Abstract
Upper-limb paresis is a main disabling condition in stroke and neurological diseases and rehabilitation is essential for recovering/maintaining function. Upper-limb weight support may help/enable these patients performing movements against gravity thus allowing for task oriented interventions. In this framework, an exoskeleton for upper-limb weight support was developed. In this preliminary study the system was tested in a small group of neurological patients (Nā=ā12) to verify the overall usability and its efficacy in assisting patients during functional movements against gravity. Patients performed some functional tasks of the ARAT test both with and without the exoskeleton. The system seems effective as it enabled even the most impaired patients performing the tasks. All patients could wear the exoskeleton and complete the tasks. Usability of the system was assessed as adequate for a use inside a clinical study. Future work will focus on verifying the efficacy of task-oriented intervention performed using the exoskeleton.
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References
Millan, M., Davalos, A.: The need for new therapies for acute ischemic stroke. Cerebrovasc. Dis. 22(Suppl 1), 3ā9 (2006)
Bertoni, R., Lamers, I., Chen, C., Feys, P., Cattaneo, D.: Unilateral and bilateral upper limb dysfunction at body functions, activity and participation levels in people with MS. Mult. Scler. 21(12), 1566 (2015)
Taveggia, G., Borboni, A., Salvi, L., et al.: Efficacy of robot-assisted rehab for the functional recovery of the upper limb in post-stroke patients: a randomized controlled study. Eur. J. Phys. Rehabil. Med. 52, 767 (2016)
Gijbels, D., Lamers, I., Kerkhofs, L., Alders, G., Knippenberg, E., Feys, P.: The Armeo Spring as training tool to improve upper limb functionality in multiple sclerosis: a pilot study. J. Neuroeng. Rehabil. 8, 5 (2011)
Choi, Y., Gordon, J., Park, H., Schweighofer, N.: Feasibility of the adaptive and automatic presentation of tasks system for rehabilitation of upper extremity function post-stroke. J. Neuroeng. Rehabil. 8, 42 (2011)
Carpinella, I., Cattaneo, D., Bertoni, R., Ferrarin, M.: Robot training of upper limb in multiple sclerosis: comparing protocols with or without manipulative task. IEEE Trans. Neural Syst. Rehabil. Eng. 20, 351 (2012)
Scano, A., Spagnuolo, G., Caimmi, M., Chiavenna, A., Malosio, M., Legnani, G., Tosatti, L.M.: Static and dynamic characterization of the LIGHTarm exoskeleton for rehabilitation. In: IEEE ICORR (2015)
Spagnuolo, G., Malosio, M., Scano, A., Caimmi, M., Legnani, G., et al.: Passive and active gravity-compensation of LIGHTarm, an exoskeleton for the upper-limb rehabilitation. In: IEEE ICORR (2015)
Carroll, D.: A quantitative test of upper extremity function. J. Chronic Dis. 18, 479ā491 (1965)
PĆ©rez, R., Costa, Ć., Torrent, M., Solana, J., Opisso, E., et al.: Upper limb portable motion analysis system based on inertial technology for neurorehabilitation purposes. Sensors (Basel) 10, 10733ā10751 (2010)
Brooke, J.: SUS: a āquick and dirtyā usability scaleā. In: Jordan, P.W., Thomas, B., Weerdmeester, B.A., McClelland, A.L. (eds.) Usability Evaluation In Industry (1996)
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Caimmi, M. et al. (2019). Preliminary Usability and Efficacy Tests in Neurological Patients of an Exoskeleton for Upper-Limb Weight Support. In: Carrozza, M., Micera, S., Pons, J. (eds) Wearable Robotics: Challenges and Trends. WeRob 2018. Biosystems & Biorobotics, vol 22. Springer, Cham. https://doi.org/10.1007/978-3-030-01887-0_68
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DOI: https://doi.org/10.1007/978-3-030-01887-0_68
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