis of the temporal organization of sleep spindles in the human sleep EEG using a phenomenological modeling approach.Trait-like characteristics of the sleep EEG across adolescent development.Development of nap neurophysiology: preliminary insights into sleep regulation in early childhood.Relation of Heart Rate and its Variability during Sleep with Age, Physical Activity, and Body Composition in Young Children.Sleep, intelligence and cognition in a developmental context: differentiation between traits and state-dependent aspects.The multiple time scales of sleep dynamics as a challenge for modelling the sleeping brain.Developmental Changes in Sleep Oscillations during Early ChildhoodDevelopmental Changes in Ultradian Sleep Cycles across Early Childhood.Radio frequency electromagnetic field exposure in humans: Estimation of SAR distribution in the brain, effects on sleep and heart rate.Commentary: future considerations for models of human neurobehavioral function.All-night sleep EEG and artificial stochastic control signals have similar correlation dimensions.Decline of long-range temporal correlations in the human brain during sustained wakefulness.Caffeine attenuates waking and sleep electroencephalographic markers of sleep homeostasis in humans.In human non-REM sleep, more slow-wave activity leads to less blood flow in the prefrontal cortex.The EEG microstate topography is predominantly determined by intracortical sources in the alpha band.The sleeping brain as a complex system.The Effect of a Slowly Rocking Bed on Sleep.Resisting Sleep Pressure: Impact on Resting State Functional Network Connectivity.Mapping Slow Waves by EEG Topography and Source Localization: Effects of Sleep Deprivation.Global field synchronization in gamma range of the sleep EEG tracks sleep depth: Artifact introduced by a rectangular analysis window.Three decades of continuous wrist-activity recording: analysis of sleep duration.
P50
Q24608948-13995CAC-7C10-43EA-BE66-9AB5A6BF80FBQ24673435-6867C605-89D5-4811-AFF0-3CF6966CCAB4Q25255697-712E8689-17BE-436E-8644-AC26763FB9D5Q28596363-508E9813-76C3-45E0-ABA1-1F7574AD51FBQ30372819-336ADA32-6396-4DD7-AFE8-BE15043F0980Q30476920-2907AE0A-37C9-43D9-A119-BF26F09F0E4BQ30845205-C5170FCA-F681-4FD0-A357-73732A83029CQ30901373-3670B6B9-CDB7-4891-B93F-DC157836A29FQ33865664-F56DBFB1-27E9-4254-8408-A94F5EDB6291Q33994094-097D54E7-E70E-41C1-A256-048577E0C7E2Q33994442-239FC38B-E209-4A96-9C59-4DD9C475C4E8Q34490150-F9A5F1DD-8C78-4EDA-908E-0B7BFF6884A0Q34496193-163CA55D-4F45-44CF-8C98-A037EBD6F54DQ34529508-3F1CAD2E-39DF-4794-9494-AB29E71B8110Q34556187-847A51C0-56EE-4BED-BCEF-7A1E544F8D18Q35109377-37B6AABB-D816-4A00-BC82-3F20DE32660EQ35949340-FC3BB858-382B-42C3-82F5-508FE68BFE16Q36068807-B7CC8AD7-A5B4-4C7F-9EC7-ED819446EC89Q36784004-45A8A930-26F1-4265-B8BF-9AD20827EAE3Q36979339-E91BC070-EA34-45DD-A142-2C9E6FE2262DQ37135688-EF598BC0-57E0-488C-8E58-3245AF47DE89Q37470133-5390B358-23C7-4037-9514-B10C9E081CDAQ37662590-A0C8CBAA-DAEC-4372-A3E2-07B016D36AC8Q37809328-F4F240B2-06F4-45B3-BEF4-A4B030524D76Q37926761-D78235FC-EB3B-4B84-97FB-D5323385E979Q38606242-95EB3CD2-8669-4504-8DB9-898E44FBF53AQ39020070-91A64993-F57A-4045-A5DE-5F49614AA45CQ39647153-AE6EC649-3F3C-404F-B43A-A14C5D12ECF6Q40781405-EB049D96-3A04-412B-8F89-E6B2CB17A5A1Q41661719-FEC37EF5-DBFD-440F-B62E-82CF4730BAB1Q41717559-FB8DCBD4-035D-401C-A9F0-03C58A63832DQ44981520-C59C536C-FA3F-4322-9550-0ABA21C3701DQ47093952-F1B743D1-FFF5-4DBF-B121-B3D9DB46909EQ47300615-0B76D9A5-7016-4AD7-983D-C44C03AAC2DFQ47577909-8183BB19-B8B8-40AD-B7EC-FDD7C3C5C094Q47638004-014DFC4B-B0EF-40C1-B101-0D1F9F159B38Q47667602-AE2D955D-FC98-4DA9-93F3-4B631518FA72Q47677386-13384C69-2B64-4F0E-A056-3F8F9394F44AQ47741789-43FE0C1D-E971-4F54-8021-7B999747CF79Q47774123-9380C4FD-BC17-4BBF-BC66-ED9AB09F33DB
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Peter Achermann
@ast
Peter Achermann
@en
Peter Achermann
@es
Peter Achermann
@nl
type
label
Peter Achermann
@ast
Peter Achermann
@en
Peter Achermann
@es
Peter Achermann
@nl
prefLabel
Peter Achermann
@ast
Peter Achermann
@en
Peter Achermann
@es
Peter Achermann
@nl
P1053
N-1215-2014
P106
P21
P31
P496
0000-0002-0208-3511