Movement Type Prediction Before Its Onset Using Signals from Prefrontal Area: an Electrocorticography Study

Overview

Journal Biomed Res Int

Publisher Wiley

Specialties Biomedical Engineering
Biotechnology
General Medicine

Date 2014 Aug 16

PMID 25126578

Citations 7

Authors

Seokyun Ryun

June Sic Kim

Sang Hun Lee

Sehyoon Jeong

Sung-Phil Kim

Chun Kee Chung

Affiliations

Soon will be listed here.

Abstract

Power changes in specific frequency bands are typical brain responses during motor planning or preparation. Many studies have demonstrated that, in addition to the premotor, supplementary motor, and primary sensorimotor areas, the prefrontal area contributes to generating such responses. However, most brain-computer interface (BCI) studies have focused on the primary sensorimotor area and have estimated movements using postonset period brain signals. Our aim was to determine whether the prefrontal area could contribute to the prediction of voluntary movement types before movement onset. In our study, electrocorticography (ECoG) was recorded from six epilepsy patients while performing two self-paced tasks: hand grasping and elbow flexion. The prefrontal area was sufficient to allow classification of different movements through the area's premovement signals (-2.0 s to 0 s) in four subjects. The most pronounced power difference frequency band was the beta band (13-30 Hz). The movement prediction rate during single trial estimation averaged 74% across the six subjects. Our results suggest that premovement signals in the prefrontal area are useful in distinguishing different movement tasks and that the beta band is the most informative for prediction of movement type before movement onset.

Citing Articles

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Decoding Movement From Electrocorticographic Activity: A Review.

Volkova K, Lebedev M, Kaplan A, Ossadtchi A Front Neuroinform. 2019; 13:74.

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