STELO: A New Modular Robotic Gait Device for Acquired Brain Injury-Exploring Its Usability

Overview

Journal Sensors (Basel)

Publisher MDPI

Specialty Biotechnology

Date 2024 Jan 11

PMID 38203060

Authors

Carlos Cumplido-Trasmonte

Eva Barquin-Santos

Maria Dolores Gor-Garcia-Fogeda

Alberto Plaza-Flores

David Garcia-Varela

Leticia Ibanez-Herran

Carlos Gonzalez-Alted

Paola Diaz-Valles

Cristina Lopez-Pascua

Arantxa Castrillo-Calvillo

Francisco Molina-Rueda

Roemi Fernandez

Elena Garcia-Armada

Affiliations

Soon will be listed here.

Abstract

In recent years, the prevalence of acquired brain injury (ABI) has been on the rise, leading to impaired gait functionality in affected individuals. Traditional gait exoskeletons are typically rigid and bilateral and lack adaptability. To address this, the STELO, a pioneering modular gait-assistive device, was developed. This device can be externally configured with joint modules to cater to the diverse impairments of each patient, aiming to enhance adaptability and efficiency. This study aims to assess the safety and usability of the initial functional modular prototype, STELO, in a sample of 14 ABI-diagnosed participants. Adverse events, device adjustment assistance and time, and gait performance were evaluated during three sessions of device use. The results revealed that STELO was safe, with no serious adverse events reported. The need for assistance and time required for device adjustment decreased progressively over the sessions. Although there was no significant improvement in walking speed observed after three sessions of using STELO, participants and therapists reported satisfactory levels of comfort and usability in questionnaires. Overall, this study demonstrates that the STELO modular device offers a safe and adaptable solution for individuals with ABI, with positive user and therapist feedback.

Citing Articles

Modularity Implications of an Overground Exoskeleton on Plantar Pressures, Strength, and Spasticity in Persons with Acquired Brain Injury.

Cumplido-Trasmonte C, Barquin-Santos E, Gor-Garcia-Fogeda M, Plaza-Flores A, Garcia-Varela D, Ibanez-Herran L Sensors (Basel). 2024; 24(5).

PMID: 38474971 PMC: 10935314. DOI: 10.3390/s24051435.

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