Jeffrey G. Ojemann

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iEEG-BIDS, extending the Brain Imaging Data Structure specification to human intracranial electrophysiology

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Description:

The Brain Imaging Data Structure (BIDS) is a community-driven specification for organizing neuroscience data and metadata with the aim to make datasets more transparent, reusable, and reproducible. Intracranial electroencephalography (iEEG) data offer a unique combination of high spatial and temporal resolution measurements of the living human brain. To improve internal (re) use and external sharing of these unique data, we present a specification for storing and sharing iEEG data: iEEG-BIDS.

Authors:

  • Christopher Holdgraf

  • Stefan Appelhoff

  • Stephan Bickel

  • Kristofer Bouchard

  • Sasha D’Ambrosio

  • Olivier David

  • Orrin Devinsky

  • Benjamin Dichter

  • Adeen Flinker

  • Brett L. Foster

  • Krzysztof J. Gorgolewski

  • Iris Groen

  • David Groppe

  • Aysegul Gunduz

  • Liberty Hamilton

  • Christopher J. Honey

  • Mainak Jas

  • Robert T. Knight

  • Jean-Philippe Lachaux

  • Jonathan C. Lau

  • Christopher Lee-Messer

  • Brian N. Lundstrom

  • Kai J. Miller

  • Jeffrey G. Ojemann

  • Robert Oostenveld

  • Natalia Petridou

  • Gio Piantoni

  • Andrea Pigorini

  • Nader Pouratian

  • Nick F. Ramsey

  • Arjen Stolk

  • Nicole C. Swann

  • François Tadel

  • Bradley Voytek

  • Brian A . Wandell

  • Jonathan Winawer

  • Kirstie Whitaker

  • Lyuba Zehl

  • Dora Hermes

Date: 2019

DOI: https://doi.org/10.1038/s41597-019-0105-7

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Proceedings of the Third International Workshop on Advances in Electrocorticography

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Authors:

  • Anthony Ritaccio

  • Michael Beauchamp

  • Conrado Bosman

  • Peter Brunner

  • Edward F. Chang

  • Nathan E. Crone

  • Ayesegul Gunduz

  • Disha Gupta

  • Robert T. Knight

  • Eric Leuthardt

  • Brian Litt

  • Daniel Moran

  • Jeffrey G. Ojemann

  • Josef Parvizi

  • Nick F. Ramsey

  • Jochem W. Rieger

  • Jonathan Viventi

  • Bradley Voytek

  • Justin Williams

  • Gerwin Schalk

Date: 2012

DOI: 10.1016/j.yebeh.2012.09.016

PubMed: 23160096

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Abstract:

The Third International Workshop on Advances in Electrocorticography (ECoG) was convened in Washington, DC, on November 10–11, 2011. As in prior meetings, a true multidisciplinary fusion of clinicians, scientists, and engineers from many disciplines gathered to summarize contemporary experiences in brain surface recordings. The proceedings of this meeting serve as evidence of a very robust and transformative field but will yet again require revision to incorporate the advances that the following year will surely bring.

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Human motor cortical activity is selectively phase-entrained on underlying rhythms

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Authors:

  • Kai J. Miller

  • Dora Hermes

  • Christopher J. Honey

  • Adam O. Hebb

  • Nick F. Ramsey

  • Robert T. Knight

  • Jeffrey G. Ojemann

  • Eberhard E. Fetz

Date: 2012

DOI: 10.1371/journal.pcbi.1002655

PubMed: 22969416

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Abstract:

The functional significance of electrical rhythms in the mammalian brain remains uncertain. In the motor cortex, the 12-20 Hz beta rhythm is known to transiently decrease in amplitude during movement, and to be altered in many motor diseases. Here we show that the activity of neuronal populations is phase-coupled with the beta rhythm on rapid timescales, and describe how the strength of this relation changes with movement. To investigate the relationship of the beta rhythm to neuronal dynamics, we measured local cortical activity using arrays of subdural electrocorticographic (ECoG) electrodes in human patients performing simple movement tasks. In addition to rhythmic brain processes, ECoG potentials also reveal a spectrally broadband motif that reflects the aggregate neural population activity beneath each electrode. During movement, the amplitude of this broadband motif follows the dynamics of individual fingers, with somatotopically specific responses for different fingers at different sites on the pre-central gyrus. The 12-20 Hz beta rhythm, in contrast, is widespread as well as spatially coherent within sulcal boundaries and decreases in amplitude across the pre- and post-central gyri in a diffuse manner that is not finger-specific. We find that the amplitude of this broadband motif is entrained on the phase of the beta rhythm, as well as rhythms at other frequencies, in peri-central cortex during fixation. During finger movement, the beta phase-entrainment is diminished or eliminated. We suggest that the beta rhythm may be more than a resting rhythm, and that this entrainment may reflect a suppressive mechanism for actively gating motor function.