Gabriel Delgado-Oleas scite author profile

Tremor is defined as a rhythmic, involuntary oscillatory movement of a body part. Although everyone exhibits a certain degree of tremor, some pathologies lead to very disabling tremors. These pathological tremors constitute the most prevalent movement disorder, and they imply severe difficulties in performing activities of daily living. Although tremors are currently managed through pharmacotherapy or surgery, these treatments present significant associated drawbacks: drugs often induce side effects and show decreased effectiveness over years of use, while surgery is a hazardous procedure for a very low percentage of eligible patients. In this context, recent research demonstrated the feasibility of managing upper limb tremors through wearable technologies that suppress tremors by modifying limb biomechanics or applying counteracting forces. Furthermore, recent experiments with transcutaneous afferent stimulation showed significant tremor attenuation. In this regard, this article reviews the devices developed following these tremor management paradigms, such as robotic exoskeletons, soft robotic exoskeletons, and transcutaneous neurostimulators. These works are presented, and their effectiveness is discussed. The article also evaluates the different metrics used for the validation of these devices and the lack of a standard validation procedure that allows the comparison among them.

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Development and Evaluation of BenchBalance: A System for Benchmarking Balance Capabilities of Wearable Robots and Their Users

Bayón

Delgado-Oleas

Avellar

et al. 2021

Sensors

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Recent advances in the control of overground exoskeletons are being centered on improving balance support and decreasing the reliance on crutches. However, appropriate methods to quantify the stability of these exoskeletons (and their users) are still under development. A reliable and reproducible balance assessment is critical to enrich exoskeletons’ performance and their interaction with humans. In this work, we present the BenchBalance system, which is a benchmarking solution to conduct reproducible balance assessments of exoskeletons and their users. Integrating two key elements, i.e., a hand-held perturbator and a smart garment, BenchBalance is a portable and low-cost system that provides a quantitative assessment related to the reaction and capacity of wearable exoskeletons and their users to respond to controlled external perturbations. A software interface is used to guide the experimenter throughout a predefined protocol of measurable perturbations, taking into account antero-posterior and mediolateral responses. In total, the protocol is composed of sixteen perturbation conditions, which vary in magnitude and location while still controlling their orientation. The data acquired by the interface are classified and saved for a subsequent analysis based on synthetic metrics. In this paper, we present a proof of principle of the BenchBalance system with a healthy user in two scenarios: subject not wearing and subject wearing the H2 lower-limb exoskeleton. After a brief training period, the experimenter was able to provide the manual perturbations of the protocol in a consistent and reproducible way. The balance metrics defined within the BenchBalance framework were able to detect differences in performance depending on the perturbation magnitude, location, and the presence or not of the exoskeleton. The BenchBalance system will be integrated at EUROBENCH facilities to benchmark the balance capabilities of wearable exoskeletons and their users.

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Análisis de movimiento mediante textil inteligente

Delgado-Oleas¹,

Avellar²,

Stefano-Filho³

et al. 2022

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Este artículo presenta el desarrollo de un textil inteligente (smart garment) portátil dotado de 30 sensores de fibra óptica multiplexados que, a través de algoritmos de Inteligencia Artificial (IA), es capaz de clasificar de actividades de múltiples sujetos. Se evalúan seis actividades diarias: de pie, sentado, en cuclillas, brazos arriba y abajo, caminar y correr. El clasificador utilizado es el de k vecinos más cercanos y los resultados de 10 ensayos de todos los voluntarios presentaron una precisión de 94,00 (0,14) %. La cadencia y la frecuencia respiratoria se estimaron y compararon con los datos de una unidad de medición inercial ubicada en la parte posterior de la prenda. El error más alto fue del 2,22 %. El enfoque propuesto presentó la viabilidad para el reconocimiento de actividad y la extracción de parámetros relacionados con el movimiento, en el ámbito de los desarrollos en Healthcare 4.0.

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