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{"title":"Creating a Virtual Perception for Upper Limb Rehabilitation","authors":"Nina Robson, Kenneth John Faller II, Vishalkumar Ahir, Arthur Ricardo Deps Miguel Ferreira, John Buchanan, Amarnath Banerjee","volume":124,"journal":"International Journal of Biomedical and Biological Engineering","pagesStart":152,"pagesEnd":158,"ISSN":"1307-6892","URL":"https:\/\/publications.waset.org\/pdf\/10006823","abstract":"This paper describes the development of a virtual-reality system ARWED, which will be used in physical rehabilitation of patients with reduced upper extremity mobility to increase limb Active Range of Motion (AROM). The ARWED system performs a symmetric reflection and real-time mapping of the patient’s healthy limb on to their most affected limb, tapping into the mirror neuron system and facilitating the initial learning phase. Using the ARWED, future experiments will test the extension of the action-observation priming effect linked to the mirror-neuron system on healthy subjects and then stroke patients.","references":"[1]\tJ. A. Beebe and C. E. Lang, \"Active Range of Motion Predicts Upper Extremity Function 3 Months After Stroke,\" Stroke, vol. 40, pp. 1772-1779, 2009.\r\n[2]\tN. Hogan, & Krebs, H. I., \"Interactive robots for neuro-rehabilitation,\" Restor Neurol Neurosci, vol. 22, pp. 349-358, 2004.\r\n[3]\tJ. W. Krakauer, \"Motor learning: its relevance to stroke recovery and neurorehabilitation.,\" Curr Opin Neurol, vol. 19, pp. 84-90, 2006.\r\n[4]\tBuchanan, J.J., Ramos, J. & Robson, N, \u201cSimulated human arm motion drives perception-action learning in post-stroke individuals,\u201d Program No. 563.17. 2013 Neuroscience Meeting Planner, San Diego, CA: Neuroscience, 2013.\r\n[5]\tD. Maslovat, Hodges, N. J., Krigolson, O. E., & Handy, T. 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