Evidence for a motor gamma-band network governing response interference

The gamma-band response is thought to represent a key neural signature of information processing in the human brain. These brain signals have been associated with a variety of sensory modalities (vision, sensation, and audition) and also following basic motor responses, yet the functional significan...

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Bibliographic Details
Published inNeuroImage (Orlando, Fla.) Vol. 74; pp. 245 - 253
Main Authors Gaetz, W., Liu, C., Zhu, H., Bloy, L., Roberts, T.P.L.
Format Journal Article
LanguageEnglish
Published Amsterdam Elsevier Inc 01.07.2013
Elsevier
Elsevier Limited
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Summary:The gamma-band response is thought to represent a key neural signature of information processing in the human brain. These brain signals have been associated with a variety of sensory modalities (vision, sensation, and audition) and also following basic motor responses, yet the functional significance of the motor gamma-band response remains unclear. We used the Multi-Source Interference Task (MSIT) to assess the sensitivity of these cortical motor gamma-band rhythms to stimuli producing response interference. We recorded MEG from adult participants (N=24) during MSIT task performance and compared motor gamma-band activity on Control and Interference trials. Reaction time on MSIT Interference trials was significantly longer (~0.2s) for all subjects. Response interference produced a significant increase in motor gamma-band activity including ~0.5s sustained increase in gamma-band activity from contralateral primary motor area directly preceding the response. In addition, activation of increased right Inferior Frontal Gyrus (R-IFG) was observed at gamma-band frequencies ~0.2s prior to the button press response. Post-hoc analysis of R-IFG gamma-band activity was observed to correlate with reaction time increases to response interference. Our study is the first to record MEG during MSIT task performance. We observed novel activity of the motor gamma-band on interference trials which was sustained prior to the response and in novel locations including contralateral (BA6), and R-IFG. Our results support the idea that R-IFG is specialized structure for response control that also functions at gamma-band frequencies. Together, these data provide evidence for a motor gamma-band network for response selection and maintenance of planned behavior. ► We measured motor gamma-band responses during MSIT task performance. ► Response interference trials were associated with increased motor gamma-band activity. ► This pre-response (~0.5s) gamma-band activity was localized to contralateral BA6. ► Right Inferior Frontal Gyrus (R-IFG) was also observed on interference trials. ► R-IFG activity was observed to correlate with reaction time.
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ISSN:1053-8119
1095-9572
DOI:10.1016/j.neuroimage.2013.02.013