Error detection in motor behavior is a fundamental cognitive function heavily relying on local cortical information processing. Neural activity in the high-gamma frequency band (HGB) closely reflects such local cortical processing, but little is known about its role in error processing, particularly in the healthy human brain. Here we characterize the error-related response of the human brain based on data obtained with noninvasive EEG optimized for HGB mapping in 31 healthy subjects (15 females, 16 males), and additional intracranial EEG data from 9 epilepsy patients (4 females, 5 males). Our findings reveal a multiscale picture of the global and local dynamics of error-related HGB activity in the human brain. On the global level as reflected in the noninvasive EEG, the error-related response started with an early component dominated by anterior brain regions, followed by a shift to parietal regions, and a subsequent phase characterized by sustained parietal HGB activity. This phase lasted for more than 1 s after the error onset. On the local level reflected in the intracranial EEG, a cascade of both transient and sustained error-related responses involved an even more extended network, spanning beyond frontal and parietal regions to the insula and the hippocampus. HGB mapping appeared especially well suited to investigate late, sustained components of the error response, possibly linked to downstream functional stages such as error-related learning and behavioral adaptation. Our findings establish the basic spatio-temporal properties of HGB activity as a neural correlate of error processing, complementing traditional error-related potential studies.

BrainLinks BrainTools University of Freiburg 79110 Freiburg Germany; Faculty of Medicine University of Freiburg 79106 Freiburg Germany; Epilepsy Center Medical Center University of Freiburg 79106 Freiburg Germany

Department of Computer Science University of Freiburg 79110 Freiburg Germany; BrainLinks BrainTools University of Freiburg 79110 Freiburg Germany; Autonomous Intelligent Systems University of Freiburg 79110 Freiburg Germany

Department of Neurology 2nd Faculty of Medicine and Motol University Hospital Charles University 15006 Prague Czech Republic

Department of Paediatric Neurology 2nd Faculty of Medicine and Motol University Hospital Charles University 15006 Prague Czech Republic

Faculty of Medicine University of Freiburg 79106 Freiburg Germany; Stereotactic and Functional Neurosurgery Medical Center University of Freiburg 79106 Freiburg Germany

Institute of Neuroscience and Medicine Jülich Research Centre and JARA 52428 Jülich Germany

Translational Neurotechnology Lab Medical Center University of Freiburg 79106 Freiburg Germany; BrainLinks BrainTools University of Freiburg 79110 Freiburg Germany; Bernstein Center University of Freiburg 79104 Freiburg Germany; Faculty of Medicine University of Freiburg 79106 Freiburg Germany

Translational Neurotechnology Lab Medical Center University of Freiburg 79106 Freiburg Germany; BrainLinks BrainTools University of Freiburg 79110 Freiburg Germany; Department of Neurology 2nd Faculty of Medicine and Motol University Hospital Charles University 15006 Prague Czech Republic

Translational Neurotechnology Lab Medical Center University of Freiburg 79106 Freiburg Germany; BrainLinks BrainTools University of Freiburg 79110 Freiburg Germany; Faculty of Biology University of Freiburg 79104 Freiburg Germany; Bernstein Center University of Freiburg 79104 Freiburg Germany

Translational Neurotechnology Lab Medical Center University of Freiburg 79106 Freiburg Germany; Department of Computer Science University of Freiburg 79110 Freiburg Germany; BrainLinks BrainTools University of Freiburg 79110 Freiburg Germany

Translational Neurotechnology Lab Medical Center University of Freiburg 79106 Freiburg Germany; Faculty of Medicine University of Freiburg 79106 Freiburg Germany

Translational Neurotechnology Lab Medical Center University of Freiburg 79106 Freiburg Germany; Graduate School of Robotics University of Freiburg 79106 Freiburg Germany; Department of Computer Science University of Freiburg 79110 Freiburg Germany; BrainLinks BrainTools University of Freiburg 79110 Freiburg Germany

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