Cognitive demands and cortical control of human balance-recovery reactions.
about
Age effects on mediolateral balance controlProcessing time of addition or withdrawal of single or combined balance-stabilizing haptic and visual informationCalibration of the Leg Muscle Responses Elicited by Predictable Perturbations of Stance and the Effect of Vision.Changes in cortical activity associated with adaptive behavior during repeated balance perturbation of unpredictable timing.Changes in the activity of the cerebral cortex relate to postural response modification when warned of a perturbationIncreased frontal brain activation during walking while dual tasking: an fNIRS study in healthy young adults.How to improve walking, balance and social participation following stroke: a comparison of the long term effects of two walking aids--canes and an orthosis TheraTogs--on the recovery of gait following acute stroke. A study protocol for a multi-centrContribution of primary motor cortex to compensatory balance reactions.Postural sway and motor control in trans-tibial amputees as assessed by electroencephalography during eight balance training tasks.Contribution of hindpaw cutaneous inputs to the control of lateral stability during walking in the cat.Do aging and dual-tasking impair the capacity to store and retrieve visuospatial information needed to guide perturbation-evoked reach-to-grasp reactions?A qualitative review of balance and strength performance in healthy older adults: impact for testing and training.Corticospinal Excitability of Trunk Muscles during Different Postural TasksNeural Correlates of Task Cost for Stance Control with an Additional Motor Task: Phase-Locked Electroencephalogram ResponsesPostural sway and rhythmic electroencephalography analysis of cortical activation during eight balance training tasks.Extracting kinematic parameters for monkey bipedal walking from cortical neuronal ensemble activityLoss of balance during balance beam walking elicits a multifocal theta band electrocortical response.Timing of reactive stepping among individuals with sub-acute stroke: effects of 'single-task' and 'dual-task' conditions.Specific Stimuli Induce Specific Adaptations: Sensorimotor Training vs. Reactive Balance Training.The use of peripheral vision to guide perturbation-evoked reach-to-grasp balance-recovery reactions.Framework for understanding balance dysfunction in Parkinson's disease.Effect of dual tasking on intentional vs. reactive balance control in people with hemiparetic stroke.Higher Balance Task Demands are Associated with an Increase in Individual Alpha Peak Frequency.Reliability of dynamic balance simultaneously with cognitive performance in patients with ACL deficiency and after ACL reconstructions and in healthy controls.Body Sway Increases After Functional Inactivation of the Cerebellar Vermis by cTBS.Using a dry electrode EEG device during balance tasks in healthy young-adult males: Test-retest reliability analysis.Cortical activity differs between position- and force-control knee extension tasks.Cortical Correlates of Human Balance Control.Electrocortical Sources Related to Whole-Body Surface Translations during a Single- and Dual-Task Paradigm.NeuroControl of movement: system identification approach for clinical benefit.Role of the Frontal Cortex in Standing Postural Sway Tasks While Dual-Tasking: A Functional Near-Infrared Spectroscopy Study Examining Working Memory Capacity.Age-Related Differences in Reorganization of Functional Connectivity for a Dual Task with Increasing Postural DestabilizationWhy we need to better understand the cortical neurophysiology of impaired postural responses with age, disease, or injuryCerebral Hemodynamic Responses During Dynamic Posturography: Analysis with a Multichannel Near-Infrared Spectroscopy System.Gaze Behavior of Older Adults in Responding to Unexpected Loss of Balance while Walking in an Unfamiliar Environment: a Pilot Study.Activation timing of postural muscles of lower legs and prediction of postural disturbance during bilateral arm flexion in older adults.Postural and Cortical Responses Following Visual Occlusion in Adults With and Without ASD.Attentional requirements of postural control in people with spinal cord injury: the effect of dual task.Timings of attentional switching to perturbation and postural preparation during transient forward or backward floor translation.Postural and cortical responses following visual occlusion in standing and sitting tasks.
P2860
Q21131912-9EF74991-72A1-409D-A3CD-BB396187C8AFQ30368791-EB56669A-1CBD-4689-B73D-8A65B4E84F9CQ30374511-AD5D745F-F209-40ED-8332-4B4235AC8121Q30399590-0A2666D0-03A4-400D-B7D7-93DEB74E6EE4Q30489294-4A283628-F7B3-40BF-A5D6-A90A6EFDFA91Q33747055-F9F86B07-7E50-4AD9-8D4B-549D16579727Q34214227-8B7AECDD-D5E5-4693-94F7-7457D0CEF90EQ34381948-2800A3C2-4E88-46A6-B273-5ED25EBD82A2Q34783106-1CAEF465-5177-46EC-8F7E-FBD2760F4CCAQ34992454-6305F68D-7F20-44C7-812A-1D09E5942B70Q35041305-94290BA3-C4BF-418A-85A1-4499295B5ADAQ35725040-AA248456-7B5C-4E38-BE5F-EE284E041D86Q35903052-FB8B5D3C-5E77-4F12-B875-00FD5F93B5A0Q35968881-CDDD5A9F-0F22-4B60-9D3F-E8883FC9BFF9Q36773199-93440F81-50E0-4AE1-B757-3CB2D577154DQ37136691-A57CAD7D-3D7B-475F-92A5-26EF9DE610A4Q37346324-7E28B32C-CEC1-4926-9779-D7FBC7124944Q37405339-37A90A61-1E28-4C4F-A5DF-44395CC94AADQ37468833-AD42B5A2-902A-44C2-B97F-3C3A449C2425Q37482198-1CE8D53E-1359-44BF-8401-F2326DB8F5BFQ37727132-775BD675-CC72-48A9-A635-B8DBE11B5238Q38429502-B19E7C7D-8113-42F2-801B-3BED8E0C517DQ38919554-7134D76B-4EB7-43EF-9897-686E3F5A7822Q39177460-8C9F6646-23D3-43A4-804C-ADB8CBAFC3CBQ40094285-C0E463EA-6E17-4A57-BFE9-B1B1A7312C70Q40540322-E1CA69E5-24C1-46F5-9B2C-DC027C93399AQ40622658-7A85238F-78B3-444B-A5A1-9C6EA5C4558FQ40971502-457B3F34-271F-43F8-920D-1E7408155613Q41481609-57B11866-4B9D-464F-9B9E-6DC8E63DB3D3Q41831751-73E56C91-6D48-4905-95FD-0C3DA9813142Q41894333-F5CFA199-E8F2-4CDB-AC7B-D7139DDC0162Q42070782-1C405978-4ADF-4D56-BEAC-CC5704728574Q42849805-118CD77D-9983-4DDA-8425-19381F794844Q43171682-81F453E6-4D59-4265-B26E-E869B2510BFDQ45824085-0B5A2D80-B050-43E4-BC49-E7E70063A2A9Q47138503-935209ED-D452-4E6E-A9AF-3E0E88F587B0Q47321739-52C1B188-8090-4187-8ED4-57D554EF8CFCQ47721609-586D2F4D-1974-4B11-A786-A2AD013A45C0Q47877952-8B44F576-DB42-4646-8291-798206F574DCQ48113068-A7AFFE9D-3974-42EC-995C-9FF165988F42
P2860
Cognitive demands and cortical control of human balance-recovery reactions.
description
2007 nî lūn-bûn
@nan
2007年の論文
@ja
2007年論文
@yue
2007年論文
@zh-hant
2007年論文
@zh-hk
2007年論文
@zh-mo
2007年論文
@zh-tw
2007年论文
@wuu
2007年论文
@zh
2007年论文
@zh-cn
name
Cognitive demands and cortical control of human balance-recovery reactions.
@en
type
label
Cognitive demands and cortical control of human balance-recovery reactions.
@en
prefLabel
Cognitive demands and cortical control of human balance-recovery reactions.
@en
P2860
P1476
Cognitive demands and cortical control of human balance-recovery reactions.
@en
P2093
P2860
P2888
P304
P356
10.1007/S00702-007-0764-Y
P577
2007-06-08T00:00:00Z