Psychophysiological mechanisms of interindividual differences in goal activation modes during action cascading.
about
Improvements of sensorimotor processes during action cascading associated with changes in sensory processing architecture-insights from sensory deprivation.Action Video Gaming and Cognitive Control: Playing First Person Shooter Games Is Associated with Improved Action Cascading but Not Inhibition.Feeling safe in the plane: neural mechanisms underlying superior action control in airplane pilot trainees--a combined EEG/MRS studyThe importance of sensory integration processes for action cascading.Neurophysiological mechanisms of circadian cognitive control in RLS patients - an EEG source localization study.Neuronal Intra-Individual Variability Masks Response Selection Differences between ADHD Subtypes-A Need to Change PerspectivesOn the effects of multimodal information integration in multitasking.Psychophysiological mechanisms underlying response selection in multidimensional space.γ-Aminobutyric acid (GABA) administration improves action selection processes: a randomised controlled trial.How Life Experience Shapes Cognitive Control Strategies: The Case of Air Traffic Control Training.Conscientiousness increases efficiency of multicomponent behaviorDifferent strategies, but indifferent strategy adaptation during action cascading.Questioning the role of the frontopolar cortex in multi-component behavior--a TMS/EEG study.Single-subject prediction of response inhibition behavior by event-related potentials.Behavioral and neurophysiological evidence for increased cognitive flexibility in late childhood.The neuronal mechanisms underlying improvement of impulsivity in ADHD by theta/beta neurofeedback.Response inhibition in Attention deficit disorder and neurofibromatosis type 1 - clinically similar, neurophysiologically different.Conflict processing in juvenile patients with neurofibromatosis type 1 (NF1) and healthy controls - Two pathways to success.Humans with latent toxoplasmosis display altered reward modulation of cognitive controlEvidence for enhanced multi-component behaviour in Tourette syndrome - an EEG study.ADHD patients fail to maintain task goals in face of subliminally and consciously induced cognitive conflicts.Neural mechanisms and functional neuroanatomical networks during memory and cue-based task switching as revealed by residue iteration decomposition (RIDE) based source localization.Dysfunctions in striatal microstructure can enhance perceptual decision making through deficits in predictive coding.Working memory load affects repetitive behaviour but not cognitive flexibility in adolescent autism spectrum disorder.Blocking effects in non-conditioned goal-directed behaviour.Are multitasking abilities impaired in welders exposed to manganese? Translating cognitive neuroscience to neurotoxicology.On the dependence of response inhibition processes on sensory modality.Effects of high-dose ethanol intoxication and hangover on cognitive flexibility.The norepinephrine system affects specific neurophysiological subprocesses in the modulation of inhibitory control by working memory demands.Effects of multisensory integration processes on response inhibition in adolescent autism spectrum disorder.Effects of binge drinking and hangover on response selection sub-processes-a study using EEG and drift diffusion modeling.Perceptual conflict during sensorimotor integration processes - a neurophysiological study in response inhibitionEffects of copper toxicity on response inhibition processes: a study in Wilson's disease.Reversal of alcohol-induced effects on response control due to changes in proprioceptive information processing.Mammalian cadherins DCHS1-FAT4 affect functional cerebral architecture.Deep brain stimulation in the globus pallidus compensates response inhibition deficits: evidence from pantothenate kinase-associated neurodegeneration.A causal role of the right inferior frontal cortex in implementing strategies for multi-component behaviour.Self-Regulatory Capacities Are Depleted in a Domain-Specific Manner.On the relevance of the alpha frequency oscillation's small-world network architecture for cognitive flexibilityNeurophysiological variability masks differences in functional neuroanatomical networks and their effectiveness to modulate response inhibition between children and adults.
P2860
Q27335931-25E81801-691C-4114-B559-8C180028E1F8Q30395183-A3CB1CC1-5FA3-475B-871A-5D8A8C4D617EQ30401851-A8B9CC36-2EAB-4C25-A09C-11AC96FCA546Q30414827-ECAFCA2C-408D-42A0-A61C-789446417EB6Q33823013-C088998D-E5D4-49D1-A850-D6E6CED4DBB1Q33843096-EA575D7A-13D7-4928-B336-F950008EBA45Q33884805-F7CB9CF8-D79E-4721-9C9B-3B786B852EDDQ34925182-D97343BE-6982-47DF-85A5-7C68776044B2Q35905868-4ABDDD70-9404-4845-A1F2-564A73504653Q36054522-5B0C9AEC-A0ED-44E8-B12F-E5553A213703Q36209601-80B861A0-2FAB-4F18-A8B5-C51A95AD17A4Q36292388-E062E077-152B-4C6C-87EC-48DD80DA8E13Q36628595-9C9AC547-A622-4F9E-BCF8-4934B3F48B55Q36729810-4E4F29B5-C0FC-4426-BD2A-1A4FE901C6F4Q37044595-51D09C08-E434-4D0B-84B7-838FA76D7588Q37169094-92C3D4DF-714E-4A79-A547-FA910BE28250Q37682078-1A6246D7-6341-4216-A12A-7E42B4C88B3EQ37682749-2EFBFEEE-1B00-4B4F-9B03-DA0CF8046FCEQ38599056-B4FDAEBE-4AD6-4C9A-89CD-0A65E99E60E1Q38629711-80B7BBC0-806A-4A8B-8221-83916EC2944FQ38739666-6973A564-E8FE-46E9-B8FF-9A4098C05A6EQ38805644-C97B01D6-5E82-4EAB-892D-64AD6F183A9CQ38807658-6F4F859A-7EE5-463E-A6E5-423747001AC1Q38904073-4B343482-D983-41ED-B41C-6508227A12DBQ38961254-8C09F696-A95A-4202-9DF8-9EB57E5661F0Q38979813-29B6D6AB-4C13-46DA-B97F-998382F2B861Q39043405-AE7C4A92-2F3F-4F4E-A25F-C868E8BCD49EQ39240154-0D9B4C99-F996-4FAA-8CA9-F557AB3EAE01Q39494723-06D6972E-6E38-407A-90EE-A68B06B86099Q39593851-E72DCFF6-F1FC-424B-BE7E-C011C49523A5Q39726911-BB84743D-CD8C-44FC-9E02-4DF68AFA2778Q39738254-41119096-F1A7-4045-9624-0A9C108BAEAEQ40464829-D93A23BC-1D3C-4773-9562-5DE3542F8DAFQ40551205-FA4E1CF9-6B64-4F6C-8F6E-87D5344BD357Q40991126-B6E82EB8-709D-4B36-8024-F62C876817DDQ41093586-ABE68796-BEBB-4CFE-BDFA-9D7E71EE6859Q41104270-11FA93A7-8498-4492-96CD-05FB3921EB30Q42369101-995B449B-8091-4A03-B045-04613D648DE4Q42639344-25662A13-0ADA-4F0B-A4D7-183B0DFBC5A2Q47326109-380D629C-AD4B-433F-866E-62C0928E75DC
P2860
Psychophysiological mechanisms of interindividual differences in goal activation modes during action cascading.
description
2013 nî lūn-bûn
@nan
2013年の論文
@ja
2013年学术文章
@wuu
2013年学术文章
@zh
2013年学术文章
@zh-cn
2013年学术文章
@zh-hans
2013年学术文章
@zh-my
2013年学术文章
@zh-sg
2013年學術文章
@yue
2013年學術文章
@zh-hant
name
Psychophysiological mechanisms ...... modes during action cascading.
@en
Psychophysiological mechanisms ...... modes during action cascading.
@nl
type
label
Psychophysiological mechanisms ...... modes during action cascading.
@en
Psychophysiological mechanisms ...... modes during action cascading.
@nl
prefLabel
Psychophysiological mechanisms ...... modes during action cascading.
@en
Psychophysiological mechanisms ...... modes during action cascading.
@nl
P2093
P2860
P356
P1433
P1476
Psychophysiological mechanisms ...... modes during action cascading.
@en
P2093
Ann-Kathrin Stock
Christian Beste
Moritz Mückschel
P2860
P304
P356
10.1093/CERCOR/BHT066
P577
2013-03-14T00:00:00Z