Por favor, use este identificador para citar o enlazar este ítem: https://hdl.handle.net/11000/31257

Synchronization of Slow Cortical Rhythms During Motor Imagery-Based Brain–Machine Interface Control


no-thumbnailVer/Abrir:

 2019_ijns.pdf



7,67 MB
Adobe PDF
Compartir:

Este recurso está restringido

Título :
Synchronization of Slow Cortical Rhythms During Motor Imagery-Based Brain–Machine Interface Control
Autor :
Badesa, Francisco Javier
García Aracil, Nicolás
Nann, Marius
Barios, Juan A.
Ezquerro, Santiago
Bertomeu Motos, Arturo
Fernández, Eduardo
Soekadar, Surjo R.
Editor :
World Scientific Publishing
Departamento:
Departamentos de la UMH::Ingeniería de Sistemas y Automática
Fecha de publicación:
2018
URI :
https://hdl.handle.net/11000/31257
Resumen :
Modulation of sensorimotor rhythm (SMR) power, a rhythmic brain oscillation physiologically linked to motor imagery, is a popular Brain–Machine Interface (BMI) paradigm, but its interplay with slower cortical rhythms, also involved in movement preparation and cognitive processing, is not entirely understood. In this study, we evaluated the changes in phase and power of slow cortical activity in delta and theta bands, during a motor imagery task controlled by an SMR-based BMI system. In Experiment I, EEG of 20 right-handed healthy volunteers was recorded performing a motor-imagery task using an SMR-based BMI controlling a visual animation, and during task-free intervals. In Experiment II, 10 subjects were evaluated along five daily sessions, while BMI-controlling same visual animation, a buzzer, and a robotic hand exoskeleton. In both experiments, feedback received from the controlled device was proportional to SMR power (11–14 Hz) detected by a real-time EEG-based system. Synchronization of slow EEG frequencies along the trials was evaluated using inter-trial-phase coherence (ITPC). Results: cortical oscillations of EEG in delta and theta frequencies synchronized at the onset and at the end of both active and task-free trials; ITPC was significantly modulated by feedback sensory modality received during the tasks; and ITPC synchronization progressively increased along the training. These findings suggest that phase-locking of slow rhythms and resetting by sensory afferences might be a functionally relevant mechanism in cortical control of motor function. We propose that analysis of phase synchronization of slow cortical rhythms might also improve identification of temporal edges in BMI tasks and might help to develop physiological markers for identification of context task switching and practice-related changes in brain function, with potentially important implications for design and monitoring of motor imagery-based BMI systems, an emerging tool in neurorehabilitation of strok
Palabras clave/Materias:
Slow rhythms
synchronization
EEG
coherence
motor imagery
BMI
Tipo documento :
application/pdf
Derechos de acceso:
info:eu-repo/semantics/closedAccess
Attribution-NonCommercial-NoDerivatives 4.0 Internacional
DOI :
https://doi.org/10.1142/S0129065718500454
Aparece en las colecciones:
Artículos Ingeniería de Sistemas y Automática



Creative Commons La licencia se describe como: Atribución-NonComercial-NoDerivada 4.0 Internacional.