Credential · Certification

CIMT (Constraint-Induced Movement)

OTPT150 citations · 3 lenses

EXCITE trial: 14-point Wolf Motor Function Test improvement sustained 2 years. Pediatric CIMT superior for hemiplegia. Neuroplasticity mechanism established.

Scores · default weights

Each lens uses its own dimensions and default weights. Scores answer different questions across paths — they aren’t apples-to-apples. How scoring works →

Clinical breakdown

Clinical outcomes×35%

83/100

Among the best-evidenced upper extremity rehab interventions post-stroke and for pediatric hemiplegia. EXCITE trial landmark.

Caseload applicability×15%

32/100

Limited to stroke patients with residual upper limb function; requires intensive format not feasible in most settings.

Billing & reimbursement×15%

52/100

Billed as intensive OT/PT; commercial payers cover at standard therapy rates; frequency justification often required.

Certification investment×20%

38/100

Multi-day CIMT training plus constrained practice requires dedicated equipment and space; moderate investment.

Employer demand×10%

48/100

Moderate demand in neuro specialty programs and stroke rehabilitation centers.

Patient experience×5%

68/100

Restraint tolerated when motivation high; pediatric populations show high family engagement.

Business breakdown

Cash-pay viability×25%

35/100

Stroke/neuro families will pay for intensive programs, but population is narrower and often insurance/Medicare-driven.

Pricing leverage×20%

40/100

Intensive protocol model supports package pricing in niche neuro clinics.

Market differentiation×15%

55/100

Relatively few certified providers; defensible neuro niche.

Owner leverage×15%

45/100

Protocol-based — can train staff to deliver, but volume is limited by patient pool.

Consumer demand×15%

30/100

Stroke survivors/families do search for it, but a small subsegment.

Credential investment×10%

35/100

Multi-day training, moderate cost; delivery is labor-intensive (massed practice).

Academic Clinical breakdown

Faculty recognition×25%

65/100

Strong neuro credential aligning with NCS faculty profiles.

Scholarship signal×20%

80/100

Taub's body of work and ongoing RCTs make this a publishable, fundable area.

Teaching value×15%

75/100

Core example in neuro rehab curricula for motor learning and neuroplasticity.

Evidence depth×20%

85/100

EXCITE trial and multiple systematic reviews — among the best-evidenced neuro interventions.

Faculty demand×10%

45/100

Useful but not required; neuro faculty lines lean on NCS more.

Credential investment×10%

40/100

Time-intensive training relative to alternatives like NDT or task-specific training coursework.

Evidence base · 150 sources

01
Enhancing Grip Strength and Manual Dexterity in Unilateral Cerebral Palsy: A Randomized Trial of Mirror Visual Feedback vs. Modified Constraint-Induced Movement Therapy
M. A. Abdel Ghafar; O. R. Abdelraouf; N. H. Alkhamees; M. E. Mohamed; E. M. Harraz; M. K. Seyam; Z. M. Ibrahim; A. Alnamnakani; A. A. Elborady; R. E. Radwan · Brain Sci2025
RCTdoi:10.3390/brainsci15030305
02
A systematic review of physical therapy rehabilitation for stroke survivors in Arab countries and Saudi Arabia: current approaches and future challenges
A. I. Alhusayni; A. H. Alzahrani · Saudi Med J2025
Systematic reviewdoi:10.15537/smj.2025.46.9.20250255
03
Effectiveness of Modified Constraint-Induced Movement Therapy in Restoring Fine Motor Function of The Upper Limb in MCA Post-Stroke Patients: A Prospective Case Study
A. Ashok; K. Ramana; V. Srinivasan; P. Suganthirababu; S. Rambachan · Indian Journal of Physiotherapy & Occupational Therapy2025
Cohort studydoi:10.37506/0sxqyv56
04
Randomized Comparison Trial of Rehabilitation Very Early for Infants with Congenital Hemiplegia
R. N. Boyd; S. Greaves; J. Ziviani; I. Novak; N. Badawi; K. Pannek; C. Elliott; M. Wallen; C. Morgan; J. Valentine; L. Findlay; A. Guzzetta; K. Whittingham; R. S. Ware; S. Fiori; N. L. Maitre; J. Heathcock; K. Scott; A. C. Eliasson; L. Sakzewski · J Pediatr2025
RCTdoi:10.1016/j.jpeds.2024.114381
05
Reinforcement Learning is Impaired in the Sub-acute Post-stroke Period
M. Branscheidt; A. M. Hadjiosif; M. A. Anaya; J. Keller; M. Widmer; K. D. Runnalls; A. R. Luft; A. J. Bastian; J. W. Krakauer; P. A. Celnik · Neurorehabilitation & Neural Repair2025
Otherdoi:10.1177/15459683241304352
06
Motor Rehabilitation Provides Modest Functional Benefits After Intracerebral Hemorrhage: a Systematic Review and Meta-Analysis of Translational Rehabilitation Studies
B. A. Fedor; N. H. Sander; M. MacLaren; L. J. Liddle; C. L. MacLellan; F. Colbourne · Transl Stroke Res2025
Meta-analysisdoi:10.1007/s12975-023-01205-w
07
A 6-Week Modified Physical Therapy Intensive Program for a Child With Cerebral Palsy
M. Flowers · Pediatric Physical Therapy2025
Otherdoi:10.1097/PEP.0000000000001191
08
Could aerobic exercise applied before constraint-induced movement therapy change circulating molecular biomarkers in chronic post-stroke?
L. F. García-Salazar; N. D. Pereira; E. S. M. Silva; J. A. M. Ribeiro; G. Nagai Ocamoto; R. Mendes Zambetta; S. G. de Oliveira; A. M. Catai; A. Borstad; T. L. Russo · Taylor & Francis Ltd2025
Otherdoi:10.1080/09593985.2024.2411311
09
Effectiveness of intensive motor learning approaches from working on a vertical surface on hemiplegic children's upper limb motor skills, a randomized controlled trial
O. S. A. Ghoneim; D. Galal; D. H. Al-Afify; M. H. El Ebrashy; F. S. Zidan; R. A. Saad · Disabil Rehabil2025
RCTdoi:10.1080/09638288.2024.2407505
10
Effectiveness of modified constraint-induced movement therapy on upper limb function of stroke survivors in inpatient hospital settings: a systematic review and meta-analysis
R. J. Hansen; A. Joy; K. J. Lockwood · Disabil Rehabil2025
Meta-analysisdoi:10.1080/09638288.2025.2496361
11
Home-Based Telerehabilitation to Prevent Post-Modified Constraint-Induced Movement Therapy Regression in Unilateral Cerebral Palsy: A Randomized Controlled Trial
Y. Hwang; W. H. Shin; S. E. Kim; J. Y. Kwon · Phys Occup Ther Pediatr2025
RCTdoi:10.1080/01942638.2025.2482257
12
Effectiveness of Intensive Motor Learning Approaches for Stroke: A Systematic Review of Randomized Controlled Trials
M. Jamkar; S. Giri; S. Jeyakumar; T. Vignesh · Indian Journal of Physiotherapy & Occupational Therapy2025
Systematic reviewdoi:10.37506/wqasrb19
13
tDCS Combined with CIMT for Post-stroke Upper Extremity Rehabilitation: A Systematic Review and Meta-Analysis
T. Jiang; J. Yan; X. Li; M. Yang; Y. Zhuang; Z. Ding; M. Tan; S. Xia; R. Li; W. Wang; F. Chen; X. Xie; W. Liu · NeuroRehabilitation2025
Meta-analysisdoi:10.1177/10538135241301692
14
Interventional effects of modified constraint-induced movement therapy on upper limb function in patients who had a stroke: systematic review and meta-analysis
J. Liu; Z. Wang; C. Wang; Y. Zhang · BMJ Open2025
Meta-analysisdoi:10.1136/bmjopen-2024-094309
15
Exploring Therapists' Experiences of an Educational Website to Support Telehealth Delivery of Constraint-Induced Movement Therapy
K. Makroglou; N. Fearn; B. Portelli; H. Badge; J. Boydell; A. Kilkenny; A. Meharg; L. J. Christie · Healthcare (2227-9032)2025
Otherdoi:10.3390/healthcare13020159
16
Constraint-Induced Movement Therapy Versus Bimanual Training to Improve Upper Limb Function in Cerebral Palsy: A Systematic Review and Meta-Analysis of Follow-Ups
G. Martin-Moreno; M. Moreno-Ligero; A. Salazar; D. Lucena-Anton; J. A. Moral-Munoz · Children2025
Meta-analysisdoi:10.3390/children12060804
17
Transcranial direct current stimulation combined with an intensive training program for upper limb rehabilitation in children with unilateral cerebral palsy. A randomized controlled pilot study
J. Merino-Andrés; R. Palomo-Carrión; J. Gómez-Soriano; J. J. Fernández-Pérez; D. Serrano-Muñoz; E. Muñoz-Marrón; P. López-Muñoz · Res Dev Disabil2025
RCTdoi:10.1016/j.ridd.2025.105001
18
Integrating modified constraint-induced movement therapy with sensory threshold somatosensory electrical stimulation in stroke rehabilitation: A randomized controlled clinical trial
E. Mete; Z. Sari; H. H. Karadeli; A. Avarisli · Pm r2025
RCTdoi:10.1002/pmrj.13394
19
Hand Functions Following Prone-weight Bearing on Upper Limb with Active Elbow Extension Versus Modified Constraint Induced Movement Therapy in Children with Unilateral Cerebral Palsy - A Randomised Clinical Trial
A. Narayan; R. Bavighar; S. Krishnan; A. Alammari; S. D. Karnad; D. P. Poojari · NeuroRehabilitation2025
RCTdoi:10.1177/10538135251329200
20
Hand-arm bimanual intensive therapy versus modified constraint-induced movement therapy in children with hemiparetic cerebral palsy: A randomized controlled trial
P. K. Panda; I. K. Sharawat; D. Gupta; A. Palayullakandi; S. S. Kumaran; P. Sherwani; S. Sopanam; O. Neyaz · Brain Dev2025
RCTdoi:10.1016/j.braindev.2025.104381
21
Enhancing quality of life in individuals with cerebral palsy: a systematic review and meta-analysis of physiotherapy interventions
A. A. Passos; F. O. A. Santos; R. M. Arida; J. A. F. Brogin; J. Faber; C. López-Ortiz; L. Teixeira-Machado · Disabil Rehabil2025
Meta-analysisdoi:10.1080/09638288.2024.2443040
22
Evaluation of a Game-Based Mechatronic Device for Rehabilitation of Hand-Arm Function in Children With Cerebral Palsy: Feasibility Randomized Controlled Trial
M. K. Peramalaiah; S. T. Parmar; N. Sepehri; S. Muthukumarana; A. Kanitkar; C. K. Hin; T. J. Szturm · JMIR Rehabil Assist Technol2025
RCTdoi:10.2196/65358
23
The effect of constraint-induced movement therapy for children with hemiplegic cerebral palsy in Vietnam
V. M. Pham; T. L. Hoang; K. C. Hoang; N.-M. Nguyen; S. C. DeLuca; P. Coker-Bolt · Disability & Rehabilitation2025
Otherdoi:10.1080/09638288.2024.2360060
24
Blinded, Randomized Trial Comparing Constraint-Induced Movement Therapy With Virtual Reality With Constraint-Induced Movement Therapy Alone...American Occupational Therapy Association (AOTA) INSPIRE Annual Conference and Expo, April 3-5, 2025, Philadelphia, Pennsylvania
H. Roberts; N. Clegg; H. Becker; A. Loewen; A. Erdman; S. Ulman; F. Reyes; A. Shierk; S. Chapa · American Journal of Occupational Therapy2025
RCTdoi:10.5014/ajot.2025.79S2-PO451
25
Constraint Therapy with and Without Virtual Reality for Children with Unilateral Cerebral Palsy: A Randomized Trial
H. Roberts; N. J. Clegg; W. Wang; S. Chapa; B. Arellano; M. Trahan; F. Reyes; M. R. Delgado; S. Ram; A. Shierk · Children2025
RCTdoi:10.3390/children12030283
26
Safety and efficacy of transcranial direct current stimulation in addition to constraint-induced movement therapy for post-stroke motor recovery (TRANSPORT2): a phase 2, multicentre, randomised, sham-controlled triple-blind trial
G. Schlaug; C. Cassarly; J. A. Feld; S. L. Wolf; V. T. Rowe; S. Fritz; P. Y. Chhatbar; A. Shinde; Z. Su; J. P. Broderick; R. Zorowitz; O. Awosika; D. Edwards; C. Lin; G. E. Franciso; G. F. Wittenberg; S. Pundik; C. Gregory; M. R. Borich; V. Ramakrishnan; W. Feng · Lancet Neurol2025
RCTdoi:10.1016/s1474-4422(25)00044-4
27
Long COVID brain fog treatment: An early-phase randomized controlled trial of constraint-induced cognitive therapy signals go
G. Uswatte; E. Taub; K. Ball; B. S. Mitchell; J. A. Blake; S. McKay; F. Biney; O. Iosipchuk; P. Hempfling; E. Harris; A. Dickerson; K. Lokken; A. J. Knight; V. W. Mark; S. Agnihotri; G. Cutter · Rehabil Psychol2025
RCTdoi:10.1037/rep0000626
28
Occupational therapy intervention for Cerebral Palsy -- a rapid review
J. van der Walt; H. M. van Biljon; M. Engelbrecht; S. M. Soeker · South African Journal of Occupational Therapy2025
Otherdoi:10.17159/2310-3833/2025/vol55no1a8
29
The effectiveness of modified constraint-induced movement therapy on upper limb function in children with cerebral palsy: a systematic review and meta-analysis
H. Wang; J. Zhou; X. Shan; L. Zhang · BMC Sports Sci Med Rehabil2025
Meta-analysisdoi:10.1186/s13102-025-01259-3
30
Investigating the acceptability of modified constraint-induced movement therapy among stroke survivors and carers: a qualitative study
A. Weerakkody; E. Godecke; B. Singer · Disability & Rehabilitation2025
Qualitativedoi:10.1080/09638288.2024.2361808
31
Translating acceptability to sustained delivery: Clinician and manager perspectives on implementing modified constraint‐induced movement therapy in an early‐supported discharge rehabilitation service
A. Weerakkody; E. Godecke; B. Singer · Australian Occupational Therapy Journal2025
Otherdoi:10.1111/1440-1630.12993
32
Modified‐constraint movement induced therapy versus neuro‐developmental therapy on reaching capacity in children with hemiplegic cerebral palsy
R. S. Abdul‐Rahman; N. L. Radwan; B. A. El‐Nassag; W. M. Amin; M. S. Ali · Physiotherapy Research International2024
Otherdoi:10.1002/pri.2069
33
Effect of modified constraint-induced movement therapy along with bimanual massed practice on upper extremity functions in tetraplegics: a pilot study
S. Chakraverty; S. Walia · Bulletin of Faculty of Physical Therapy2024
Pilot/feasibilitydoi:10.1186/s43161-024-00238-y
34
The Effect of Constraint-Induced Movement Therapy on Arm Function and Activities of Daily Living in Post-stroke Patients: A Systematic Review and Meta-Analysis
H. Choi; H. J. Kim · Brain Neurorehabil2024
Meta-analysisdoi:10.12786/bn.2024.17.e19
35
Increasing the delivery of upper limb constraint-induced movement therapy programs for stroke and brain injury survivors: evaluation of the ACTIveARM project
L. J. Christie; R. Rendell; N. Fearn; J. Descallar; A. McCluskey; A. Pearce; L. Wong; M. Lovarini · Disabil Rehabil2024
Otherdoi:10.1080/09638288.2023.2290687
36
Development of a behaviour change intervention to increase the delivery of upper limb constraint-induced movement therapy programs to people with stroke and traumatic brain injury
L. J. Christie; R. Rendell; A. McCluskey; N. Fearn; A. Hunter; M. Lovarini · Disabil Rehabil2024
Otherdoi:10.1080/09638288.2023.2290686
37
A Review of Current Perspectives on Motoric Insufficiency Rehabilitation following Pediatric Stroke
H. Colovic; D. Zlatanovic; V. Zivkovic; M. Jankovic; N. Radosavljevic; S. Ducic; J. Ducic; J. Stojkovic; K. Jovanovic; D. Nikolic · Healthcare (Basel)2024
Otherdoi:10.3390/healthcare12020149
38
Cost-Effectiveness of an Intensive Upper Limb Rehabilitation Therapy for Children With Unilateral Cerebral Palsy: An Economic Evaluation of a Randomized Controlled Trial
M. C. David; H. Higashi · J Health Econ Outcomes Res2024
RCTdoi:10.36469/001c.94460
39
Effectiveness of Constraint Induced Movement Therapy and Proprioceptive Neuromuscular Facilitation on Upper Extremity Functions in Stroke
L. Dhanalakshmi; J. Alagesan; A. Buvanesh · Indian Journal of Physiotherapy & Occupational Therapy2024
Otherdoi:10.37506/pjqhy364
40
The effect of constraint-induced movement therapy assessed by accelerometry: the impact on daytime activity and sleep in children with cerebral palsy
M. Fischer de Almeida; A. Obrecht; M. Bueno Zonta; A. Chrystina Crippa · Fisioterapia em Movimento2024
Otherdoi:10.1590/fm.2024.37104
41
Non-pharmacological interventions on quality of life in stroke survivors: A systematic review and meta-analysis
C. Gao; X. Li; F. Li; J. Li; J. Zhang · Worldviews Evid Based Nurs2024
Meta-analysisdoi:10.1111/wvn.12714
42
Infant Modified Constraint-Induced Movement Therapy Paired With Neuromuscular Electrical Stimulation: A Feasibility Study
K. Grinde; J. Myhre; A. Nickel; M. D. Finch · Pediatric Physical Therapy2024
Pilot/feasibilitydoi:10.1097/PEP.0000000000001124
43
Therapeutic effect of adjuvant therapy added to constraint-induced movement therapy in patients with subacute to chronic stroke: a systematic review and meta-analysis
T. Kaneko; M. Maeda; H. Yokoyama; S. Kai; K. Obuchi; S. Takase; T. Horimoto; R. Shimada; T. Moriya; H. Ohmae; M. Amanai; Y. Okita; T. Takebayashi · Disabil Rehabil2024
Meta-analysisdoi:10.1080/09638288.2023.2269843
44
Effectiveness of Intermittent Theta Burst Stimulation to Enhance Upper Extremity Recovery After Stroke: A Pilot Study
E. N. Kolbaşı; B. E. Huseyinsinoglu; Z. Ozdemir; Z. Bayraktaroglu; A. Soysal · Arch Phys Med Rehabil2024
Pilot/feasibilitydoi:10.1016/j.apmr.2024.05.025
45
Improvement of gait and balance function in chronic post-stroke patients induced by Lower Extremity - Constraint Induced Movement Therapy: a randomized controlled clinical trial
E. Menezes-Oliveira; G. da Silva Matuti; C. B. de Oliveira; S. F. de Freitas; C. Miyuki Kawamura; J. A. Fernandes Lopes; J. Faber; R. M. Arida · Brain Inj2024
RCTdoi:10.1080/02699052.2024.2328808
46
Is more always better? Effectiveness of constraint-induced movement therapy in children with high-risk or unilateral cerebral palsy (0-6 years): Systematic review and meta-analysis
J. Merino-Andrés; P. López-Muñoz; R. P. Carrión; P. Martín-Casas; I. Ruiz-Becerro; Á. Hidalgo-Robles · Child Care Health Dev2024
Meta-analysisdoi:10.1111/cch.13262
47
Enhanced phasic calf muscle activation with swing resistance enhances propulsion of the paretic leg in people poststroke
S. H. Park; S. Yan; W. Dee; R. Keefer; E. J. Roth; W. Z. Rymer; M. Wu · J Neurophysiol2024
Otherdoi:10.1152/jn.00485.2023
48
Young Children Benefit from Intensive, Group-Based Pediatric Constraint-Induced Movement Therapy
K. S. Ryan-Bloomer · Healthcare (2227-9032)2024
Otherdoi:10.3390/healthcare12212134
49
Effectiveness of constraint-induced movement therapy (CIMT)-Telerehabilitation compared to traditional CIMT on upper extremity dysfunction of adult chronic stroke patients-A systematic review and meta-analysis
L. Sanchez; B. M. Asuncion; K. R. Tayag; C. Chua; S. J. Escandor; V. C. Dones, 3rd · Physiother Res Int2024
Meta-analysisdoi:10.1002/pri.2090
50
Effects of modified-constraint induced movement therapy based telerehabilitation on upper extremity motor functions in stroke patients
F. Saygili; A. Guclu-Gunduz; S. Eldemir; K. Eldemir; C. Ozkul; G. T. Gursoy · Brain Behav2024
Otherdoi:10.1002/brb3.3569
51
POSITIVE EFFECTS OF LOWER EXTREMITY CONSTRAINT-INDUCED MOVEMENT THERAPY ON BALANCE, LEG STRENGTH AND DUAL-TASK ABILITY IN STROKE PATIENTS: A LONGITUDINAL COHORT STUDY
A. Sefastsson; I. Marklund; H. Littbrand; P. Wester; B.-M. StÅLnacke; A. SÖRlin; B. Langhammer; L. I. V. Per; H. U. Xiaolei · Journal of Rehabilitation Medicine (Stiftelsen Rehabiliteringsinformation)2024
Cohort studydoi:10.2340/jrm.v56.24168
52
Fast and Fun: A Pilot Feasibility Study Using Dual Joystick-Operated Ride-on Toys for Upper Extremity Rehabilitation in Children with Hemiplegia
V. Shahane; P. D. Kumavor; K. Morgan; S. Srinivasan · Physical & Occupational Therapy in Pediatrics2024
Pilot/feasibilitydoi:10.1080/01942638.2024.2360462
53
A STUDY TO ASSESS THE EFFECTIVENESS OF CONSTRAINT-INDUCED MOVEMENT THERAPY ON MOTOR FUNCTION AMONG STROKE PATIENTS IN SELECTED HOSPITALS IN ERODE
L. S. Sheeba; R. D. Tepilah; R. D. Delightson · i-Manager's Journal on Nursing2024
Otherdoi:10.26634/jnur.14.3.20667
54
Outcomes of a Parent-Delivered Baby-mCIMT Model for Infants at High Risk of Unilateral Cerebral Palsy Using Remote Coaching in Telerehabilitation
K. Svensson; H. Sundelin; A.-C. Eliasson · Children2024
Otherdoi:10.3390/children11010101
55
Long COVID Brain Fog Treatment: Findings from a Pilot Randomized Controlled Trial of Constraint-Induced Cognitive Therapy
G. Uswatte; E. Taub; K. Ball; B. S. Mitchell; J. A. Blake; S. McKay; F. Biney; O. Iosipchuk; P. Hempfling; E. Harris; A. Dickerson; K. Lokken; A. J. Knight; V. W. Mark; S. Agnihotri; G. Cutter · medRxiv2024
RCTdoi:10.1101/2024.07.04.24309908
56
Global research hotspots and trends in constraint-induced movement therapy in rehabilitation over the past 30 years: a bibliometric and visualization study
J. Xu; M. Chen; X. Wang; Z. Cai; Y. Wang; X. Luo · Front Neurol2024
Otherdoi:10.3389/fneur.2024.1375855
57
Effects of constraint induced movement therapy in patients with multiple sclerosis: A systematic review
A. Abdullahi; T. W. Wong; S. S. Ng · Mult Scler Relat Disord2023
Systematic reviewdoi:10.1016/j.msard.2023.104569
58
Combination of noninvasive brain stimulation and constraint-induced movement therapy in patients with stroke: a systematic review and meta-analysis
A. Abdullahi; T. W. Wong; T. Van Criekinge; S. S. Ng · Expert Rev Neurother2023
Meta-analysisdoi:10.1080/14737175.2023.2177154
59
Effectiveness of combining robotic therapy and modified constraint-induced movement therapy for moderate to severe upper limb paresis after stroke in subacute phase: Case–control study by propensity score analysis
N. Anmoto; T. Takebayashi; Y. Okita; M. Ishigaki; S. Hibino; K. Hanada · British Journal of Occupational Therapy2023
Otherdoi:10.1177/03080226221121745
60
The Efficacy of Two Models of Intensive Upper Limb Training on Health-Related Quality of Life in Children with Hemiplegic Cerebral Palsy Mainstreamed in Regular Schools: A Double-Blinded, Randomized Controlled Trial
H. Bingol; M. Kerem Gunel; H. Alkan · Physiother Theory Pract2023
RCTdoi:10.1080/09593985.2021.1999355
61
Implementing Home-Based Clinical Research for Caregivers and Persons with Stroke: Lessons Learned
S. Blanton; S. Dunbar; S. Caston; T. McLaughlin; H. Stewart; P. C. Clark · Home Healthcare Now2023
Otherdoi:10.1097/NHH.0000000000001171
62
Effect of Modified Constraint-Induced Movement Therapy on Upper Extremity Function for Stroke Patients with Right/Left Arm Paresis: A Single-Blind Randomized Controlled Trial
C. M. Ceylan; E. İ. ŞEn; T. KaraaĞAÇ; T. ŞAhbaz; A. Yaliman · Ahi Evran Medical Journal2023
RCTdoi:10.46332/aemj.1081991
63
Lower limb rehabilitation using modified constraint-induced movement therapy and motor relearning program on balance and gait in sub-acute hemiplegic stroke: a comparative study
N. S. Chavan; R. Raghuveer · F1000Res2023
Otherdoi:10.12688/f1000research.138127.2
64
Effect of different constraint-induced movement therapy protocols on recovery of stroke survivors with upper extremity dysfunction: a systematic review and network meta-analysis
Q. Gao; Y. Zhang; J. Long; M. Pan; J. Wang; F. Yang · Int J Rehabil Res2023
Meta-analysisdoi:10.1097/mrr.0000000000000577
65
Early transcranial direct current stimulation with modified constraint-induced movement therapy for motor and functional upper limb recovery in hospitalized patients with stroke: A randomized, multicentre, double-blind, clinical trial
M. M. Garrido; E. E. Álvarez; P. F. Acevedo; V. Á. Moyano; N. N. Castillo; G. Cavada Ch · Brain Stimul2023
RCTdoi:10.1016/j.brs.2022.12.008
66
Brain Stimulation and Constraint Induced Movement Therapy in Children With Unilateral Cerebral Palsy: A Randomized Controlled Trial
J. Gupta; S. Gulati; U. P. Singh; A. Kumar; P. Jauhari; B. Chakrabarty; R. M. Pandey; R. Bhatia; S. Jain; A. Srivastava · Neurorehabil Neural Repair2023
RCTdoi:10.1177/15459683231174222
67
Efficacy of Constraint-Induced Movement Therapy Versus Bimanual Intensive Training on Motor and Psychosocial Outcomes in Children With Unilateral Cerebral Palsy: A Randomized Trial
K.-J. Liang; H.-L. Chen; C.-W. Huang; T.-N. Wang · American Journal of Occupational Therapy2023
RCTdoi:10.5014/ajot.2023.050104
68
Neuromuscular Electrical Stimulation of Upper Limbs in Patients With Cerebral Palsy: A Systematic Review and Meta-analysis of Randomized Controlled Trials
C. H. Ou; C. C. Shiue; Y. C. Kuan; T. H. Liou; H. C. Chen; T. J. Kuo · Am J Phys Med Rehabil2023
Meta-analysisdoi:10.1097/phm.0000000000002058
69
Constraint-induced movement therapy versus bimanual intensive therapy in children with hemiplegia showing low/very low bimanual functional performance: A randomized clinical trial
R. Palomo-Carrión; A. Ferri-Morales; S. Ando-LaFuente; R. A. Fernández; J. I. C. Arenillas; V. Antón-Antón; E. B. Esteban · Pm r2023
RCTdoi:10.1002/pmrj.12990
70
Feasibility of family-directed home-based bimanual intensive therapy combined with modified constraint induced movement therapy (h-BITmCI) in very low and low bimanual functional level: A brief report
R. Palomo-Carrión; H. Romay-Barrero; C. Lirio-Romero; R. Arroyo-Fernádez; M. M-Guijarro-Herraiz; A. Ferri-Morales · Taylor & Francis Ltd2023
Pilot/feasibilitydoi:10.1080/17518423.2022.2099993
71
Aphasia improvement without logotherapy during motor neurorehabilitation of post-stroke hemiparesis using virtual reality or modified constraint-induced movement therapy: A retrospective cohort
M. D. C. Rojas-Sosa; J. A. Zárate; N. de la Rosa-Peña; J. L. Olvera-Gómez; D. Rojano-Mejía; J. Delgado-García; J. Garduño-Espinosa · NeuroRehabilitation2023
Cohort studydoi:10.3233/nre-230183
72
Efficacy of Modified Constraint Induced Movement Therapy in Post-Surgical Ulnar and/or Median Nerve Repair Patients
S. Sambyal; S. Kumar; Manisha · Indian Journal of Physiotherapy & Occupational Therapy2023
Otherdoi:10.37506/ijpot.v17i3.19548
73
Comparative effects of kinect-based versus therapist-based constraint-induced movement therapy on motor control and daily motor function in children with unilateral cerebral palsy: a randomized control trial
T. Y. Shih; T. N. Wang; J. Y. Shieh; S. Y. Lin; S. J. Ruan; H. H. Tang; H. L. Chen · J Neuroeng Rehabil2023
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Developing a framework for utilizing adjunct rehabilitation therapies in motor recovery of upper extremity post stroke
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Effects of Intensive Versus Distributed Constraint-Induced Movement Therapy for Children With Unilateral Cerebral Palsy: A Quasi-Randomized Trial
T. N. Wang; K. J. Liang; Y. C. Liu; J. Y. Shieh; H. L. Chen · Neurorehabil Neural Repair2023
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Upper limb manual training for children with cerebral palsy: A systematic review and network meta-analysis of randomized controlled trials
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Adjunct therapies after botulinum toxin injections in spastic adults: Systematic review and SOFMER recommendations
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Goal-Directed Personalized Upper Limb Intensive Therapy (PULIT) for Children With Hemiparesis: A Retrospective Analysis
G. L. P. Bono; P. Achermann; B. Rückriem; J. Lieber; H. J. A. van Hedel · Am J Occup Ther2022
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Tactile Sensation Improves Following Motor Rehabilitation for Chronic Stroke: The VIGoROUS Randomized Controlled Trial
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Cost-Effectiveness of Constraint-Induced Movement Therapy Implementation in Neurorehabilitation: The ACTIveARM Project
L. J. Christie; N. Fearn; A. McCluskey; M. Lovarini; R. Rendell; A. Pearce · Pharmacoecon Open2022
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Single Blind Randomized Controlled Trial of Modified Constraint-Induced Movement Therapy in Infants With the Sequelas of Unilateral Brachial Plexus Injury
Z. Cui; L. Liu; X. Chen; H. Zeng; S. Zheng; D. Wu · Front Hum Neurosci2022
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Constraint-Induced Movement Therapy for Infants With or at Risk for Cerebral Palsy: A Scoping Review
M. C. Dionisio; A. L. Terrill · Am J Occup Ther2022
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Video game rehabilitation for outpatient stroke (VIGoROUS): A multi-site randomized controlled trial of in-home, self-managed, upper-extremity therapy
L. V. Gauthier; D. S. Nichols-Larsen; G. Uswatte; N. Strahl; M. Simeo; R. Proffitt; K. Kelly; R. Crawfis; E. Taub; D. Morris; L. P. Lowes; V. Mark; A. Borstad · EClinicalMedicine2022
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Interventions to improve physical function for children and young people with cerebral palsy: international clinical practice guideline
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Exploring Clinical and Neurophysiological Factors Associated with Response to Constraint Therapy and Brain Stimulation in Children with Hemiparetic Cerebral Palsy
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The Effect of the Modified Constraint-Induced Movement Therapy on the Upper Extremity Functions of Obstetric Brachial Plexus Palsy Patients
B. Kuran; S. D. Azrak; B. Dogu; F. Yilmaz; H. Sirzai; J. Oncu; R. Terlemez; A. Ayyildiz · Sisli Etfal Hastan Tip Bul2022
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Effects of a lower limb rehabilitation robot with various training modes in patients with stroke: A randomized controlled trial
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Feasibility of High Repetition Upper Extremity Rehabilitation for Children with Unilateral Cerebral Palsy
M. J. Metzler; K. O'Grady; L. Fay; M. Herrero; M. Dunbar; D. Fehlings; J. Andersen; A. Kirton · Physical & Occupational Therapy in Pediatrics2022
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Impact of Constraint-Induced Movement Therapy (CIMT) on Functional Ambulation in Stroke Patients-A Systematic Review and Meta-Analysis
R. S. Reddy; K. Gular; S. Dixit; P. K. Kandakurti; J. S. Tedla; A. P. Gautam; D. R. Sangadala · Int J Environ Res Public Health2022
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Network Meta-Analysis of Non-Conventional Therapies for Improving Upper Limb Motor Impairment Poststroke
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Worldwide Survey of Clinician Practice on use of Adjunctive Therapies Following Botulinum Toxin Injection for Spasticity
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Effects of Dual Transcranial Direct Current Stimulation and Modified Constraint Induced Movement Therapy to Improve Upper-Limb Function After Stroke: A Double-Blinded, Pilot Randomized Controlled Trial
R. Sharma; V. P. Aranha; A. Saxena; A. J. Samuel · W B Saunders2022
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Robot-Assisted Training as Self-Training for Upper-Limb Hemiplegia in Chronic Stroke: A Randomized Controlled Trial
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Current knowledge and practice of post-stroke unilateral spatial neglect rehabilitation: A cross-sectional survey of South African neurorehabilitation physiotherapists
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Comparison of the Effects of Constraint-Induced Movement Therapy and Unconstraint Exercise on Oxidative Stress and Limb Function-A Study on Human Patients and Rats with Cerebral Infarction
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Effects of cerebellar transcranial direct current stimulation on upper limb motor function after stroke: study protocol for the pilot of a randomized controlled trial
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Combination of constraint-induced movement therapy with fasudil amplifies neurogenesis after focal cerebral ischemia/reperfusion in rats
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Comparing Two Different Modes of Task Practice during Lower Limb Constraint-Induced Movement Therapy in People with Stroke: A Randomized Clinical Trial
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Effect of constraint-induced movement therapy on persons-reported outcomes of health status after stroke: a systematic review and meta-analysis
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M. T. Correr Ribeiro; L. Iara Pfeifer · Fisioterapia em Movimento2021
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Early intervention evidence for infants with or at risk for cerebral palsy: an overview of systematic reviews
D. L. Damiano; E. Longo · Dev Med Child Neurol2021
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Rehabilitation in multiple sclerosis in 2021
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Improvements in Upper Extremity Function Following Intensive Training Are Independent of Corticospinal Tract Organization in Children With Unilateral Spastic Cerebral Palsy: A Clinical Randomized Trial
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PCORI Final Research Reports
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Timing and Dose of Upper Limb Motor Intervention After Stroke: A Systematic Review
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The clinical effect of Kinesio taping and modified constraint-induced movement therapy on upper extremity function and spasticity in patients with stroke: a randomized controlled pilot study
H. C. Hsieh; R. D. Liao; T. H. Yang; C. P. Leong; H. H. Tso; J. Y. Wu; Y. C. Huang · Eur J Phys Rehabil Med2021
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Parents' Perspectives on a Computer Game-Assisted Rehabilitation Program for Manual Dexterity in Children With Cerebral Palsy: Qualitative Analysis of Expectations, Child Engagement, and Benefits
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Effects of Dual Transcranial Direct Current Stimulation and Modified Constraint-Induced Movement Therapy to Improve Upper-Limb Function after Stroke: A Double-Blinded, Pilot Randomized Controlled Trial
S. H. Kim · J Stroke Cerebrovasc Dis2021
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A hybrid model of modified constraint induced movement therapy to improve upper extremity performance in children with unilateral upper extremity paresis: Retrospective case series
G. K. Lee; M. Pascual; S. A. Rethlefsen · British Journal of Occupational Therapy2021
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Early interventions in infants with unilateral cerebral palsy: A systematic review and narrative synthesis
L. Mailleux; N. De Beukelaer; M. B. Carbone; E. Ortibus · Res Dev Disabil2021
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R. A. Mohamed; A. M. Yousef; N. L. Radwan; M. M. Ibrahim · Eur Rev Med Pharmacol Sci2021
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Constraint-Induced Movement Therapy Combined With Botulinum Toxin for Post-stroke Spasticity: A Systematic Review and Meta-Analysis
M. Nasb; S. Z. A. Shah; H. Chen; A. S. Youssef; Z. Li; L. Dayoub; A. Noufal; A. E. S. Allam; M. Hassanien; A. A. El Oumri; K. V. Chang; W. T. Wu; M. Rekatsina; F. Galluccio; A. AlKhrabsheh; A. Salti; G. Varrassi · Cureus2021
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Efficacy of the use of unaffected hand containment in unimanual intensive therapy to increase visuomotor coordination in children with hemiplegia: a randomized controlled pilot study
R. Palomo-Carrión; E. Bravo-Esteban; S. Ando-La Fuente; P. López-Muñoz; I. Martínez-Galán; H. Romay-Barrero · Ther Adv Chronic Dis2021
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Constraint-Induced Movement Therapy for Cerebral Palsy: A Randomized Trial
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Corpus Callosum Integrity Relates to Improvement of Upper-Extremity Function Following Intensive Rehabilitation in Children With Unilateral Spastic Cerebral Palsy
M. T. Robert; J. Gutterman; C. L. Ferre; K. Chin; M. B. Brandao; A. M. Gordon; K. Friel · Neurorehabil Neural Repair2021
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Constraint Induced Movement Therapy Camp for Children with Hemiplegic Cerebral Palsy Augmented by Use of an Exoskeleton to Play Games in Virtual Reality
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Constraint Induced Movement Therapy Increases Functionality and Quality of Life after Stroke
L. S. O. Rocha; G. C. B. Gama; R. S. B. Rocha; L. B. Rocha; C. P. Dias; L. L. S. Santos; M. C. S. Santos; M. I. L. Montebelo; R. M. Teodori · J Stroke Cerebrovasc Dis2021
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Robot-Assisted Therapy and Constraint-Induced Movement Therapy for Motor Recovery in Stroke: Results From a Randomized Clinical Trial
T. T. Terranova; M. Simis; A. C. A. Santos; F. M. Alfieri; M. Imamura; F. Fregni; L. R. Battistella · Front Neurorobot2021
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Tele-rehabilitation of upper-extremity hemiparesis after stroke: Proof-of-concept randomized controlled trial of in-home Constraint-Induced Movement therapy
G. Uswatte; E. Taub; P. Lum; D. Brennan; J. Barman; M. H. Bowman; A. Taylor; S. McKay; S. B. Sloman; D. M. Morris; V. W. Mark · Restor Neurol Neurosci2021
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Responsiveness of kinematic and clinical measures of upper-limb motor function after stroke: A systematic review and meta-analysis
C. Villepinte; A. Verma; C. Dimeglio; X. De Boissezon; D. Gasq · Ann Phys Rehabil Med2021
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Constraint-induced movement therapy for children with neonatal brachial plexus palsy: a randomized crossover trial
J. M. Werner; J. Berggren; J. Loiselle; G. K. Lee · Dev Med Child Neurol2021
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The effects of modified constraint-induced movement therapy combined with intensive bimanual training in children with brachial plexus birth injury: a retrospective data base study
I. M. Zielinski; R. van Delft; J. M. Voorman; A. C. H. Geurts; B. Steenbergen; P. B. M. Aarts · Disability & Rehabilitation2021
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Use of a Caregiver Coaching Model for Implementation of Intensive Motor Training for Hemiplegic Cerebral Palsy: A Case Study
S. E. Zylstra; A. Sidhu · Open Journal of Occupational Therapy (OJOT)2021
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Comparison of Task Oriented Therapy and Modified Constraint Induced Movement Therapy along with Functional Electrical Stimulation to Improve Hand Function In Sub Acute Stroke survivors: a Randomized Control Trial
N. Bhalla; N. Shergill · Indian Journal of Physiotherapy & Occupational Therapy2020
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144
Accelerometer Measurements Indicate That Arm Movements of Children With Cerebral Palsy Do Not Increase After Constraint-Induced Movement Therapy (CIMT)
B. M. Goodwin; E. K. Sabelhaus; Y.-C. Pan; K. F. Bjornson; K. L. D. Pham; W. O. Walker; K. M. Steele · American Journal of Occupational Therapy2020
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Intensive Unimanual Training Leads to Better Reaching and Head Control than Bimanual Training in Children with Unilateral Cerebral Palsy
Y.-C. Hung; A. Spingarn; K. M. Friel; A. M. Gordon · Physical & Occupational Therapy in Pediatrics2020
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Effect of Modified Constrain Induced Movement Therapy on Fatigue and Motor Performance in Sub Acute Stroke
W. Mushtaq; N. Hamdani; M. M. Noohu; S. Raghavan · Journal of Stroke & Cerebrovascular Diseases2020
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Unimanual Intensive Therapy with or without Unaffected Hand Containment in Children with Hemiplegia. A Randomized Controlled Pilot Study
R. Palomo-Carrión; E. Pinero-Pinto; S. Ando-LaFuente; A. Ferri-Morales; E. Bravo-Esteban; H. Romay-Barrero · J Clin Med2020
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Exploration of barriers and enablers for evidence-based interventions for upper limb rehabilitation following a stroke: Use of Constraint Induced Movement Therapy and Robot Assisted Therapy in NHS Scotland
G. Sweeney; M. Barber; A. Kerr · British Journal of Occupational Therapy2020
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Predicting clinically significant motor function improvement after contemporary task-oriented interventions using machine learning approaches
H. K. Thakkar; W.-w. Liao; C.-y. Wu; Y.-W. Hsieh; T.-H. Lee · Journal of NeuroEngineering & Rehabilitation (JNER)2020
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A Pilot Study of Two Different Constraint-Induced Movement Therapy Interventions in Children With Hemiplegic Cerebral Palsy After Botulinum Toxin Injection During Preschool Education
C. L. Wu; S. F. Liao; C. H. Liu; Y. T. Hsieh; Y. R. Lin · Front Pediatr2020
Pilot/feasibilitydoi:10.3389/fped.2020.00557

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