연구동향 분석

Walkbot robot-assisted gait training effects in posture, gait, balance, spasticity, and brain activities in individuals with cerebral palsy

황종석 2020년

논문상세정보
인용/피인용
' Walkbot robot-assisted gait training effects in posture, gait, balance, spasticity, and brain activities in individuals with cerebral palsy' 의 주제별 논문영향력
논문영향력 선정 방법
논문영향력 요약
주제
  • 10 미터 보행검사
  • 10-minute walking test
  • Cerebral palsy
  • EEG frequency band power
  • Electroencephalography
  • Gait cycle event-related spectral perturbations
  • Gross motor function measure-88
  • Pediatric balance scale
  • Robot-assisted gait training
  • Topography
  • 근전도
  • 뇌성마비
  • 뇌전도
  • 뇌전도 지도
  • 대뇌피질 밴드 파워
  • 대동작 기능평가도구
  • 로봇보행훈련
  • 보행위상관련 스펙트럴 섭동
  • 아동 균형 척도
동일주제 총논문수 논문피인용 총횟수 주제별 논문영향력의 평균
532 0

0.0%

' Walkbot robot-assisted gait training effects in posture, gait, balance, spasticity, and brain activities in individuals with cerebral palsy' 의 참고문헌

  • specific training : evidence for and translation toClinical practice
    16 ( 3 ? 4 ) :175-189 [2009]
  • Xiong L. Reliability of a new scale for measurement of spasticity in stroke patients
    46 ( 8 ) :746-753 [2014]
  • Voluntary muscle activation , contractile properties , and fatigability in children with and without cerebral palsy
    31 ( 5 ) :594-601 . [2005]
  • Validity of pediatric balance scales in children with spastic cerebral palsy
    43 ( 6 ) :307-313 . [2012]
  • Validity , responsiveness , minimal detectable change , and minimal clinically important change of Pediatric Balance Scale in children with cerebral palsy
    34 ( 3 ) :916-922 . [2013]
  • Tsorbatzoudis C. Effect of intensive neurodevelopmental treatment in gross motor function of children with cerebral palsy
    46 ( 11 ) :740-745 . [2004]
  • The motor cortex drives the muscles during walking in human subjects
    590 ( 10 ) : 2443-2452 . [2012]
  • The effects of strength training on gait in adolescents with cerebral palsy .
    16 ( 1 ) :22-30 . [2004]
  • Teasell R. The role of task-specific training in rehabilitation therapies
    12 ( 3 ) :58-65 . [2005]
  • Tarakc©¥ E. Effect of robot assisted gait training on motor performance in cerebral palsy : a pilot study .
    6 ( 3 ) :156-162 . [2019]
  • Structural and functional improvements due to robot-assisted gait training in the stroke-injured brain
    637:114-119 [2017]
  • Spatial-Spectral Identification Of Mu And Beta Eeg Rhythm Sourcrs During Robot-Assisted Walking
    58 ( 1 ) :293-312 . [2013]
  • Should we be testing and training muscle strength inCerebral palsy ?
    44 ( 1 ) :68-72 . [2002]
  • Shin YI . Effects of Innovative WALKBOT Robotic-Assisted Locomotor Training on Balance and Gait Recovery in Hemiparetic Stroke : A Prospective , Randomized , Experimenter BlindedCaseControl Study With
    . 2015 ; 23 ( 4
  • Sensory and motor deficits inChildren withCerebral palsy born pretermCorrelate with diffusion tensor imaging abnormalities in thalamocortical pathways
    51 ( 9 ) :697-704 . [2009]
  • Selber P. Musculoskeletal aspects ofCerebral palsy
    volume .85 ( 2 ) :157-166 [2003]
  • Schurr K. Exercise dose and mobility outcome in aComprehensive stroke unit : description and prediction from a prospectiveCohort study
    44 ( 10 ) :824-829 [2012]
  • Scherer R. Level of participation in robotic-assisted treadmill walking modulates midline sensorimotor EEG rhythms in able-bodied subjects
    63 ( 3 ) :1203-1211 . [2012]
  • Ryu J. Force/torque sensorless impedanceControl for indirect driven robot-aided gait rehabilitation system .
    652-657 [2015]
  • Rusch-BohtzC. Robot-assisted gait training might be beneficial for more severely affectedChildren withCerebral palsy
    19 ( 6 ) :410-415 . [2016]
  • Robot-assisted andComputer-enhanced therapies forChildren withCerebral palsy :Current state andClinical implementation
    20 ( 2 ) :139-145 . [2013]
  • Riener R. Patient-cooperativeControl increases active participation of individuals with SCI during robot-aided gait training
    7 ( 1 ) :43-50 . [2010]
  • Riener R. A novel method for automatic treadmill speed adaptation .
    15 ( 3 ) :401-409 . [2007]
  • Reducing robotic guidance during robot-assisted gait training improves gait function : aCase report on a stroke survivor
    94 ( 6 ) :1202-1206 . [2013]
  • Recalibration of inhibitoryControl systems during walking-related dual-task interference : a mobile brain-body imaging ( MOBI ) study
    94:55-64 . [2014]
  • R. Modulation of leg muscle activity and gait kinematics by walking speed and bodyweight unloading .
    24 ( 1 ) : 35-45 . [2006]
  • ProspectiveControlledCohort study to evaluateChanges of function , activity and participation in patients with bilateral spasticCerebral palsy after Robot-enhanced repetitive treadmill therapy
    18 ( 4 ) :502-510 . [2014]
  • Pringsheim T. An update on the prevalence ofCerebral palsy : a systematic review and meta-analysis .
    55 ( 6 ) :509-519 . [2013]
  • Prefrontal , posterior parietal and sensorimotor network activity underlying speedControl during walking
    9 : 247-261 . [2015]
  • Poizner H. Linking brain , mind and behavior
    73 ( 2 ) :95-100 . [2009]
  • Pediatric balance scale : a modified version of the berg balance scale for the school-age child with mild to moderate motor impairment
    15 ( 2 ) :114-128 [2003]
  • Newton R. Genetic aspects of cerebral palsy
    34 ( 1 ) :80-86 . [1992]
  • Neuromuscular activation and motor-unit firing characteristics in cerebral palsy .
    47 ( 5 ) :329-336 . [2005]
  • Muller-Putz G. It 's how you get there : walking down a virtual alley activates premotor and parietal areas
    8:93-106 . [2014]
  • Muller-Putz G. Distinct ¥â band oscillatory networks subserving motor and cognitive control during gait adaptation .
    36 ( 7 ) :2212-2226 . [2016]
  • Motor adaptation to single force pulses : sensitive to direction but insensitive to within-movement pulse placement and magnitude
    96 ( 2 ) :710-720 . [2006]
  • Meyer-Heim A. Robotic-assisted treadmill therapy improves walking and standing performance in children and adolescents with cerebral palsy
    14 ( 6 ) :496-502 . [2010]
  • Meeusen R. Human-Robot Interaction : Does Robotic Guidance Force Affect Gait-Related Brain Dynamics during Robot-Assisted Treadmill Walking ?
    10 ( 10 ) :140-162 .. [2015]
  • Makeig S. Cognition in action : imaging brain/body dynamics in mobile humans .
    22 ( 6 ) :593-608 . [2011]
  • M. Reliability and Responsiveness of the Gross Motor Function Measure88 in Children With Cerebral Palsy
    93 ( 7 ) .129-158 [2012]
  • Lichtwark G. Medial gastrocnemius muscle fascicle active torquelength and Achilles tendon properties in young adults with spastic cerebral palsy
    45 ( 15 ) :2526-2530 . [2012]
  • Li X. Test-retest reliability and inter-rater reliability of the Modified Tardieu Scale and the Modified Ashworth Scale in hemiplegic patients with stroke
    50 ( 1 ) :9-15 [2014]
  • Leahey L. Contributing factors to muscle weakness in children with cerebral palsy
    45 ( 8 ) :542-550 . [2003]
  • Improvement of walking abilities after robotic-assisted locomotion training in children with cerebral palsy
    94 ( 8 ) :615-620 . [2009]
  • Immediate effect of Walkbot robotic gait training on neuromechanical knee stiffness in spastic hemiplegia : a case report
    32 ( 4 ) :833-838 . [2013]
  • Hudspith K. De novo point mutations in patients diagnosed with ataxic cerebral palsy .
    138 ( 7 ) :1817-1832 . [2015]
  • Hudspith K. De novo point mutations in patients diagnosed with ataxic cerebral palsy
    [2016]
  • High and low gamma EEG oscillations in central sensorimotor areas are conversely modulated during the human gait cycle
    112:318-326 [2015]
  • Hesse S. Treadmill training with partial body weight support in nonambulatory patients with cerebral palsy
    81 ( 3 ) :301-306 . [2000]
  • Heinen F. Feasibility of robotic ? assisted locomotor training in children with central gait impairment
    49 ( 12 ) :900-906 [2007]
  • Hagg G. European recommendations for surface electromyography .
    8 ( 2 ) :13-54 . [1999]
  • Gross Motor Function Measure ( GMFM-66 and GMFM-88 ) Users¡¯ Manual
    34 ( 3 ) :341-342 . [2014]
  • Graham H. Walking speed in children and young adults with neuromuscular disease : comparison between two assessment methods
    23 ( 3 ) :302-307 . [2003]
  • Gnip C. Counting repetitions : an observational study of outpatient therapy for people with hemiparesis post-stroke
    31 ( 1 ) :3-10 . [2007]
  • Function and well-being in ambulatory children with cerebral palsy
    26 ( 1 ) :119-124 . [2006]
  • Foley S. Partial body ? weight ? supported treadmill training can improve walking in children with cerebral palsy : a clinical controlled trial
    49 ( 2 ) :101-105 . [2007]
  • Explicit information interferes with implicit motor learning of both continuous and discrete movement tasks after stroke
    30 ( 2 ) :46-57 . [2006]
  • Evaluation of spasticity in children with cerebral palsy using Ashworth and Tardieu Scales compared with laboratory measures .
    25 ( 10 ) :1242-1247 . [2010]
  • Elger C. The ten-twenty electrode system of the International Federation . The International Federation of Clinical Neurophysiology
    52:3-6 [1999]
  • Effects of walkbot gait training on kinematics , kinetics , and clinical gait function in paraplegia and quadriplegia
    42 ( 4 ) :481-489 . [2018]
  • EEG beta suppression and low gamma modulation are different elements of human upright walking
    8:485-498 [2014]
  • DyhrePoulsen P. Neural inhibition during maximal eccentric and concentric quadriceps contraction : effects of resistance training
    89 ( 6 ) : 2249-2257 . [2000]
  • Duysens J. Feasibility of measuring event related desynchronization with electroencephalography during walking
  • Duschau-Wicke A. Feasibility and effects of patient-cooperative robot-aided gait training applied in a 4-week pilot trial
    9:31-39 [2012]
  • Dockery P. Fitzgerald 's Clinical Neuroanatomy and Neuroscience E-Book
    [2015]
  • Comparative effects of robotic-assisted gait training combined with conventional physical therapy on paretic hip joint stiffness and kinematics between subacute and chronic hemiparetic stroke
    42 ( 2 ) :181-190 . [2018]
  • Burnfield J. Gait analysis : normal and pathological function
    [2010]
  • Bredin J. Robotic-assisted gait training improves walking abilities in diplegic children with cerebral palsy
    21 ( 3 ) :557-564 . [2017]
  • Behrmann M. Very high density EEG elucidates spatiotemporal aspects of early visual processing
    7 ( 1 ) :1-11 . [2017]
  • Bartolo M. Improvement of motor performance in children with cerebral palsy treated with exoskeleton robotic training : A retrospective explorative analysis
    2:10-16 [2019]
  • Assist-as-needed robot-aided gait training improves walking function in individuals following stroke
    23 ( 6 ) :956-963 . [2014]
  • Adaptive impedance control of a robotic orthosis for gait rehabilitation
    43 ( 3 ) :1025-1034 . [2013]
  • Ada L. The Tardieu Scale differentiates contracture from spasticity whereas the Ashworth Scale is confounded by it
    20 ( 2 ) :173-182 . [2006]