Volition-adaptive control for gait training using wearable exoskeleton: preliminary tests with incomplete spinal cord injury individuals
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Fecha
2018-01-03
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BMC
Resumen
Background
Gait training for individuals with neurological disorders is challenging in providing the suitable assistance and more adaptive behaviour towards user needs. The user specific adaptation can be defined based on the user interaction with the orthosis and by monitoring the user intentions. In this paper, an adaptive control model, commanded by the user intention, is evaluated using a lower limb exoskeleton with incomplete spinal cord injury individuals (SCI).
Methods
A user intention based adaptive control model has been developed and evaluated with 4 incomplete SCI individuals across 3 sessions of training per individual. The adaptive control model modifies the joint impedance properties of the exoskeleton as a function of the human-orthosis interaction torques and the joint trajectory evolution along the gait sequence, in real time. The volitional input of the user is identified by monitoring the neural signals, pertaining to the user’s motor activity. These volitional inputs are used as a trigger to initiate the gait movement, allowing the user to control the initialization of the exoskeleton movement, independently. A Finite-state machine based control model is used in this set-up which helps in combining the volitional orders with the gait adaptation.
Results
The exoskeleton demonstrated an adaptive assistance depending on the patients’ performance without guiding them to follow an imposed trajectory. The exoskeleton initiated the trajectory based on the user intention command received from the brain machine interface, demonstrating it as a reliable trigger. The exoskeleton maintained the equilibrium by providing suitable assistance throughout the experiments. A progressive change in the maximum flexion of the knee joint was observed at the end of each session which shows improvement in the patient performance. Results of the adaptive impedance were evaluated by comparing with the application of a constant impedance value. Participants reported that the movement of the exoskeleton was flexible and the walking patterns were similar to their own distinct patterns.
Conclusions
This study demonstrates that user specific adaptive control can be applied on a wearable robot based on the human-orthosis interaction torques and modifying the joints’ impedance properties. The patients perceived no external or impulsive force and felt comfortable with the assistance provided by the exoskeleton. The main goal of such a user dependent control is to assist the patients’ needs and adapt to their characteristics, thus maximizing their engagement in the therapy and avoiding slacking. In addition, the initiation directly controlled by the brain allows synchronizing the user’s intention with the afferent stimulus provided by the movement of the exoskeleton, which maximizes the potentiality of the system in neuro-rehabilitative therapies.
Descripción
Esta publicacion ha sido realizada en los proyectos de investigación HYPER (Hybrid Neuroprosthetic and Neurorobotic devices for functional compensation and rehabilitation of motor disorders), Ref.: CSD2009-00067 CONSOLIDER-INGENIO (MINECO), y Proyecto AURORA (Distributed control strategies and human-robot cooperation in health care settings), Ref.: DPI2015-70415-C2-1-R (MINECO)
Contribución según taxonomía CReDIT: Investigation, Resources, Supervisión, Writting: review & editing.
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Indicios de calidad:
- A nivel del medio de difusión
Revista con revisión por pares doble ciego indexada en JCR, en el primer cuartil (Q1) y primer tercil (T1) en las categorías de Ingeniería Biomédica (JCR) y Health Informatics Instruments & Instrumentation (Scopus), con factor de impacto 3.852 en el año de publicación del artículo (2018)
- A nivel de aportación.
El artículo ha recibido bastante atención en los años desde su publicación dentro de su ámbito de conocimiento, como lo demuestra los índices normalizados de citas (1.21 (FWCI, Scoups) y 3.39 (FCR, Dimensions)), situándose en el percentil 76 de artículos más citados dentro de su ámbito de conocimeinto (Scopus)
El impacto también se ve reflejado a través de las métricas de uso y acceso a través de las principales redes de interacción científica: Mendeley (156 accesos) y ResearchGate (401 accesos).
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Citación
Rajasekaran, V., López-Larraz, E., Trincado-Alonso, F. et al. Volition-adaptive control for gait training using wearable exoskeleton: preliminary tests with incomplete spinal cord injury individuals. J NeuroEngineering Rehabil 15, 4 (2018)
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