1. James, SL, Theadom, A, Ellenbogen, RG, et al. Global, regional, and national burden of traumatic brain injury and spinal cord injury, 1990–2016: a systematic analysis for the Global Burden of Disease Study 2016. Lancet Neurol. 2019;18:56-87.
Google Scholar |
Crossref |
Medline2. Traumatic Brain Injury & Concussion: Basic Information. [Internet]. Atlanta, GA: Center for Disease Control and Prevention.
https://www.cdc.gov/traumaticbraininjury/get_the_ facts.html. Accessed July 25, 2021.
Google Scholar3. Taylor, CA, Bell, JM, Breiding, MJ, Xu, L. Traumatic brain injury–related emergency department visits, hospitalizations, and deaths—United States, 2007 and 2013. MMWR CDC Surveill Summ. 2017;66:1-16.
Google Scholar |
Crossref |
Medline4. Dixon, KJ . Pathophysiology of traumatic train injury. Phys Med Rehabil Clin N Am. 2017;28:215-225.
Google Scholar |
Crossref |
Medline5. Capizzi, A, Woo, J, Verduzco-Gutierrez, M. Traumatic brain injury: an overview of epidemiology, pathophysiology, and medical management. Med Clin North Am. 2020; 104:213-238.
Google Scholar |
Crossref |
Medline6. Allanson, F, Pestell, C, Gignac, GE, Yeo, YX, Weinborn, M. Neuropsychological predictors of outcome following traumatic brain injury in adults: a meta-analysis. Neuropsychol Rev. 2017; 27:187-201.
Google Scholar |
Crossref |
Medline7. Weber, E, Spirou, A, Chiaravalloti, N, Lengenfelder, J. Impact of frontal neurobehavioral symptoms on employment in individuals with TBI. Rehabil Psychol. 2018;63:383-391.
Google Scholar |
Crossref |
Medline8. Meulenbroek, P, Turkstra, LS. Job stability in skilled work and communication ability after moderate-severe traumatic brain injury. Disabil Rehabil. 2016;38:452-461.
Google Scholar |
Crossref |
Medline9. Oberholzer, M, Muri, RM. Neurorehabilitation of Traumatic Brain Injury (TBI): a clinical review. Med Sci 2019;7(3):47. doi:
10.3390/medsci7030047 Google Scholar |
Crossref10. Fulk, GD, Nirider, C. Physical Rehabilitation. 7th ed. Philadelphia, PA: FA Davis; 2019.
Google Scholar11. Lamontagne, ME, Bayley, MT, Marshall, S, et al. Assessment of users’ needs and expectations toward clinical practice guidelines to support the rehabilitation of adults with moderate to severe Traumatic Brain Injury. J Head Trauma Rehabil. 2018;33:288-295.
Google Scholar |
Crossref |
Medline12. Breceda, EY, Dromerick, AW. Motor rehabilitation in stroke and traumatic brain injury: stimulating and intense. Curr Opin Neurol. 2013;26:595-601.
Google Scholar |
Crossref |
Medline13. Glenn, MB, Shih, SL. Rehabilitation following TBI. In: JW, Tsao , ed. Traumatic Brain Injury: A Clinician’s Guide to Diagnosis, Management, and Rehabilitation. Springer; 2020:293-327.
Google Scholar |
Crossref14. Kleim, JA, Jones, TA. Principles of experience-dependent neural plasticity: implications for rehabilitation after brain damage. J Speech Lang Hear Res. 2008;51:S225–S239.
Google Scholar |
Crossref |
Medline |
ISI15. Bayley, M, Swaine, B, Lamontagne, ME, et al. INESSS-ONF Clinical Practice Guideline for the Rehabilitation of Adults with Moderate to Severe Traumatic Brain Injury. Toronto, ON, Canada: Ontario Neurotrauma Foundation; 2018.
https://braininjuryguidelines.org/modtosevere. Accessed July 25, 2021.
Google Scholar16. Dobkin, BH . Motor rehabilitation after stroke, traumatic brain, and spinal cord injury: common denominators within recent clinical trials. Curr Opin Neurol. 2009;22:563-569.
Google Scholar |
Crossref |
Medline |
ISI17. Vanderbeken, I, Kerckhofs, E. A systematic review of the effect of physical exercise on cognition in stroke and traumatic brain injury patients. NeuroRehabilitation. 2017;40:33-48.
Google Scholar |
Crossref |
Medline18. Hellweg, S, Johannes, S. Physiotherapy after traumatic brain injury: a systematic review of the literature. Brain Inj. 2008;22:365-373.
Google Scholar |
Crossref |
Medline19. Jang, SH . Review of motor recovery in patients with traumatic brain injury. NeuroRehabilitation. 2009;24:349-353.
Google Scholar |
Crossref |
Medline20. McCrea, PH, Eng, JJ, Hodgson, AJ. Biomechanics of reaching: clinical implications for individuals with acquired brain injury. Disabil Rehabil. 2002;24:534-541.
Google Scholar |
Crossref |
Medline |
ISI21. Andelic, N, Sigurdardottir, S, Tenovuo, O. Rehabilitation after severe TBI. In: T, Sundstrom, P-O, Grände, T, Luoto, C, Rosenlund, J, Undén, KG, Wester, eds. Management of Severe Traumatic Brain Injury Evidence, Tricks, and Pitfalls. 2nd ed. Springer; 2020:547-556.
Google Scholar |
Crossref22. Perumparaichallai, RK, Lewin, RK, Klonoff, PS. Community reintegration following holistic milieu-oriented neurorehabilitation up to 30 years post-discharge. NeuroRehabilitation. 2020;46:243-253.
Google Scholar |
Crossref |
Medline23. Soeker, MS, Van Rensburg, V, Travill, A. Individuals with traumatic brain injuries perceptions and experiences of returning to work in South Africa. Work. 2012;42:589-600.
Google Scholar |
Crossref |
Medline24. Eriksen, MB, Frandsen, TF. The impact of patient, intervention, comparison, outcome (PICO) as a search strategy tool on literature search quality: a systematic review. J Med Libr Assoc. 2018;106:420-431.
Google Scholar |
Crossref |
Medline25. Subramanian, SK, Fountain, M, Hood, A. Interventions to augment upper extremity motor improvement in individuals with a Traumatic Brain Injury: a systematic review [abstract]. Neurorehabil Neural Repair. 2018;32:1110-1111.
Google Scholar26. Husted, JA, Cook, RJ, Farewell, VT, Gladman, DD. Methods for assessing responsiveness: a critical review and recommendations. J Clin Epidemiol. 2000;53:459-468.
Google Scholar |
Crossref |
Medline |
ISI27. Cohen, J. The effect size index: d. Statistical power analysis for the behavioral sciences. 1988;2:284-288.
Google Scholar28. Morton, S, Barton, CJ, Rice, S, Morrissey, D. Risk factors and successful interventions for cricket-related low back pain: a systematic review. Br J Sports Med. 2014;48:685-691.
Google Scholar |
Crossref |
Medline |
ISI29. Downs, SH, Black, N. The feasibility of creating a checklist for the assessment of the methodological quality both of randomised and non-randomised studies of health care interventions. J Epidemiol Comm Health. 1998;52:377-384.
Google Scholar |
Crossref |
Medline |
ISI30. Hootman, JM, Driban, JB, Sitler, MR, Harris, KP, Cattano, NM. Reliability and validity of three quality rating instruments for systematic reviews of observational studies. Res Synth Methods. 2011;2(2):110-118. doi:
10.1002/jrsm.41 Google Scholar |
Crossref |
Medline31. Aubut, JA, Marshall, S, Bayley, M, Teasell, RW. A comparison of the PEDro and Downs and Black quality assessment tools using the acquired brain injury intervention literature. NeuroRehabilitation. 2013;32:95-102. doi:
10.3233/NRE-130826 Google Scholar |
Crossref |
Medline32. Subramanian, SK, Caramba, SM, Hernandez, OL, Morgan, QT, Cross, MK, Hirschhauser, CS. Is the Downs and Black scale a better tool to appraise the quality of the studies using virtual rehabilitation for post-stroke upper limb rehabilitation? In: WG, Wright, GG, Fluet, SK, Subramanian, M, Agmon, eds. Proceedings of the 2019 International Conference on Virtual Rehabilitation (ICVR); ; Tel Aviv, Israel. IEEE Publications. doi:
10.1109/ICVR46560.2019.8994724 Google Scholar33. O’Connor, SR, Tully, MA, Ryan, B, Bradley, JM, Baxter, GD, McDonough, SM. Failure of a numerical quality assessment scale to identify potential risk of bias in a systematic review: a comparison study. BMC Res Notes. 2015;8(1):224. doi:
10.1186/s13104-015-1181-1.
Google Scholar |
Crossref |
Medline34. Yablon, SA, Agana, BT, Ivanhoe, CB, Boake, C. Botulinum toxin in severe upper extremity spasticity among patients with traumatic brain injury: an open-labeled trial. Neurology. 1996;47:939-944.
Google Scholar |
Crossref |
Medline |
ISI35. Pavesi, G, Brianti, R, Medici, D, Mammi, P, Mazzucchi, A, Mancia, D. Botulinum toxin type A in the treatment of upper limb spasticity among patients with traumatic brain injury. J Neurol Neurosurg Psychiatr. 1998;64:419-420.
Google Scholar |
Crossref |
Medline36. Meythaler, JM, Guin-Renfroe, S, Johnson, A, Brunner, RM. Prospective assessment of tizanidine for spasticity due to acquired brain injury. Arch Phys Med Rehabil. 2001;82:1155-1163.
Google Scholar |
Crossref |
Medline37. Moseley, AM, Hassett, LM, Leung, J, Clare, JS, Herbert, RD, Harvey, LA. Serial casting versus positioning for the treatment of elbow contractures in adults with traumatic brain injury: a randomized controlled trial. Clin Rehabil. 2008;22:406-417.
Google Scholar |
SAGE Journals |
ISI38. Thibaut, A, Deltombe, T, Wannez, S, et al. Impact of soft splints on upper limb spasticity in chronic patients with disorders of consciousness: a randomized, single-blind, controlled trial. Brain Inj. 2015;29:830-836.
Google Scholar |
Crossref |
Medline39. Matsumoto-Miyazaki, J, Asano, Y, Yonezawa, S, et al. Acupuncture increases the excitability of the cortico-spinal system in patients with chronic disorders of consciousness following traumatic brain injury. J Altern Complement Med. 2016;22:887-894.
Google Scholar |
Crossref |
Medline40. Page, S, Levine, P. Forced use after TBI: promoting plasticity and function through practice. Brain Inj. 2003;17:675-684.
Google Scholar |
Crossref |
Medline41. Shaw, SE, Morris, DM, Uswatte, G, McKay, S, Meythaler, JM, Taub, E. Constraint-induced movement therapy for recovery of upper-limb function following traumatic brain injury. J Rehabil Res Dev. 2005;42:769-778.
Google Scholar |
Crossref |
Medline42. Morris, DM, Shaw, SE, Mark, VW, Uswatte, G, Barman, J, Taub, E. The influence of neuropsychological characteristics on the use of CI therapy with persons with traumatic brain injury. NeuroRehabilitation. 2006;21:131-137.
Google Scholar |
Crossref |
Medline |
ISI43. Cho, YW, Jang, SH, Lee, ZI, Song, JC, Lee, HK, Lee, HY. Effect and appropriate restriction period of constraint-induced movement therapy in hemiparetic patients with brain injury: a brief report. NeuroRehabilitation. 2005;20:71-74.
Google Scholar |
Crossref |
Medline44. Ustinova, KI, Leonard, WA, Cassavaugh, ND, Ingersoll, CD. Development of a 3D immersive videogame to improve arm-postural coordination in patients with TBI. J NeuroEng Rehabil. 2011;8:61. doi:
10.1186/1743-0003-8-61 Google Scholar |
Crossref |
Medline45. Ustinova, KI, Perkins, J, Leonard, WA, Hausbeck, CJ. Virtual reality game-based therapy for treatment of postural and co-ordination abnormalities secondary to TBI: a pilot study. Brain Inj. 2014;28:486-495.
Google Scholar |
Crossref |
Medline46. Mumford, N, Duckworth, J, Thomas, PR, Shum, D, Williams, G, Wilson, PH. Upper-limb virtual rehabilitation for traumatic brain injury: a preliminary within-group evaluation of the elements system. Brain Inj. 2012;26:166-176.
Google Scholar |
Crossref |
Medline47. Syed, UE, Kamal, A. Video game-based and conventional therapies in patients of neurological deficits: an experimental study. Disabil Rehabil Assist Technol. 2021;16:332-339.
Google Scholar |
Crossref |
Medline48. Buccellato, KH, Nordstrom, M, Murphy, JM, et al. A randomized feasibility trial of a novel, integrative, and intensive virtual rehabilitation program for service members post-acquired brain injury. Mil Med. 2020;185:e203-e211.
Google Scholar |
Medline49. Alon, G, Dar, A, Katz-Behiri, D, Weingarden, H, Nathan, R. Efficacy of a hybrid upper limb neuromuscular electrical stimulation system in lessening selected impairments and dysfunctions consequent to cerebral damage. J Neuro Rehab. 1998;12:73-79.
Google Scholar |
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