[1] Dobkin BH. Clinical practice. Rehabilitation after stroke. New England Journal of Medicine. 2005;352(16):1677-1684.
[2] Kwakkei G, Kollen BJ. Predicting activities after stroke what is clinically relevant?. International Journal of Stroke. 2013;8:25-32.
[3] Cunningham P, Turton AJ, Van Wijck F, & Van Vliet P. Task-specific reach-to-grasp training after stroke: development and description of a home-based intervention. Clinical Rehabilitation. 2016;30(8):731-740.
[4] Cauraugh JH & Kim SB. Stroke motor recovery: active neuromuscular stimulation and repetitive practice schedules. Journal of Neurology, Neurosurgery & Psychiatry. 2003;74(11):1562-1566.
[5] Bayona NA, Bitensky J, Salter K & Teasell R. The role of task-specific training in rehabilitation therapies. Topics in stroke rehabilitation. 2005;12(3):58-65.
[6] Galea MP, Miller KJ, & Kilbreath SL. Early task-related training enhances upper limb function following stroke. Poster presentation (March 25 – 30, 2001) at the annual meeting of the Society for Neural Control of Movementvi. Spain: Sevilla; 2001.
[7] Page SJ. Intensity versus task-specificity after stroke: how important is intensity?. American Journal of Physical Medicine & Rehabilitation. 2003;82(9):730-732.
[8] Timmermans AA, Seelen HA, Willmann RD, Rakx W, de Ruyter B, Lanfermann G, & Kingma H. Arm and hand skills: Training preferences after stroke. Disability and Rehabilitation. 2009;31:1344-52.
[9] Schultheis MT & Rizzo AA. The application of virtual reality technology in rehabilitation. Rehabilitation Psychology. 2001;46(3):296.
[10] De Mauro A. Virtual reality based rehabilitation and game technology. Engineering Interactive Computer Systems for Medicine and Healthcare. 2011;1:48-52.
[11] Fong KNK, Chow KKY, Chan BCH, Lam KCK, Lee JCK, Li THY, Yan EWH & Wong AKY. Usability of a virtual reality environment simulating an automated teller machine for assessing and training persons with acquired brain injury. Journal of NeuroEngineering and Rehabilitation. 2010;7(19):1-9.
[12] Saposnik G, Levin M & Stroke Outcome Research Canada (SORCan) Working Group. Virtual reality in stroke rehabilitation: a meta-analysis and implications for clinicians. Stroke. 2011;42(5):1380-1386.
[13] Shin JH, Kim MY, Lee JY, et al. Effects of virtual reality-based rehabilitation on distal upper extremity function and health-related quality of life: a single-blinded, randomized controlled trial. Journal of NeuroEngineering and Rehabilitation. 2016;13(1):17.
[14] Tang YM, Au KMK & Leung Y. Comprehending Products with Mixed Reality (MR): Geometric Relationships and Creativity. International Journal of Engineering Business Management. 2018;10:1–12. [DOI:10.1177/1847979018809599]
[15] Okazaki S, Muraoka Y, & Suzuki R. Validity and Reliability of Leap Motion Controller for Assessing Grasping and Releasing Finger Movements. Journal of Ergonomic Technology. 2017;17(1):32-42.
[16] Weichert F, Bachmann D, Rudak B & Fisseler D. Analysis of the Accuracy and Robustness of the Leap Motion Controller. Sensors. 2013;13(5):6380-6393.
[17] Lee B, Lee D & Chin S. Structural Motion Grammar for Universal Use of LeapMotion: Amusement and Functional Contents Focused. Journal of Sensors. 2018;6073786:1-15.
[18] Fernández-González P, Carratalá-Tejada M, Monge-Pereira E, et al. Leap motion controlled video game-based therapy for upper limb rehabilitation in patients with Parkinson’s disease: a feasibility study. Journal of NeuroEngineering and Rehabilitation. 2019;16:133. Available from:. https://doi.org/10.1186/s12984-019-0593-x
[19] Wang ZR, Wang P, Xing L, Mei LP, Zhao J, Zhang T. Leap Motion-based virtual reality training for improving motor functional recovery of upper limbs and neural reorganization in subacute stroke patients. Neural Regen Res. 2017;12(11):1823-1831. [DOI:10.4103/1673-5374.219043]
[20] Bohannon RW & Smith MB. Interrater reliability of a modified Ashworth scale of muscle spasticity. Physical Therapy. 1987;67:206-207.
[21] Fong K, Ng B, Chan D, et al. Development of the Hong Kong version of the Functional Test for the Hemiplegic Upper Extremity (FTHUE-HK). Hong Kong Journal of Occupational Therapy. 2004;14:21-29.
[22] Wilson DJ, Baker LL, & Craddock JA. Functional test for the hemiplegic upper extremity. American Journal of Occupational Therapy. 1984;38:159-164.
[23] Colgan A. How Does the Leap Motion Controller Work?. Leap Motion Blog. 2017 Jan 18. Available from:. blog.leapmotion.com/hardware-to-software-how-does-the-leap-motion-controller-work/.
[24] Krastev G & Andreeva M. A Software Tool for Experimental Study Leap Motion. International Journal of Computer Science & Information Technology. 2015;7(6):145-153.
[25] Duncan PW, Propst M & Nelson SG. Reliability of the Fugl-Meyer assessment of sensorimotor recovery following cerebrovascular accident. Physical Therapy. 1983;63(10):1606-1610.
[26] Fugl-Meyer AR & Jaasko L. Post-stroke hemiplegia and ADL performance. Scandinavian Journal of Rehabilitation Medicine. 1980;7:140-152.
[27] Wolf SL, Thompson PA, Morris DM, Rose DK, Winstein CJ, Taub E, et al. The EXCITE trial attributes of the Wolf Motor Function Test in patients with subacute stroke. Neurorehabilitation and Neural Repair. 2005;19:194-205.
[28] Fugl-Meyer AR, Jääskö L, Leyman I, Olsson S, Steglind S. The post-stroke hemiplegic patient. 1. a method for evaluation of physical performance. Scand J Rehabil Med. 1975;7(1):13-31.
[29] Ng AKY, Leung DPK & Fong KNK. Clinical utility of the Action Research Arm Test, Wolf Motor Function Test and the Motor Activity Log of hemiparetic upper extremity functions after stroke: a pilot study. Hong Kong Journal of Occupational Therapy. 2008;18(1):20-27.
[30] Uswatte G, Taub E, Morris D, Light K & Thompson PA. The Motor Activity Log-28: assessing daily use of the hemiparetic arm after stroke. Neurology. 2006;67:1189-1194.
[31] Magill RA & Anderson DI. Motor learning and control: Concepts and applications (Vol. 11). New York: McGraw-Hill; 2007.
[32] Seo NJ, Kumar JA, Hur P, Crocher V, Motawar B & Lakshminarayanan K. Usability evaluation of low-cost virtual reality hand and arm rehabilitation games. Journal of Rehabilitation Research and Development. 2016;53(3):321-334.