Activation of a Rhythmic Lower Limb Movement Pattern During the Use of a Multimodal Brain-Computer Interface: A Case Study of a Clinically Complete Spinal Cord Injury

Overview

Journal Life (Basel)

Specialty Biology

Date 2024 Mar 28

PMID 38541720

Authors

Carla Pais-Vieira

Jose Gabriel Figueiredo

Andre Perrotta

Demetrio Matos

Mafalda Aguiar

Julia Ramos

Marcia Gato

Tania Poleri

Miguel Pais-Vieira

Affiliations

Soon will be listed here.

Abstract

Brain-computer interfaces (BCIs) that integrate virtual reality with tactile feedback are increasingly relevant for neurorehabilitation in spinal cord injury (SCI). In our previous case study employing a BCI-based virtual reality neurorehabilitation protocol, a patient with complete T4 SCI experienced reduced pain and emergence of non-spastic lower limb movements after 10 sessions. However, it is still unclear whether these effects can be sustained, enhanced, and replicated, as well as the neural mechanisms that underlie them. The present report outlines the outcomes of extending the previous protocol with 24 more sessions (14 months, in total). Clinical, behavioral, and neurophysiological data were analyzed. The protocol maintained or reduced pain levels, increased self-reported quality of life, and was frequently associated with the appearance of non-spastic lower limb movements when the patient was engaged and not experiencing stressful events. Neural activity analysis revealed that changes in pain were encoded in the theta frequency band by the left frontal electrode F3. Examination of the lower limbs revealed alternating movements resembling a gait pattern. These results suggest that sustained use of this BCI protocol leads to enhanced quality of life, reduced and stable pain levels, and may result in the emergence of rhythmic patterns of lower limb muscle activity reminiscent of gait.

Citing Articles

Psychological outcomes of extended reality interventions in spinal cord injury rehabilitation: a systematic scoping review.

Williamson S, Aaby A, Ravn S Spinal Cord. 2025; 63(2):58-65.

PMID: 39789357 PMC: 11810788. DOI: 10.1038/s41393-024-01057-7.

Is Virtual Reality Orientation Therapy Useful to Optimize Cognitive and Behavioral Functioning Following Severe Acquired Brain Injury? An Exploratory Study.

De Luca R, Calderone A, Gangemi A, Rifici C, Bonanno M, Maggio M Brain Sci. 2024; 14(5).

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