Cortical Functional Topography of High-frequency Gamma Activity Relates to Perceptual Decision: an Intracranial Study

Overview

Journal PLoS One

Specialties General Medicine
Science

Date 2017 Oct 27

PMID 29073154

Citations 5

Authors

Joao Castelhano

Isabel C Duarte

Sulaiman I Abuhaiba

Manuel Rito

Francisco Sales

Miguel Castelo-Branco

Affiliations

Soon will be listed here.

Abstract

High-frequency activity (HFA) is believed to subserve a functional role in cognition, but these patterns are often not accessible to scalp EEG recordings. Intracranial studies provide a unique opportunity to link the all-encompassing range of high-frequency patterns with holistic perception. We tested whether the functional topography of HFAs (up to 250Hz) is related to perceptual decision-making. Human intracortical data were recorded (6 subjects; >250channels) during an ambiguous object-recognition task. We found a spatial topography of HFAs reflecting processing anterior dorsal and ventral streams, linked to decision independently of the type of processed object/stimulus category. Three distinct regional fingerprints could be identified, with lower gamma frequency patterns (<45Hz) dominating in the anterior semantic ventral object processing and dorsoventral integrating networks and evolving later, during perceptual decision phases, than early sensory posterior patterns (60-250Hz). This suggests that accurate object recognition/perceptual decision-making is related to distinct spatiotemporal signatures in the low gamma frequency range.

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