On the use of power-based connectivity between EEG and sEMG signals for three-weight classification during object manipulation tasks

C. D. Guerrero-Mendez; C. F. Blanco-Díaz; M. E. Duarte-Gonzalez; T. F. Bastos-Filho; S. Jaramillo-Isaza; A. F. Ruiz-Olaya

On the use of power-based connectivity between EEG and sEMG signals for three-weight classification during object manipulation tasks

Título traducido de la contribución: Sobre el uso de la conectividad basada en la potencia entre las señales EEG y sEMG para la clasificación de tres pesos durante tareas de manipulación de objetos

C. D. Guerrero-Mendez
, C. F. Blanco-Díaz
, M. E. Duarte-Gonzalez
, T. F. Bastos-Filho
, S. Jaramillo-Isaza
, A. F. Ruiz-Olaya

Producción científica: Contribución a revista › Artículo de Investigación › revisión exhaustiva

1 Cita (Scopus)

Resumen

Purpose: Brain-machine interfaces (BMIs) have been used for motor rehabilitation of complex movements, such as those based on object manipulation. However, task identification during these movements remains a challenge in the scientific community. Recent research has suggested that corticomuscular connectivity may enhance the BMIs’ performance in task identification. Therefore, this study presents an algorithm that uses power-based connectivity (PBC) as a descriptor to improve the classification of three different weights during object manipulation which was compared with power spectral density (PSD) benchmark algorithm. Methods: Signals from three electroencephalography (EEG) and five surface electromyography (sEMG) electrodes were analyzed using Welch’s estimator to determine the PSD features and then correlated using Spearman’s correlation. The performance was evaluated using four classifiers that are widely applied in brain-computer interfaces (BCIs). Furthermore, different frequency bands and the influence of EEG and sEMG channels on object weight identification were evaluated using accuracy, F-score, and computational cost metrics. Results: The proposed algorithm significantly outperforms (p

Título traducido de la contribución	Sobre el uso de la conectividad basada en la potencia entre las señales EEG y sEMG para la clasificación de tres pesos durante tareas de manipulación de objetos
Idioma original	Inglés estadounidense
Páginas (desde-hasta)	99–116
Número de páginas	18
Publicación	Research on Biomedical Engineering
Volumen	40
N.º	1
Estado	Publicada - mar. 1 2024

ODS de las Naciones Unidas

Este resultado contribuye a los siguientes Objetivos de Desarrollo Sostenible

ODS 3: Salud y bienestar

Áreas temáticas de ASJC Scopus

Ingeniería biomédica

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@article{1b04f0e3318a4523ba18d21e1261b4f6,

title = "On the use of power-based connectivity between EEG and sEMG signals for three-weight classification during object manipulation tasks",

abstract = "Purpose: Brain-machine interfaces (BMIs) have been used for motor rehabilitation of complex movements, such as those based on object manipulation. However, task identification during these movements remains a challenge in the scientific community. Recent research has suggested that corticomuscular connectivity may enhance the BMIs{\textquoteright} performance in task identification. Therefore, this study presents an algorithm that uses power-based connectivity (PBC) as a descriptor to improve the classification of three different weights during object manipulation which was compared with power spectral density (PSD) benchmark algorithm. Methods: Signals from three electroencephalography (EEG) and five surface electromyography (sEMG) electrodes were analyzed using Welch{\textquoteright}s estimator to determine the PSD features and then correlated using Spearman{\textquoteright}s correlation. The performance was evaluated using four classifiers that are widely applied in brain-computer interfaces (BCIs). Furthermore, different frequency bands and the influence of EEG and sEMG channels on object weight identification were evaluated using accuracy, F-score, and computational cost metrics. Results: The proposed algorithm significantly outperforms (p<0.05) the standard method based on PSD, with a difference in accuracy of 19.15\% and F-score of 10.40\% and obtaining a computational cost of 6 s less. Conclusions: These findings demonstrate the promising potential of the PBC method for object weight identification in complex tasks. The implementation of such algorithms can lead to significant improvements in the effectiveness of BMIs for object manipulation, with potential benefits for rehabilitation and other applications.",

author = "Guerrero-Mendez, \{C. D.\} and Blanco-D{\'i}az, \{C. F.\} and Duarte-Gonzalez, \{M. E.\} and Bastos-Filho, \{T. F.\} and S. Jaramillo-Isaza and Ruiz-Olaya, \{A. F.\}",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive licence to The Brazilian Society of Biomedical Engineering 2024.",

year = "2024",

month = mar,

day = "1",

language = "English (US)",

volume = "40",

pages = "99–116",

journal = "Research on Biomedical Engineering",

issn = "2446-4732",

publisher = "Sociedade Brasileira de Engenharia Biomedica",

number = "1",

}

On the use of power-based connectivity between EEG and sEMG signals for three-weight classification during object manipulation tasks. / Guerrero-Mendez, C. D.; Blanco-Díaz, C. F.; Duarte-Gonzalez, M. E. et al.
En: Research on Biomedical Engineering, Vol. 40, N.º 1, 01.03.2024, p. 99–116.

Producción científica: Contribución a revista › Artículo de Investigación › revisión exhaustiva

TY - JOUR

T1 - On the use of power-based connectivity between EEG and sEMG signals for three-weight classification during object manipulation tasks

AU - Guerrero-Mendez, C. D.

AU - Blanco-Díaz, C. F.

AU - Duarte-Gonzalez, M. E.

AU - Bastos-Filho, T. F.

AU - Jaramillo-Isaza, S.

AU - Ruiz-Olaya, A. F.

N1 - Publisher Copyright: © The Author(s), under exclusive licence to The Brazilian Society of Biomedical Engineering 2024.

PY - 2024/3/1

Y1 - 2024/3/1

N2 - Purpose: Brain-machine interfaces (BMIs) have been used for motor rehabilitation of complex movements, such as those based on object manipulation. However, task identification during these movements remains a challenge in the scientific community. Recent research has suggested that corticomuscular connectivity may enhance the BMIs’ performance in task identification. Therefore, this study presents an algorithm that uses power-based connectivity (PBC) as a descriptor to improve the classification of three different weights during object manipulation which was compared with power spectral density (PSD) benchmark algorithm. Methods: Signals from three electroencephalography (EEG) and five surface electromyography (sEMG) electrodes were analyzed using Welch’s estimator to determine the PSD features and then correlated using Spearman’s correlation. The performance was evaluated using four classifiers that are widely applied in brain-computer interfaces (BCIs). Furthermore, different frequency bands and the influence of EEG and sEMG channels on object weight identification were evaluated using accuracy, F-score, and computational cost metrics. Results: The proposed algorithm significantly outperforms (p<0.05) the standard method based on PSD, with a difference in accuracy of 19.15% and F-score of 10.40% and obtaining a computational cost of 6 s less. Conclusions: These findings demonstrate the promising potential of the PBC method for object weight identification in complex tasks. The implementation of such algorithms can lead to significant improvements in the effectiveness of BMIs for object manipulation, with potential benefits for rehabilitation and other applications.

AB - Purpose: Brain-machine interfaces (BMIs) have been used for motor rehabilitation of complex movements, such as those based on object manipulation. However, task identification during these movements remains a challenge in the scientific community. Recent research has suggested that corticomuscular connectivity may enhance the BMIs’ performance in task identification. Therefore, this study presents an algorithm that uses power-based connectivity (PBC) as a descriptor to improve the classification of three different weights during object manipulation which was compared with power spectral density (PSD) benchmark algorithm. Methods: Signals from three electroencephalography (EEG) and five surface electromyography (sEMG) electrodes were analyzed using Welch’s estimator to determine the PSD features and then correlated using Spearman’s correlation. The performance was evaluated using four classifiers that are widely applied in brain-computer interfaces (BCIs). Furthermore, different frequency bands and the influence of EEG and sEMG channels on object weight identification were evaluated using accuracy, F-score, and computational cost metrics. Results: The proposed algorithm significantly outperforms (p<0.05) the standard method based on PSD, with a difference in accuracy of 19.15% and F-score of 10.40% and obtaining a computational cost of 6 s less. Conclusions: These findings demonstrate the promising potential of the PBC method for object weight identification in complex tasks. The implementation of such algorithms can lead to significant improvements in the effectiveness of BMIs for object manipulation, with potential benefits for rehabilitation and other applications.

UR - https://www.mendeley.com/catalogue/8db313c6-e68f-3d8d-a5f8-6af49f4ca38f/

M3 - Research Article

AN - SCOPUS:85186872180

SN - 2446-4732

VL - 40

SP - 99

EP - 116

JO - Research on Biomedical Engineering

JF - Research on Biomedical Engineering

IS - 1

ER -

On the use of power-based connectivity between EEG and sEMG signals for three-weight classification during object manipulation tasks

Resumen

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Áreas temáticas de ASJC Scopus

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