Stroke Clinical Trial
Official title:
Robot-Aided Assessment and Rehabilitation of Upper Extremity Function After Stroke
The purpose of this clinical trial is to investigate the efficacy of a hybrid-based rehabilitation program for the upper extremity(UE) combining the interventions- Functional Electrical Stimulation (FES) and Robotic rehabilitation in individuals with chronic stroke. The main question it aims to answer is if the Hybrid multi-muscle FES+Robot upper extremity rehabilitation is more effective in improving the upper extremity motor impairments and function as compared to robotic upper extremity training alone.
| Status | Recruiting |
| Enrollment | 24 |
| Est. completion date | June 30, 2024 |
| Est. primary completion date | May 30, 2024 |
| Accepts healthy volunteers | No |
| Gender | All |
| Age group | 22 Years to 85 Years |
| Eligibility | Inclusion Criteria: 1. Individuals with chronic stroke(>6months post stroke) 2. Age-22-85 years old 3. Ability to perform a Upper Extremity forward reach of about 3 inches Exclusion Criteria: 1. Upper Extremity co-morbidities-pain, arthritis, and other neurological disorders 2. Unable to tolerate electrical stimulation 3. Have implants such as pacemaker, spinal cord or deep brain stimulator 4. Have an elbow contracture of greater than 150 degrees 5. Receiving Botox injections within 3 months |
| Country | Name | City | State |
|---|---|---|---|
| United States | University of Maryland School of Medicine | Baltimore | Maryland |
| Lead Sponsor | Collaborator |
|---|---|
| University of Maryland, Baltimore |
United States,
Ambrosini E, Zajc J, Ferrante S, Ferrigno G, Gasperina SD, Bulgheroni M, Baccinelli W, Schauer T, Wiesener C, Russold M, Gfoehler M, Puchinger M, Weber M, Becker S, Krakow K, Immick N, Augsten A, Rossini M, Proserpio D, Gasperini G, Molteni F, Pedrocchi A. A Hybrid Robotic System for Arm Training of Stroke Survivors: Concept and First Evaluation. IEEE Trans Biomed Eng. 2019 Dec;66(12):3290-3300. doi: 10.1109/TBME.2019.2900525. Epub 2019 Jun 5. — View Citation
Collins KC, Kennedy NC, Clark A, Pomeroy VM. Kinematic Components of the Reach-to-Target Movement After Stroke for Focused Rehabilitation Interventions: Systematic Review and Meta-Analysis. Front Neurol. 2018 Jun 25;9:472. doi: 10.3389/fneur.2018.00472. eCollection 2018. — View Citation
Duret C, Grosmaire AG, Krebs HI. Robot-Assisted Therapy in Upper Extremity Hemiparesis: Overview of an Evidence-Based Approach. Front Neurol. 2019 Apr 24;10:412. doi: 10.3389/fneur.2019.00412. eCollection 2019. — View Citation
Hughes AM, Freeman CT, Burridge JH, Chappell PH, Lewin PL, Rogers E. Feasibility of iterative learning control mediated by functional electrical stimulation for reaching after stroke. Neurorehabil Neural Repair. 2009 Jul-Aug;23(6):559-68. doi: 10.1177/1545968308328718. Epub 2009 Feb 3. — View Citation
Kahn LE, Zygman ML, Rymer WZ, Reinkensmeyer DJ. Robot-assisted reaching exercise promotes arm movement recovery in chronic hemiparetic stroke: a randomized controlled pilot study. J Neuroeng Rehabil. 2006 Jun 21;3:12. doi: 10.1186/1743-0003-3-12. — View Citation
Moon SH, Choi JH, Park SE. The effects of functional electrical stimulation on muscle tone and stiffness of stroke patients. J Phys Ther Sci. 2017 Feb;29(2):238-241. doi: 10.1589/jpts.29.238. Epub 2017 Feb 24. — View Citation
Resquin F, Cuesta Gomez A, Gonzalez-Vargas J, Brunetti F, Torricelli D, Molina Rueda F, Cano de la Cuerda R, Miangolarra JC, Pons JL. Hybrid robotic systems for upper limb rehabilitation after stroke: A review. Med Eng Phys. 2016 Nov;38(11):1279-1288. doi: 10.1016/j.medengphy.2016.09.001. Epub 2016 Sep 29. — View Citation
Turner DL, Ramos-Murguialday A, Birbaumer N, Hoffmann U, Luft A. Neurophysiology of robot-mediated training and therapy: a perspective for future use in clinical populations. Front Neurol. 2013 Nov 13;4:184. doi: 10.3389/fneur.2013.00184. — View Citation
Volpe BT, Lynch D, Rykman-Berland A, Ferraro M, Galgano M, Hogan N, Krebs HI. Intensive sensorimotor arm training mediated by therapist or robot improves hemiparesis in patients with chronic stroke. Neurorehabil Neural Repair. 2008 May-Jun;22(3):305-10. doi: 10.1177/1545968307311102. Epub 2008 Jan 9. — View Citation
| Type | Measure | Description | Time frame | Safety issue |
|---|---|---|---|---|
| Primary | Kinematic Assessment:Smoothness in 1/s2 | This measure will be collected as the participants performs target reaching out and in movements of the arm. Smoothness will be collected from the REACH robotic device to determine the kinematic changes in the reaching movements. Kinereach/trakStar system will also be utilized to conduct kinematic assessment and determine the translation of training effects into functional upper extremity use. | Change from Baseline Smoothness at 6 weeks | |
| Primary | Kinematic Assessment:Speed in cm/seconds | This measure will be collected as the participants performs target reaching out and in movements of the arm. Speed will be collected from the REACH robotic device to determine the kinematic changes in the reaching movements. Kinereach/trakStar system will also be utilized to conduct kinematic assessment and determine the translation of training effects into functional upper extremity use. | Change from Baseline Speed at 6 weeks | |
| Primary | Kinematic Assessment:Range of Motion(ROM) in cms | This measure will be collected as the participants performs target reaching out and in movements of the arm. ROM will be collected from the REACH robotic device to determine the kinematic changes in the reaching movements. Kinereach/trakStar system will also be utilized to conduct kinematic assessment and determine the translation of training effects into functional upper extremity use. | Change from Baseline ROM at 6 weeks | |
| Secondary | Fugl-Meyer Upper Extremity(FMA-UE) | FMA-UE is a standard measure for the clinical assessment of motor impairment. FMA mainly evaluates the degree of synergy pattern during volitional movements, along with reflex activity and coordination. It is based on 33 items and scores range from 0 to 66. A higher score means better motor function. | Change from Baseline FMA-UE at 6 weeks | |
| Secondary | Modified Ashworth Scale of muscle spasticity (MAS) | The MAS is a measurement of spasticity across specific muscle groups. The grading of spasticity ranges from 0 to 5 with higher score indicating worse functioning. | Change from Baseline MAS at 6 weeks | |
| Secondary | Wolf Motor Function Test (WMFT) | WMFT is a function based test designed to measure upper extremity movements and movement speed during functional tasks. The WMFT consists of 17 items, of which 15 measure time to perform functional tasks and 2 strength-based tasks. Two types of scores are recorded during the task:WMFT-TIME(time of the task) and WMFT-FAS (functional abilities). The maximum score of WMFT-TIME is 120 seconds, and a higher score means slower movement. WMFT-FAS is scored from 0 to 5, and a higher score indicates higher level of functional performance, better quality of the paretic upper extremity during the task. | Change from Baseline WMFT at 6 weeks |
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