| review article | Q7318358 |
| scholarly article | Q13442814 |
| P50 | author | Janne M Veerbeek | Q56925140 |
| Gert Kwakkel | Q67102623 | ||
| P2093 | author name string | Steven L Wolf | |
| Erwin E H van Wegen | |||
| P2860 | cites work | Constraint-induced movement therapy for upper extremities in stroke patients | Q24240204 |
| Are we ready for a natural history of motor learning? | Q24633804 | ||
| Remodeling the brain: plastic structural brain changes produced by different motor therapies after stroke | Q24647483 | ||
| Systematic review of the empirical evidence of study publication bias and outcome reporting bias - an updated review | Q26851424 | ||
| Global and regional burden of stroke during 1990-2010: findings from the Global Burden of Disease Study 2010 | Q27015585 | ||
| Modified constraint-induced therapy after subacute stroke: a preliminary study | Q28201980 | ||
| An operant approach to rehabilitation medicine: overcoming learned nonuse by shaping | Q28252645 | ||
| Combined botulinum toxin type A with modified constraint-induced movement therapy for chronic stroke patients with upper extremity spasticity: a randomized controlled study | Q28257329 | ||
| Barriers to the implementation of constraint-induced movement therapy into practice | Q28262465 | ||
| Effect of constraint-induced movement therapy on upper extremity function 3 to 9 months after stroke: the EXCITE randomized clinical trial | Q28271402 | ||
| Motor cortex plasticity during constraint-induced movement therapy in stroke patients | Q28278973 | ||
| Constraint-induced movement therapy following stroke: A systematic review of randomised controlled trials | Q30462953 | ||
| Effectiveness of constraint-induced movement therapy on activity and participation after stroke: a systematic review and meta-analysis of randomized controlled trials | Q30476808 | ||
| Constraint-Induced Movement Therapy Compared to Dose-Matched Interventions for Upper-Limb Dysfunction in Adult Survivors of Stroke: A Systematic Review with Meta-analysis | Q30477180 | ||
| Stroke rehabilitation | Q30555764 | ||
| Meta-analysis of individual participant data: rationale, conduct, and reporting | Q33530020 | ||
| Functional neuroimaging studies of early upper limb recovery after stroke: a systematic review of the literature | Q33571270 | ||
| Early exclusive use of the affected forelimb after moderate transient focal ischemia in rats : functional and anatomic outcome | Q73746637 | ||
| Efficacy of modified constraint-induced movement therapy in chronic stroke: a single-blinded randomized controlled trial | Q76360741 | ||
| Movements in monkeys with deafferented forelimbs | Q76486955 | ||
| Modified constraint induced therapy: a randomized feasibility and efficacy study | Q77320534 | ||
| A randomized controlled trial of modified constraint-induced movement therapy for elderly stroke survivors: changes in motor impairment, daily functioning, and quality of life | Q79829469 | ||
| Impact of time on improvement of outcome after stroke | Q80165392 | ||
| Effects of modified constraint-induced movement therapy on movement kinematics and daily function in patients with stroke: a kinematic study of motor control mechanisms | Q80547919 | ||
| Kinematic and clinical analyses of upper-extremity movements after constraint-induced movement therapy in patients with stroke: a randomized controlled trial | Q80747478 | ||
| Short- and long-term outcome of constraint-induced movement therapy after stroke: a randomized controlled feasibility trial | Q81163341 | ||
| Modified constraint-induced therapy in acute stroke: a randomized controlled pilot study | Q81325800 | ||
| Effectiveness of constraint-induced movement therapy in chronic stroke patients | Q81636355 | ||
| Effectiveness of modified constraint-induced movement therapy on upper limb function in stroke subjects | Q81658389 | ||
| Presence of finger extension and shoulder abduction within 72 hours after stroke predicts functional recovery: early prediction of functional outcome after stroke: the EPOS cohort study | Q82957746 | ||
| Brain reorganization after bilateral arm training and distributed constraint-induced therapy in stroke patients: a preliminary functional magnetic resonance imaging study | Q83102351 | ||
| Bobath Concept versus constraint-induced movement therapy to improve arm functional recovery in stroke patients: a randomized controlled trial | Q83275311 | ||
| Shortened constraint-induced movement therapy in subacute stroke - no effect of using a restraint: a randomized controlled study with independent observers | Q83398623 | ||
| A modified method for constraint-induced movement therapy: a supervised self-training protocol | Q84149729 | ||
| Comparison of conventional therapy, intensive therapy and modified constraint-induced movement therapy to improve upper extremity function after stroke | Q84169830 | ||
| Potential effectiveness of three different treatment approaches to improve minimal to moderate arm and hand function after stroke--a pilot randomized clinical trial | Q84592498 | ||
| Pilot trial of distributed constraint-induced therapy with trunk restraint to improve poststroke reach to grasp and trunk kinematics | Q84920007 | ||
| Comparison of constraint-induced movement therapy and bilateral treatment of equal intensity in people with chronic upper-extremity dysfunction after cerebrovascular accident | Q84998723 | ||
| Randomized trial of distributed constraint-induced therapy versus bilateral arm training for the rehabilitation of upper-limb motor control and function after stroke | Q85196397 | ||
| Effects of modified constraint induced therapy on upper limb function in subacute stroke patients | Q86047626 | ||
| Motor recovery of the ipsilesional upper limb in subacute stroke | Q86998428 | ||
| Estimating minimal clinically important differences of upper-extremity measures early after stroke | Q33640678 | ||
| Prediction of recovery of motor function after stroke | Q33733906 | ||
| Rehabilitation of brain damage: brain plasticity and principles of guided recovery | Q33733984 | ||
| Modified constraint-induced movement therapy versus traditional rehabilitation in patients with upper-extremity dysfunction after stroke: a systematic review and meta-analysis | Q33914933 | ||
| Constraint-induced movement therapy: characterizing the intervention protocol | Q34000185 | ||
| Retention of upper limb function in stroke survivors who have received constraint-induced movement therapy: the EXCITE randomised trial | Q34008703 | ||
| The responsiveness of the Action Research Arm test and the Fugl-Meyer Assessment scale in chronic stroke patients | Q34085591 | ||
| The EXCITE stroke trial: comparing early and delayed constraint-induced movement therapy | Q34197404 | ||
| What is the evidence for physical therapy poststroke? A systematic review and meta-analysis | Q35088338 | ||
| Constraint-induced movement therapy results in increased motor map area in subjects 3 to 9 months after stroke. | Q35603705 | ||
| Constraint-induced movement therapy for chronic stroke hemiparesis and other disabilities. | Q35926598 | ||
| Constraint-Induced Movement Therapy (CIMT): Current Perspectives and Future Directions | Q35936738 | ||
| Constraint-induced movement therapy for rehabilitation of arm dysfunction after stroke in adults: an evidence-based analysis. | Q36040213 | ||
| The behavior-analytic origins of constraint-induced movement therapy: an example of behavioral neurorehabilitation. | Q36409253 | ||
| Changes in serial optical topography and TMS during task performance after constraint-induced movement therapy in stroke: a case study | Q36610186 | ||
| The effects of constraint-induced therapy on precision grip: a preliminary study | Q36630375 | ||
| Putting the brain on the map: use of transcranial magnetic stimulation to assess and induce cortical plasticity of upper-extremity movement | Q36788864 | ||
| The constraint induced movement therapy: a systematic review of randomised controlled trials on the adult stroke patients. | Q36831648 | ||
| Method for enhancing real-world use of a more affected arm in chronic stroke: transfer package of constraint-induced movement therapy | Q36989885 | ||
| Study to assess the effectiveness of modified constraint-induced movement therapy in stroke subjects: A randomized controlled trial | Q37046682 | ||
| The problem of relating plasticity and skilled reaching after motor cortex stroke in the rat. | Q37087745 | ||
| Very Early Constraint-Induced Movement during Stroke Rehabilitation (VECTORS): A single-center RCT | Q37274600 | ||
| Motor recovery after stroke: a systematic review | Q37553377 | ||
| Plasticity during stroke recovery: from synapse to behaviour. | Q37627168 | ||
| Constraint-induced movement therapy in stroke patients: systematic review and meta-analysis. | Q37827668 | ||
| Early prediction of outcome of activities of daily living after stroke: a systematic review | Q37862915 | ||
| Constraint-induced movement therapy for the upper paretic limb in acute or sub-acute stroke: a systematic review | Q37939374 | ||
| Unilateral versus bilateral upper limb exercise therapy after stroke: a systematic review | Q37977828 | ||
| Constraint-induced movement therapy: from history to plasticity | Q37979873 | ||
| Exploring the efficacy of constraint in animal models of stroke: meta-analysis and systematic review of the current evidence | Q38020098 | ||
| Systematic review and meta-analysis of constraint-induced movement therapy in the hemiparetic upper extremity more than six months post stroke | Q38063452 | ||
| Understanding upper limb recovery after stroke | Q38130440 | ||
| Unilateral versus bilateral upper limb training after stroke: the Upper Limb Training After Stroke clinical trial | Q38448063 | ||
| Impact of time on quality of motor control of the paretic upper limb after stroke | Q39326005 | ||
| Improvement after constraint-induced movement therapy: recovery of normal motor control or task-specific compensation? | Q39585800 | ||
| Effectiveness of constraint-induced movement therapy (CIMT) as home-based therapy on Barthel Index in patients with chronic stroke | Q39960287 | ||
| Constraint-induced movement therapy during early stroke rehabilitation | Q40259682 | ||
| Neuroplasticity, learning and recovery after stroke: a critical evaluation of constraint-induced therapy | Q40365282 | ||
| Early overuse and disuse of the affected forelimb after moderately severe intraluminal suture occlusion of the middle cerebral artery in rats | Q43796338 | ||
| Measurement of motor recovery after stroke. Outcome assessment and sample size requirements | Q43920473 | ||
| The contribution of kinematics in the assessment of upper limb motor recovery early after stroke | Q44836438 | ||
| Constraint-induced movement therapy overcomes the intrinsic axonal growth-inhibitory signals in stroke rats | Q44978917 | ||
| Constraint-induced therapy versus control intervention in patients with stroke: a functional magnetic resonance imaging study. | Q45198359 | ||
| Constraint-induced therapy with trunk restraint for improving functional outcomes and trunk-arm control after stroke: a randomized controlled trial. | Q45218349 | ||
| Constraint-induced therapy versus dose-matched control intervention to improve motor ability, basic/extended daily functions, and quality of life in stroke | Q45391944 | ||
| Forced use of hemiplegic upper extremities to reverse the effect of learned nonuse among chronic stroke and head-injured patients. | Q45999263 | ||
| Understanding adaptive motor control of the paretic upper limb early poststroke: the EXPLICIT-stroke program. | Q46099129 | ||
| The PREP algorithm predicts potential for upper limb recovery after stroke | Q46410643 | ||
| Functional reorganization and recovery after constraint-induced movement therapy in subacute stroke: case reports | Q46975848 | ||
| Efficacy of rehabilitative experience declines with time after focal ischemic brain injury. | Q47220498 | ||
| Effect of forced use of the upper extremity of a hemiplegic patient on changes in function. A single-case design | Q47615023 | ||
| Effect of constraint-induced movement therapy with modified opposition restriction orthosis in chronic hemiparetic patients with stroke | Q47630703 | ||
| Influence of constraint-induced movement therapy upon evoked potentials in rats with cerebral infarction | Q48345785 | ||
| Functional potential in chronic stroke patients depends on corticospinal tract integrity | Q48346969 | ||
| Constraint-induced therapy in stroke: magnetic-stimulation motor maps and cerebral activation | Q48360919 | ||
| Constraint-induced movement therapy in patients with stroke: a pilot study on effects of small group training and of extended mitt use. | Q48449839 | ||
| Association of activity changes in the primary sensory cortex with successful motor rehabilitation of the hand following stroke | Q48625662 | ||
| Brain-derived neurotrophic factor contributes to recovery of skilled reaching after focal ischemia in rats | Q48792323 | ||
| Active finger extension predicts outcomes after constraint-induced movement therapy for individuals with hemiparesis after stroke | Q48888176 | ||
| Effects of trunk restraint combined with intensive task practice on poststroke upper extremity reach and function: a pilot study. | Q48912579 | ||
| Use-dependent exaggeration of neuronal injury after unilateral sensorimotor cortex lesions. | Q48957307 | ||
| Activation changes in sensorimotor cortex during improvement due to CIMT in chronic stroke | Q49137399 | ||
| Effects of sling and voluntary constraint during constraint-induced movement therapy for the arm after stroke: a randomized, prospective, single-centre, blinded observer rated study. | Q50944990 | ||
| The Excite Trial: relationship of intensity of constraint induced movement therapy to improvement in the wolf motor function test. | Q51711267 | ||
| A 1-year follow-up after shortened constraint-induced movement therapy with and without mitt poststroke. | Q51777853 | ||
| Is forced use of the paretic upper limb beneficial? A randomized pilot study during subacute post-stroke recovery. | Q51838499 | ||
| A study of constraint-induced movement therapy in subacute stroke patients in Hong Kong. | Q51894685 | ||
| Can forced-use therapy be clinically applied after stroke? An exploratory randomized controlled trial. | Q51937329 | ||
| Forced use of the upper extremity in chronic stroke patients: results from a single-blind randomized clinical trial. | Q52173369 | ||
| Effects of constraint-induced therapy versus bilateral arm training on motor performance, daily functions, and quality of life in stroke survivors. | Q53119273 | ||
| Effects of modified constraint-induced movement therapy on reach-to-grasp movements and functional performance after chronic stroke: a randomized controlled study. | Q55046088 | ||
| Modified Constraint-Induced Therapy in Chronic Stroke: Results of a Single-Blinded Randomized Controlled Trial | Q57414223 | ||
| Active Finger Extension | Q60730411 | ||
| Reduced-Intensity Modified Constraint-Induced Movement Therapy Versus Conventional Therapy for Upper Extremity Rehabilitation After Stroke | Q61653414 | ||
| Modified Constraint-Induced Movement Therapy Improved Upper Limb Function in Subacute Poststroke Patients: A Small-Scale Clinical Trial | Q61811975 | ||
| Is modified constraint-induced movement therapy more effective than bimanual training in improving arm motor function in the subacute phase post stroke? A randomized controlled trial | Q62124345 | ||
| Technique to improve chronic motor deficit after stroke | Q70643541 | ||
| Does the application of constraint-induced movement therapy during acute rehabilitation reduce arm impairment after ischemic stroke? | Q73275821 | ||
| P433 | issue | 2 | |
| P304 | page(s) | 224-234 | |
| P577 | publication date | 2015-02-01 | |
| P1433 | published in | Lancet Neurology | Q15755067 |
| P1476 | title | Constraint-induced movement therapy after stroke | |
| P478 | volume | 14 |
| Q53085587 | A randomized controlled trial of self-regulated modified constraint-induced movement therapy in sub-acute stroke patients. |
| Q64090090 | A web-based carepartner-integrated rehabilitation program for persons with stroke: study protocol for a pilot randomized controlled trial |
| Q64075338 | Adopting Text Mining on Rehabilitation Therapy Repositioning for Stroke |
| Q45963344 | Agreed Definitions and a Shared Vision for New Standards in Stroke Recovery Research: The Stroke Recovery and Rehabilitation Roundtable Taskforce. |
| Q52089447 | Agreed definitions and a shared vision for new standards in stroke recovery research: The Stroke Recovery and Rehabilitation Roundtable taskforce. |
| Q47558355 | Automated Assessment of Endpoint and Kinematic Features of Skilled Reaching in Rats |
| Q38621932 | Capture, learning, and classification of upper extremity movement primitives in healthy controls and stroke patients |
| Q47833142 | Cell Therapy in Stroke-Cautious Steps Towards a Clinical Treatment. |
| Q38593330 | Central Adaptation following Brachial Plexus Injury. |
| Q26748823 | Computational neurorehabilitation: modeling plasticity and learning to predict recovery |
| Q64085614 | Constrained-Induced Dysarthria Therapy: Case Report |
| Q24186569 | Constraint-induced movement therapy for upper extremities in people with stroke |
| Q47139517 | Constraint-induced movement therapy in treatment of acute and sub-acute stroke: a meta-analysis of 16 randomized controlled trials. |
| Q85690328 | Constraint-induced movement therapy translated into practice |
| Q27302423 | Counteracting learned non-use in chronic stroke patients with reinforcement-induced movement therapy |
| Q30491865 | Crouch gait can be an effective form of forced-use/no constraint exercise for the paretic lower limb in stroke |
| Q55098703 | Does Task-Specific Training Improve Upper Limb Performance in Daily Life Poststroke? |
| Q38592192 | Dose and timing in neurorehabilitation: prescribing motor therapy after stroke. |
| Q41046617 | Dose response of task-specific upper limb training in people at least 6 months poststroke: A phase II, single-blind, randomized, controlled trial |
| Q64076359 | Early constraint-induced movement therapy affects behavior and neuronal plasticity in ischemia-injured rat brains |
| Q38689479 | Early versus late-applied constraint-induced movement therapy: A multisite, randomized controlled trial with a 12-month follow-up |
| Q64245538 | Effect of Specific Over Nonspecific VR-Based Rehabilitation on Poststroke Motor Recovery: A Systematic Meta-analysis |
| Q90338727 | Effectiveness of interventions to improve hand motor function in individuals with moderate to severe stroke: a systematic review protocol |
| Q92632360 | Effects of Dopamine on Motor Recovery and Training in Adults and Children With Nonprogressive Neurological Injuries: A Systematic Review |
| Q49022370 | Effects of Unilateral Upper Limb Training in Two Distinct Prognostic Groups Early After Stroke: The EXPLICIT-Stroke Randomized Clinical Trial |
| Q58796948 | Effects of modified constraint-induced movement therapy on upper extremity function and occupational performance of stroke patients |
| Q61807356 | Effects of task-oriented training on upper extremity functional performance in patients with sub-acute stroke: a randomized controlled trial |
| Q40257790 | Efficacy of Modified Constraint Induced Movement Therapy in the Treatment of Hemiparetic Upper Limb in Stroke Patients: A Randomized Controlled Trial |
| Q92706733 | Efficacy of Tiaoqiheying decoction in the treatment of spasmodic pain and lipid metabolism after acute ischemic stroke |
| Q47157149 | Electromyographic analysis of constraint-induced movement therapy effects in patients after stroke in chronic course. |
| Q48501717 | Encouragement-Induced Real-World Upper Limb Use after Stroke by a Tracking and Feedback Device: A Study Protocol for a Multi-Center, Assessor-Blinded, Randomized Controlled Trial |
| Q61799127 | Evaluating the effect and mechanism of upper limb motor function recovery induced by immersive virtual-reality-based rehabilitation for subacute stroke subjects: study protocol for a randomized controlled trial |
| Q35890570 | Functional Improvement after Photothrombotic Stroke in Rats Is Associated with Different Patterns of Dendritic Plasticity after G-CSF Treatment and G-CSF Treatment Combined with Concomitant or Sequential Constraint-Induced Movement Therapy |
| Q98945400 | Functional Recovery Patterns of Hemorrhagic and Ischemic Stroke Patients Under Post-Acute Care Rehabilitation Program |
| Q41524900 | Home-based constraint-induced movement therapy for patients with upper limb dysfunction after stroke (HOMECIMT): a cluster-randomised, controlled trial |
| Q37286037 | How to design clinical rehabilitation trials for the upper paretic limb early post stroke? |
| Q91676085 | Improved quality of life following constraint-induced movement therapy is associated with gains in arm use, but not motor improvement |
| Q92487044 | Increasing perceived hand size improves motor performance in individuals with stroke: a home-based training study |
| Q91282279 | Laterality of Damage Influences the Relationship Between Impairment and Arm Use After Stroke |
| Q92312282 | Long-Dose Intensive Therapy Is Necessary for Strong, Clinically Significant, Upper Limb Functional Gains and Retained Gains in Severe/Moderate Chronic Stroke |
| Q48639079 | Making if-then plans counteracts learned non-use in stroke patients: A proof-of-principle study |
| Q91864273 | Modified constraint-induced movement therapy alters synaptic plasticity of rat contralateral hippocampus following middle cerebral artery occlusion |
| Q33714272 | Motor Imagery-Based Rehabilitation: Potential Neural Correlates and Clinical Application for Functional Recovery of Motor Deficits after Stroke |
| Q26795480 | Motor System Reorganization After Stroke: Stimulating and Training Toward Perfection |
| Q42006695 | Neural Plasticity in Moderate to Severe Chronic Stroke Following a Device-Assisted Task-Specific Arm/Hand Intervention. |
| Q90668069 | New Directions in Treatments Targeting Stroke Recovery |
| Q92292277 | Pharmacological Interventions and Rehabilitation Approach for Enhancing Brain Self-repair and Stroke Recovery |
| Q88397033 | Phase II Randomized Controlled Trial of Constraint-Induced Movement Therapy in Multiple Sclerosis. Part 1: Effects on Real-World Function |
| Q36814618 | Plastic Change along the Intact Crossed Pathway in Acute Phase of Cerebral Ischemia Revealed by Optical Intrinsic Signal Imaging |
| Q30395703 | Post stroke hemi-dystonia in children: a neglected area of research. |
| Q90030580 | Predicting Improved Daily Use of the More Affected Arm Poststroke Following Constraint-Induced Movement Therapy |
| Q92535318 | Principles of Neurorehabilitation After Stroke Based on Motor Learning and Brain Plasticity Mechanisms |
| Q38675024 | Promoting recovery from ischemic stroke |
| Q92702712 | Prompting arm activity after stroke: A clinical proof of concept study of wrist-worn accelerometers with a vibrating alert function |
| Q40325545 | Recovering functional independence after a stroke through Modified Constraint-Induced Therapy |
| Q92732201 | Region-specific and activity-dependent regulation of SVZ neurogenesis and recovery after stroke |
| Q55474523 | Rehabilitation robots for the treatment of sensorimotor deficits: a neurophysiological perspective. |
| Q42064027 | Role of the Contralesional vs. Ipsilesional Hemisphere in Stroke Recovery |
| Q27336324 | Safety, Feasibility, and Efficacy of Vagus Nerve Stimulation Paired With Upper-Limb Rehabilitation After Ischemic Stroke |
| Q36715149 | Sequencing bilateral robot-assisted arm therapy and constraint-induced therapy improves reach to press and trunk kinematics in patients with stroke. |
| Q38808223 | Somatosensory deficits after stroke: a scoping review. |
| Q51796083 | Standardized Measurement of Sensorimotor Recovery in Stroke Trials: Consensus-Based Core Recommendations from the Stroke Recovery and Rehabilitation Roundtable. |
| Q38659128 | Standardized measurement of sensorimotor recovery in stroke trials: Consensus-based core recommendations from the Stroke Recovery and Rehabilitation Roundtable. |
| Q92140698 | Stroke patients' and non-professional coaches' experiences with home-based constraint-induced movement therapy: a qualitative study |
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| Q33700790 | The Effects of Modified Constraint-Induced Movement Therapy in Acute Subcortical Cerebral Infarction |
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| Q53676377 | [New aspects of neurorehabilitation: motor and language]. |
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