Assessing User Transparency with Muscle Synergies During Exoskeleton-Assisted Movements: A Pilot Study on the LIGHTarm Device for Neurorehabilitation

Overview

Journal Appl Bionics Biomech

Publisher Wiley

Date 2018 Jul 4

PMID 29967656

Citations 2

Authors

Andrea Chiavenna

Alessandro Scano

Matteo Malosio

Lorenzo Molinari Tosatti

Franco Molteni

Affiliations

Soon will be listed here.

Abstract

Exoskeleton devices for upper limb neurorehabilitation are one of the most exploited solutions for the recovery of lost motor functions. By providing weight support, passively compensated exoskeletons allow patients to experience upper limb training. Transparency is a desirable feature of exoskeletons that describes how the device alters free movements or interferes with spontaneous muscle patterns. A pilot study on healthy subjects was conducted to evaluate the feasibility of assessing transparency in the framework of muscle synergies. For such purpose, the LIGHTarm exoskeleton prototype was used. LIGHTarm provides gravity support to the upper limb during the execution of movements in the tridimensional workspace. Surface electromyography was acquired during the execution of three daily life movements (reaching, hand-to-mouth, and hand-to-nape) in three different conditions: free movement, exoskeleton-assisted (without gravity compensation), and exoskeleton-assisted (with gravity compensation) on healthy people. Preliminary results suggest that the muscle synergy framework may provide valuable assessment of user transparency and weight support features of devices aimed at rehabilitation.

Citing Articles

A Comprehensive Spatial Mapping of Muscle Synergies in Highly Variable Upper-Limb Movements of Healthy Subjects.

Scano A, Dardari L, Molteni F, Giberti H, Molinari Tosatti L, dAvella A Front Physiol. 2019; 10:1231.

PMID: 31611812 PMC: 6777095. DOI: 10.3389/fphys.2019.01231.

Robotic Assistance for Upper Limbs May Induce Slight Changes in Motor Modules Compared With Free Movements in Stroke Survivors: A Cluster-Based Muscle Synergy Analysis.

Scano A, Chiavenna A, Malosio M, Molinari Tosatti L, Molteni F Front Hum Neurosci. 2018; 12:290.

PMID: 30174596 PMC: 6107841. DOI: 10.3389/fnhum.2018.00290.

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