Suppression of EMG activity by transcranial magnetic stimulation in human subjects during walking
about
Cortical Spectral Activity and Connectivity during Active and Viewed Arm and Leg Movement.Automaticity of walking: functional significance, mechanisms, measurement and rehabilitation strategiesWalking adaptability after a stroke and its assessment in clinical settings.Locomotor sequence learning in visually guided walking.Towards effective non-invasive brain-computer interfaces dedicated to gait rehabilitation systems.How we walk: central control of muscle activity during human walking.Perceiving what is reachable depends on motor representations: evidence from a transcranial magnetic stimulation studySubcortical control of precision grip after human spinal cord injury.Merging of healthy motor modules predicts reduced locomotor performance and muscle coordination complexity post-strokeAdopting an external focus of attention alters intracortical inhibition within the primary motor cortexTranspinal and transcortical stimulation alter corticospinal excitability and increase spinal output.Ankle dorsiflexion as an fMRI paradigm to assay motor control for walking during rehabilitation.Time to task failure and motor cortical activity depend on the type of feedback in visuomotor tasks.Sensorimotor integration at spinal level as a basis for muscle coordination during voluntary movement in humans.Robust growth of human immunodeficiency virus type 1 (HIV-1)Volitional muscle strength in the legs predicts changes in walking speed following locomotor training in people with chronic spinal cord injuryExcitability changes in intracortical neural circuits induced by differentially controlled walking patterns.Rehabilitation of gait after stroke: a review towards a top-down approach.A novel fMRI paradigm suggests that pedaling-related brain activation is altered after strokeOrganisation of the motor cortex differs between people with and without knee osteoarthritisInfant stepping: a window to the behaviour of the human pattern generator for walking.The effects of experimental knee pain on lower limb corticospinal and motor cortex excitabilityPlasticity of corticospinal neural control after locomotor training in human spinal cord injurySymmetry of corticomotor input to plantarflexors influences the propulsive strategy used to increase walking speed post-stroke.Spinal and brain control of human walking: implications for retraining of walking.Recent advances in functional neuroimaging of gait.A common neural element receiving rhythmic arm and leg activity as assessed by reflex modulation in arm muscles.Persons with Parkinson's disease exhibit decreased neuromuscular complexity during gait.Synchronous EMG activity in the piper frequency band reveals the corticospinal demand of walking tasks.Associations between prefrontal cortex activation and H-reflex modulation during dual task gait.Patterned control of human locomotion.Corticospinal responses to sustained locomotor exercises: moving beyond single-joint studies of central fatigue.Noninvasive Neuromodulation in Poststroke Gait Disorders: Rationale, Feasibility, and State of the Art.Supraspinal Control Predicts Locomotor Function and Forecasts Responsiveness to Training after Spinal Cord Injury.Corticospinal and reciprocal inhibition actions on human soleus motoneuron activity during standing and walkingPhase- and Workload-Dependent Changes in Corticospinal Excitability to the Biceps and Triceps Brachii during Arm Cycling.Cadence-dependent changes in corticospinal excitability of the biceps brachii during arm cycling.Downregulating Aberrant Motor Evoked Potential Synergies of the Lower Extremity Post Stroke During TMS of the Contralesional Hemisphere.Gait acts as a gate for reflexes from the foot.Childhood development of common drive to a human leg muscle during ankle dorsiflexion and gait.
P2860
Q27313017-EE8654B3-03B5-4F59-AFF7-BCAC3F57C536Q28084858-14654213-B0F6-40BA-A5C3-1683D1BC38A4Q30430277-1618DE11-E9CF-4CF8-B1D9-67672358B4B2Q30758152-77DC2EB1-2249-4BDB-801C-DD01C69C783AQ30833207-F705F6E8-A1E9-4FE5-803D-DE652CF5EACDQ30919486-84A10A04-8882-4BBB-8704-CE8212B213D0Q33358137-B0A3FFD1-B966-49E1-8EA4-A99A52FE2344Q33639529-D4ADC97B-7D0F-4D45-AA2F-4C012B5A14B7Q33656898-D855D7B4-A2FF-451D-B4CA-45B41AE7F75BQ33834204-9B08A4B4-86EC-45E6-BC5C-C21FB757F03FQ33875188-2675207D-85FD-4F2A-9890-129AE5131DD5Q34181895-525F96F6-79CF-49BB-B343-77DA97CEDA84Q34199811-DE720AA6-8712-47C1-8033-96AAC0F2E27DQ34312360-C9A1F4E1-0CB0-44F9-A6AF-F4E9633DD63EQ34351276-D58AF8CC-8D59-40D6-8295-C5FB92A095BAQ35022484-F24FCD14-B5A7-476C-A033-75328CA05617Q35562579-CB0FB5A5-273C-4A1A-B13E-9F175329B251Q35680299-5D452CB9-A9C6-4567-883F-8E7B5DE2B4CCQ35681095-8B13EE56-0687-4F4D-96F1-FFE9592E3DBFQ35828208-68C80F0B-6E60-4192-BD81-DBDB17CEE7F5Q35938046-D81FEE69-D377-47E2-A12D-50A5B95AD4E3Q35945876-AFD1B171-B484-422B-851C-240BAB16F9BDQ36026618-D4944BCA-9E68-4B51-A830-55D25A14BD4BQ36578660-1A46699F-B6A0-4B5E-ACC1-4E7B58CBACEFQ36587178-9A1218D1-D110-4E05-9CD4-CE3CC3825EA5Q36876056-FA926FAD-D255-4BB9-8B48-4E3AE9B3F90AQ36907697-46E4764B-8643-4143-BBFA-E7267A2884B0Q36920073-C9D5E369-549D-4806-A6E4-CDAEB82D6736Q37051126-A4A4CB52-52EF-431D-83EE-FDACC6F8D862Q37589396-5476E87B-7245-4D30-84EA-0B897C0B249DQ37992865-C5DB9C4F-28AD-488C-95D3-D21CACDE9A78Q38086112-A276BEE3-5379-4540-8079-9952AD12F556Q38476216-C376229A-F9E2-4AF2-BE61-A689E468F58FQ38817244-C8E847F8-F9BF-4D23-9BB9-DC19D79737E9Q39508999-002FAFF7-AF55-4875-82C8-6E8363B5F5FEQ39927414-8F7CC545-357D-4437-B760-EC0444C613B2Q40626284-ED2EB383-8E81-4BC0-B478-2CB4A2BEFA9CQ42566702-51C7D373-0A95-4CD0-9580-B5F489656C0AQ42639613-3A322BDD-E8C8-4E9A-AE4F-439642809A60Q42908858-D4A4AEEE-08D6-46E9-A2A4-3168B3989755
P2860
Suppression of EMG activity by transcranial magnetic stimulation in human subjects during walking
description
2001 nî lūn-bûn
@nan
2001 թուականի Դեկտեմբերին հրատարակուած գիտական յօդուած
@hyw
2001 թվականի դեկտեմբերին հրատարակված գիտական հոդված
@hy
2001年の論文
@ja
2001年論文
@yue
2001年論文
@zh-hant
2001年論文
@zh-hk
2001年論文
@zh-mo
2001年論文
@zh-tw
2001年论文
@wuu
name
Suppression of EMG activity by ...... human subjects during walking
@ast
Suppression of EMG activity by ...... human subjects during walking
@en
Suppression of EMG activity by ...... human subjects during walking
@nl
type
label
Suppression of EMG activity by ...... human subjects during walking
@ast
Suppression of EMG activity by ...... human subjects during walking
@en
Suppression of EMG activity by ...... human subjects during walking
@nl
prefLabel
Suppression of EMG activity by ...... human subjects during walking
@ast
Suppression of EMG activity by ...... human subjects during walking
@en
Suppression of EMG activity by ...... human subjects during walking
@nl
P2093
P2860
P50
P1476
Suppression of EMG activity by ...... human subjects during walking
@en
P2093
N L Hansen
V Marchand-Pauvert
P2860
P304
P356
10.1111/J.1469-7793.2001.00651.X
P407
P577
2001-12-01T00:00:00Z