about
A physiologically based model of orexinergic stabilization of sleep and wakeDiversity and noise effects in a model of homeostatic regulation of the sleep-wake cycleAdaptation to shift work: physiologically based modeling of the effects of lighting and shifts' start time.Physiological Markers of Arousal Change with Psychological Treatment for Insomnia: A Preliminary Investigation.Neural synchronization at tonic-to-bursting transitions.A mathematical model of homeostatic regulation of sleep-wake cycles by hypocretin/orexin.Neuronal mechanisms of shift workers’ sleepiness.Modeling neuronal activity in relation to experimental voltage-/patch-clamp recordings.Sleep Propensity under Forced Desynchrony in a Model of Arousal State Dynamics.Effects of rotation interval on sleepiness and circadian dynamics on forward rotating 3-shift systems.A minimal physiologically based model of the HPA axis under influence of the sleep-wake cycles.Exploring sleepiness and entrainment on permanent shift schedules in a physiologically based model.A computational study of the interdependencies between neuronal impulse pattern, noise effects and synchronization.Noise-induced precursors of tonic-to-bursting transitions in hypothalamic neurons and in a conductance-based model.A unified model of melatonin, 6-sulfatoxymelatonin, and sleep dynamics.Neurones and synapses for systemic models of psychiatric disorders.Propagation effects of current and conductance noise in a model neuron with subthreshold oscillations.Spiking patterns and synchronization of thalamic neurons along the sleep-wake cyclePrediction of Cognitive Performance and Subjective Sleepiness Using a Model of Arousal DynamicsImpulse pattern in bi-directionally coupled model neurons of different dynamicsA Multiscale “Working Brain” ModelThe effect of consecutive transmeridian flights on alertness, sleep-wake cycles and sleepiness: A case studyWhat works for jetlag? A systematic review of non-pharmacological interventionsGeneralizability of A Neural Network Model for Circadian Phase Prediction in Real-World Conditions
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Q30441208-25637B97-7BB6-45F6-920D-5AE5C99F1AEBQ34395221-4FF7191A-66B3-4FD5-90C0-4E86201EC4B4Q34544984-583BD921-0C6C-409D-BB63-CCD6A525E1E3Q35873135-58CE139B-59A4-4A73-BF6F-1194B54162D9Q43176705-14F81ABF-9A1F-43C3-8626-ABB838FF78F1Q43238373-8574D2A4-2B55-4C37-9E9E-F64A73544783Q46069683-40FA07CA-8C0B-4B60-9F41-85AE45311263Q46898507-2C5C105C-CBFC-4C54-905D-48DC388F910EQ47835783-F0F1E73D-C454-4B4F-BF20-47D9E40D8D07Q48127794-B9C3E4F2-80FE-435B-A410-6918CD9C8985Q48181551-144A4929-2CF6-4BFE-AC7E-6C973498C23CQ48260220-97823D5D-E2DE-4247-A5BD-B75710952E0FQ48380350-E69819F0-837E-4254-8144-098B3202CD0BQ48724351-39839756-FE5B-405E-8324-0C7169D7FF31Q50045595-C7FE7D0B-BCBC-44A6-9A11-55E6746227EDQ51850985-2AA47FAE-F16C-4099-BF63-5FC4794A8483Q51887011-81606E19-6146-49B2-8823-1813DAE5C7D1Q59195800-CDDD3DCA-085E-48E8-B83D-5C383B34B90AQ59195804-DC393B15-F370-4D82-9EBE-D59C39507996Q59195849-3E52A196-C3E0-461A-9218-98EFA80784A8Q61606610-C5DF58FA-055E-42C5-B087-62813B2F4CEDQ89546927-87A6FAE9-BD9C-4632-B87E-6069E22521FDQ90358041-5DD6D79A-7661-492B-B98A-5218FB79CEECQ92265973-456EF7B4-1472-4284-8B3A-F3FF01DC666A
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description
hulumtuese
@sq
onderzoeker
@nl
researcher
@en
ricercatrice
@it
հետազոտող
@hy
name
Svetlana Postnova
@ast
Svetlana Postnova
@en
Svetlana Postnova
@es
Svetlana Postnova
@sl
type
label
Svetlana Postnova
@ast
Svetlana Postnova
@en
Svetlana Postnova
@es
Svetlana Postnova
@sl
prefLabel
Svetlana Postnova
@ast
Svetlana Postnova
@en
Svetlana Postnova
@es
Svetlana Postnova
@sl
P214
P106
P1153
16246530300
P21
P213
0000 0000 7740 2754
P214
P31
P496
0000-0002-1224-0779
P735
P7859
viaf-107650467