Your search keyword '"Oostenveld, Robert"' showing total 13 results

1. BIDS Derivatives: Standardization of Processing Results in Brain Imaging

Author

Markiewicz, Christopher J, Appelhoff, Stefan, Calhoun, Vince, Dickie, Erin W, Duff, Eugene, DuPre, Elizabeth, Esteban, Oscar, Feingold, Franklin, Ghosh, Satrajit, Halchenko, Yaroslav O, Harms, Michael P, Herholz, Peer, Mennes, Maarten, Nørgaard, Martin, Oostenveld, Robert, Pernet, Cyril, Pestilli, Franco, Poldrack, Russell A, Rokem, Ariel, Smith, Robert E, Yarkoni, Tal, and Gorgolewski, Krzysztof J

Subjects

Electrophysiology, Structural MRI, Informatics, Positron Emission Tomography (PET), Data Organization, Reproducibility, Functional MRI, MRI

Abstract

Introduction We present BIDS-Derivatives, a set of principles for organizing and describing outputs of computations performed on brain imaging data, enabling researchers and tools to understand and reuse those outputs in subsequent processing. BIDS-Derivatives is an extension to the Brain Imaging Data Structure (BIDS), which is a standard for organizing magnetic resonance imaging (MRI) [2], electrophysiological [6, 7, 8] and behavioral data generated by a broad range of neuroscientific experiments. BIDS has facilitated the generation of tools (BIDS-Apps) [3] that may run with minimal intervention on BIDS datasets, adapting to the details of the available data. BIDS also provides a common structure for archiving data, both within labs and in large-scale databases such as OpenNeuro [4] and the NIMH Data Archive [10]. Methods The BIDS specification is hosted on GitHub and published on ReadTheDocs [9]. Significant modifications to BIDS are formulated as BIDS Extension Proposals (BEPs), which may be developed as separate documents or as "forks" of the document source. Derivatives were conceived during early BIDS discussions as a category distinct from raw experimental data, ranging from preprocessed data to publishable results. A BEP was initially drafted in February 2016. Further work defining the scope of derivatives at an August 2017 meeting led to the division of the effort into fine-grained proposals [5]. In July 2018, a survey of the neuroimaging community was taken to establish priorities (essential, desirable or inessential) for structural, functional and diffusion MRI derivatives. The results of the survey were posted [1] in advance of an August 2018 workshop of 31 participants, where sub-proposals were pushed toward completion and common principles were established. In December 2018, Release Candidate 1 was published, including all imaging modalities, for implementation and feedback. In July 2019, a "Common Derivatives" proposal was re-introduced establishing more general principles, to be followed by subsequent modality-specific and non-imaging proposals. Results BIDS-Derivatives are specified in version 1.3.0 of the BIDS standard. This initial release specifies common derivatives, including dataset-level metadata, naming rules for preprocessed data of any modality, and generic imaging derivatives. Dataset metadata and organization follow BIDS conventions, and have been extended to allow the source dataset(s) to be linked and provenance information recorded of software used to generate the dataset. File-level naming rules permit space and desc keywords, allowing pipelines to distinguish files by a reference space or a generic description field. Custom references spaces may also be specified with the SpatialReference metadata field. All derived files must distinguish themselves from original (e.g., raw) data files by some component in the filename, permitting the inclusion of original and derived data in the same dataset, if necessary. Imaging-specific derivatives specified in this initial release include naming conventions for resampling parameters (e.g., resolution and surface mesh density) and specifications of regions of interest as masks or deterministic and probabilistic segmentations. Conclusions A standard for specifying derivatives will simplify the sharing and archiving of preprocessed data and the results of analyses. It will permit data repositories to provide canonical, preprocessed versions of datasets, simplify further automated processing, and facilitate collaboration between researchers and replication of analyses of published datasets. This initial release establishes common principles that guide future derivative specifications. Additional specifications of anatomical, functional and diffusion derivatives are planned within the next year, and electrophysiological, positron emission tomography, and connectomic derivatives are in progress. BIDS is an open effort, and everyone is encouraged to contribute, regardless of level of expertise., {"references":["Feingold, F.W. (2018), 'BIDS-Processed Data Survey Results', Stanford Center for Reproducible Neuroscience, http://reproducibility.stanford.edu/bids-processed-data-survey-results/","Gorgolewski, K.J. (2016), 'The brain imaging data structure, a format for organizing and describing outputs of neuroimaging experiments' Scientific Data, 3:160044. doi:10.1038/sdata.2016.44","Gorgolewski, K.J. (2017a), 'BIDS apps: Improving ease of use, accessibility, and reproducibility of neuroimaging data analysis methods', PLOS Computational Biology 13(3): e1005209, doi:10.1371/journal.pcbi.1005209","Gorgolewski K.J. (2017b), 'OpenNeuro – a free online platform for sharing and analysis of neuroimaging data [version 1; not peer reviewed]', F1000Research, 6:1055 (poster), doi:10.7490/f1000research.1114354.1","Gorgolewski, K.J. (2017c), 'Restructuring BIDS Derivatives', bids-discussion mailing-list, https://groups.google.com/forum/#!msg/bids-discussion/l74eKXzNX84/4rMQzS_KAwAJ","Holdgraf, C. (2019), 'iEEG-BIDS, extending the Brain Imaging Data Structure specification to human intracranial electrophysiology' Scientific Data, 6:102. doi:10.1038/s41597-019-0105-7","Niso, G. (2018), 'MEG-BIDS, the brain imaging data structure extended to magnetoencephalography' Scientific Data, 5:180110. doi:doi:10.1038/sdata.2018.110","Pernet, C.R. (2019), 'EEG-BIDS, an extension to the brain imaging data structure for electroencephalography' Scientific Data, 6:103. doi:10.1038/s41597-019-0104-8","https://bids-specification.readthedocs.io/en/stable/","https://nda.nih.gov/"]}

Published

2020

2. Localizing on-scalp MEG sensors using an array of magnetic dipole coils.

Author

Pfeiffer, Christoph, Andersen, Lau M., Lundqvist, Daniel, Hämäläinen, Matti, Schneiderman, Justin F., and Oostenveld, Robert

Subjects

MAGNETOENCEPHALOGRAPHY, MAGNETIC dipoles, MAGNETOMETERS, A priori, ELECTROMAGNETS

Abstract

Accurate estimation of the neural activity underlying magnetoencephalography (MEG) signals requires co-registration i.e., determination of the position and orientation of the sensors with respect to the head. In modern MEG systems, an array of hundreds of low-Tc SQUID sensors is used to localize a set of small, magnetic dipole-like (head-position indicator, HPI) coils that are attached to the subject’s head. With accurate prior knowledge of the positions and orientations of the sensors with respect to one another, the HPI coils can be localized with high precision, and thereby the positions of the sensors in relation to the head. With advances in magnetic field sensing technologies, e.g., high-Tc SQUIDs and optically pumped magnetometers (OPM), that require less extreme operating temperatures than low-Tc SQUID sensors, on-scalp MEG is on the horizon. To utilize the full potential of on-scalp MEG, flexible sensor arrays are preferable. Conventional co-registration is impractical for such systems as the relative positions and orientations of the sensors to each other are subject-specific and hence not known a priori. Herein, we present a method for co-registration of on-scalp MEG sensors. We propose to invert the conventional co-registration approach and localize the sensors relative to an array of HPI coils on the subject’s head. We show that given accurate prior knowledge of the positions of the HPI coils with respect to one another, the sensors can be localized with high precision. We simulated our method with realistic parameters and layouts for sensor and coil arrays. Results indicate co-registration is possible with sub-millimeter accuracy, but the performance strongly depends upon a number of factors. Accurate calibration of the coils and precise determination of the positions and orientations of the coils with respect to one another are crucial. Finally, we propose methods to tackle practical challenges to further improve the method. [ABSTRACT FROM AUTHOR]

Published

2018

3. Similarities and differences between on-scalp and conventional in-helmet magnetoencephalography recordings.

Author

Andersen, Lau M., Oostenveld, Robert, Pfeiffer, Christoph, Ruffieux, Silvia, Jousmäki, Veikko, Hämäläinen, Matti, Schneiderman, Justin F., and Lundqvist, Daniel

Subjects

*MAGNETOENCEPHALOGRAPHY, *MAGNETIC sensors, *LOW temperatures, *MAGNETIC recorders & recording, *NEURAL stimulation

Abstract

The development of new magnetic sensor technologies that promise sensitivities approaching that of conventional MEG technology while operating at far lower operating temperatures has catalysed the growing field of on-scalp MEG. The feasibility of on-scalp MEG has been demonstrated via benchmarking of new sensor technologies performing neuromagnetic recordings in close proximity to the head surface against state-of-the-art in-helmet MEG sensor technology. However, earlier work has provided little information about how these two approaches compare, or about the reliability of observed differences. Herein, we present such a comparison, based on recordings of the N20m component of the somatosensory evoked field as elicited by electric median nerve stimulation. As expected from the proximity differences between the on-scalp and in-helmet sensors, the magnitude of the N20m activation as recorded with the on-scalp sensor was higher than that of the in-helmet sensors. The dipole pattern of the on-scalp recordings was also more spatially confined than that of the conventional recordings. Our results furthermore revealed unexpected temporal differences in the peak of the N20m component. An analysis protocol was therefore developed for assessing the reliability of this observed difference. We used this protocol to examine our findings in terms of differences in sensor sensitivity between the two types of MEG recordings. The measurements and subsequent analysis raised attention to the fact that great care has to be taken in measuring the field close to the zero-line crossing of the dipolar field, since it is heavily dependent on the orientation of sensors. Taken together, our findings provide reliable evidence that on-scalp and in-helmet sensors measure neural sources in mostly similar ways. [ABSTRACT FROM AUTHOR]

Published

2017

4. An improved index of phase-synchronization for electrophysiological data in the presence of volume-conduction, noise and sample-size bias

Author

Vinck, Martin, Oostenveld, Robert, van Wingerden, Marijn, Battaglia, Franscesco, and Pennartz, Cyriel M.A.

Subjects

*SYNCHRONIZATION, *ELECTROPHYSIOLOGY, *NOISE, *ELECTROENCEPHALOGRAPHY, *PHASE transitions, *DETECTORS, *OSCILLATIONS

Abstract

Abstract: Phase-synchronization is a manifestation of interaction between neuronal groups measurable from LFP, EEG or MEG signals, however, volume conduction can cause the coherence and the phase locking value to spuriously increase. It has been shown that the imaginary component of the coherency (ImC) cannot be spuriously increased by volume-conduction of independent sources. Recently, it was proposed that the phase lag index (PLI), which estimates to what extent the phase leads and lags between signals from two sensors are nonequiprobable, improves on the ImC. Compared to ImC, PLI has the advantage of being less influenced by phase delays. However, sensitivity to volume-conduction and noise, and capacity to detect changes in phase-synchronization, is hindered by the discontinuity of the PLI, as small perturbations turn phase lags into leads and vice versa. To solve this problem, we introduce a related index, namely the weighted phase lag index (WPLI). Differently from PLI, in WPLI the contribution of the observed phase leads and lags is weighted by the magnitude of the imaginary component of the cross-spectrum. We demonstrate two advantages of the WPLI over the PLI, in terms of reduced sensitivity to additional, uncorrelated noise sources and increased statistical power to detect changes in phase-synchronization. Another factor that can affect phase-synchronization indices is sample-size bias. We show that, when directly estimated, both PLI and the magnitude of the ImC have typically positively biased estimators. To solve this problem, we develop an unbiased estimator of the squared PLI, and a debiased estimator of the squared WPLI. [Copyright &y& Elsevier]

Published

2011

5. Resting oscillatory cortico-subthalamic connectivity in patients with Parkinson’s disease.

Author

Litvak, Vladimir, Jha, Ashwani, Eusebio, Alexandre, Oostenveld, Robert, Foltynie, Tom, Limousin, Patricia, Zrinzo, Ludvic, Hariz, Marwan I., Friston, Karl, and Brown, Peter

Subjects

PARKINSON'S disease, PHENOTYPES, BASAL ganglia, ELECTROPHYSIOLOGY, MAGNETOENCEPHALOGRAPHY, SUBTHALAMUS, BRAIN stem, BIOLOGICAL neural networks

Abstract

Both phenotype and treatment response vary in patients with Parkinson’s disease. Anatomical and functional imaging studies suggest that individual symptoms may represent malfunction of different segregated networks running in parallel through the basal ganglia. In this study, we use a newly described, electrophysiological method to describe cortico-subthalamic networks in humans. We performed combined magnetoencephalographic and subthalamic local field potential recordings in thirteen patients with Parkinson’s disease at rest. Two spatially and spectrally separated networks were identified. A temporoparietal-brainstem network was coherent with the subthalamic nucleus in the alpha (7–13 Hz) band, whilst a predominantly frontal network was coherent in the beta (15–35 Hz) band. Dopaminergic medication modulated the resting beta network, by increasing beta coherence between the subthalamic region and prefrontal cortex. Subthalamic activity was predominantly led by activity in the cortex in both frequency bands. The cortical topography and frequencies involved in the alpha and beta networks suggest that these networks may be involved in attentional and executive, particularly motor planning, processes, respectively. [ABSTRACT FROM AUTHOR]

Published

2011

6. FieldTrip: Open Source Software for Advanced Analysis of MEG, EEG, and Invasive Electrophysiological Data.

Author

Oostenveld, Robert, Fries, Pascal, Maris, Eric, and Schoffelen, Jan-Mathijs

Subjects

*BRAIN imaging, *ELECTROPHYSIOLOGY, *OPEN source software, *ELECTROENCEPHALOGRAPHY, *MAGNETOENCEPHALOGRAPHY, *BEAMFORMING, *BIOMEDICAL signal processing, *EQUIPMENT & supplies

Abstract

This paper describes FieldTrip, an open source software package that we developed for the analysis of MEG, EEG, and other electrophysiological data. The software is implemented as a MATLAB toolbox and includes a complete set of consistent and user-friendly high-level functions that allow experimental neuroscientists to analyze experimental data. It includes algorithms for simple and advanced analysis, such as time-frequency analysis using multitapers, source reconstruction using dipoles, distributed sources and beamformers, connectivity analysis, and nonparametric statistical permutation tests at the channel and source level. The implementation as toolbox allows the user to perform elaborate and structured analyses of large data sets using the MATLAB command line and batch scripting. Furthermore, users and developers can easily extend the functionality and implement new algorithms. The modular design facilitates the reuse in other software packages. [ABSTRACT FROM AUTHOR]

Published

2011

7. EEG-BIDS, an extension to the brain imaging data structure for electroencephalography.

Author

Pernet, Cyril R., Appelhoff, Stefan, Gorgolewski, Krzysztof J., Flandin, Guillaume, Phillips, Christophe, Delorme, Arnaud, and Oostenveld, Robert

Subjects

ELECTROENCEPHALOGRAPHY, BRAIN imaging, FUNCTIONAL magnetic resonance imaging, HEMODYNAMICS, ELECTROPHYSIOLOGY

Abstract

The Brain Imaging Data Structure (BIDS) project is a rapidly evolving effort in the human brain imaging research community to create standards allowing researchers to readily organize and share study data within and between laboratories. Here we present an extension to BIDS for electroencephalography (EEG) data, EEG-BIDS, along with tools and references to a series of public EEG datasets organized using this new standard. [ABSTRACT FROM AUTHOR]

Published

2019

8. A 204-subject multimodal neuroimaging dataset to study language processing.

Author

Schoffelen, Jan-Mathijs, Oostenveld, Robert, Lam, Nietzsche H. L., Uddén, Julia, Hultén, Annika, and Hagoort, Peter

Subjects

BRAIN imaging, BRAIN anatomy, BRAIN function localization, ACQUISITION of data, ELECTROPHYSIOLOGY

Abstract

This dataset, colloquially known as the Mother Of Unification Studies (MOUS) dataset, contains multimodal neuroimaging data that has been acquired from 204 healthy human subjects. The neuroimaging protocol consisted of magnetic resonance imaging (MRI) to derive information at high spatial resolution about brain anatomy and structural connections, and functional data during task, and at rest. In addition, magnetoencephalography (MEG) was used to obtain high temporal resolution electrophysiological measurements during task, and at rest. All subjects performed a language task, during which they processed linguistic utterances that either consisted of normal or scrambled sentences. Half of the subjects were reading the stimuli, the other half listened to the stimuli. The resting state measurements consisted of 5 minutes eyes-open for the MEG and 7 minutes eyes-closed for fMRI. The neuroimaging data, as well as the information about the experimental events are shared according to the Brain Imaging Data Structure (BIDS) format. This unprecedented neuroimaging language data collection allows for the investigation of various aspects of the neurobiological correlates of language. Design Type(s) behavioral data analysis objective • observation design Measurement Type(s) brain activity measurement Technology Type(s) magnetic resonance imaging • Magnetoencephalography Factor Type(s) biological sex • receptive language perception • Language Sample Characteristic(s) Homo sapiens • brain Machine-accessible metadata file describing the reported data (ISA-Tab format) [ABSTRACT FROM AUTHOR]

Published

2019

9. Alpha-band suppression in the visual word form area as a functional bottleneck to consciousness.

Author

Levy, Jonathan, Vidal, Juan R., Oostenveld, Robert, FitzPatrick, Ian, Démonet, Jean-François, and Fries, Pascal

Subjects

*CONSCIOUSNESS, *SENSORY perception, *RECOGNITION (Psychology), *MOLECULAR recognition, *ELECTROPHYSIOLOGY, *MAGNETOENCEPHALOGRAPHY

Abstract

Abstract: The current state of empirical investigations refers to consciousness as an all-or-none phenomenon. However, a recent theoretical account opens up this perspective by proposing a partial level (between nil and full) of conscious perception. In the well-studied case of single-word reading, short-lived exposure can trigger incomplete word-form recognition wherein letters fall short of forming a whole word in one's conscious perception thereby hindering word-meaning access and report. Hence, the processing from incomplete to complete word-form recognition straightforwardly mirrors a transition from partial to full-blown consciousness. We therefore hypothesized that this putative functional bottleneck to consciousness (i.e. the perceptual boundary between partial and full conscious perception) would emerge at a major key hub region for word-form recognition during reading, namely the left occipito-temporal junction. We applied a real-time staircase procedure and titrated subjective reports at the threshold between partial (letters) and full (whole word) conscious perception. This experimental approach allowed us to collect trials with identical physical stimulation, yet reflecting distinct perceptual experience levels. Oscillatory brain activity was monitored with magnetoencephalography and revealed that the transition from partial-to-full word-form perception was accompanied by alpha-band (7–11Hz) power suppression in the posterior left occipito-temporal cortex. This modulation of rhythmic activity extended anteriorly towards the visual word form area (VWFA), a region whose selectivity for word-forms in perception is highly debated. The current findings provide electrophysiological evidence for a functional bottleneck to consciousness thereby empirically instantiating a recently proposed partial perspective on consciousness. Moreover, the findings provide an entirely new outlook on the functioning of the VWFA as a late bottleneck to full-blown conscious word-form perception. [Copyright &y& Elsevier]

Published

2013

10. Attentional Stimulus Selection through Selective Synchronization between Monkey Visual Areas

Author

Bosman, Conrado A., Schoffelen, Jan-Mathijs, Brunet, Nicolas, Oostenveld, Robert, Bastos, Andre M., Womelsdorf, Thilo, Rubehn, Birthe, Stieglitz, Thomas, De Weerd, Peter, and Fries, Pascal

Subjects

*LABORATORY monkeys, *VISUAL cortex, *NEURAL circuitry, *NEURAL stimulation, *ATTENTION, *STIMULUS & response (Biology), *ELECTROPHYSIOLOGY

Abstract

Summary: A central motif in neuronal networks is convergence, linking several input neurons to one target neuron. In visual cortex, convergence renders target neurons responsive to complex stimuli. Yet, convergence typically sends multiple stimuli to a target, and the behaviorally relevant stimulus must be selected. We used two stimuli, activating separate electrocorticographic V1 sites, and both activating an electrocorticographic V4 site equally strongly. When one of those stimuli activated one V1 site, it gamma synchronized (60–80 Hz) to V4. When the two stimuli activated two V1 sites, primarily the relevant one gamma synchronized to V4. Frequency bands of gamma activities showed substantial overlap containing the band of interareal coherence. The relevant V1 site had its gamma peak frequency 2–3 Hz higher than the irrelevant V1 site and 4–6 Hz higher than V4. Gamma-mediated interareal influences were predominantly directed from V1 to V4. We propose that selective synchronization renders relevant input effective, thereby modulating effective connectivity. [ABSTRACT FROM AUTHOR]

Published

2012

11. Neuronal Dynamics Underlying High- and Low-Frequency EEG Oscillations Contribute Independently to the Human BOLD Signal

Author

Scheeringa, René, Fries, Pascal, Petersson, Karl-Magnus, Oostenveld, Robert, Grothe, Iris, Norris, David G., Hagoort, Peter, and Bastiaansen, Marcel C.M.

Subjects

*ELECTROENCEPHALOGRAPHY, *NEURAL physiology, *SYNCHRONIZATION, *ELECTROPHYSIOLOGY, *ALPHA rhythm, *BETA rhythm

Abstract

Summary: Work on animals indicates that BOLD is preferentially sensitive to local field potentials, and that it correlates most strongly with gamma band neuronal synchronization. Here we investigate how the BOLD signal in humans performing a cognitive task is related to neuronal synchronization across different frequency bands. We simultaneously recorded EEG and BOLD while subjects engaged in a visual attention task known to induce sustained changes in neuronal synchronization across a wide range of frequencies. Trial-by-trial BOLD fluctuations correlated positively with trial-by-trial fluctuations in high-EEG gamma power (60–80 Hz) and negatively with alpha and beta power. Gamma power on the one hand, and alpha and beta power on the other hand, independently contributed to explaining BOLD variance. These results indicate that the BOLD-gamma coupling observed in animals can be extrapolated to humans performing a task and that neuronal dynamics underlying high- and low-frequency synchronization contribute independently to the BOLD signal. [Copyright &y& Elsevier]

Published

2011

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

Author

Olivier David, Rob Knight, Christopher J. Honey, Chris Holdgraf, Jean-Philippe Lachaux, Andrea Pigorini, Sasha D'Ambrosio, Nick F. Ramsey, Brian A. Wandell, Liberty S. Hamilton, Christopher Lee-Messer, Nader Pouratian, Jonathan Winawer, Kristofer E. Bouchard, Lyuba Zehl, Benjamin Dichter, Jeffrey G. Ojemann, Dora Hermes, Orrin Devinsky, Bradley Voytek, Arjen Stolk, David M. Groppe, Jonathan C. Lau, Natalia Petridou, Krzysztof J. Gorgolewski, Nicole C. Swann, Robert Oostenveld, François Tadel, Stefan Appelhoff, Gio Piantoni, Brian Nils Lundstrom, Adeen Flinker, Iris I. A. Groen, Mainak Jas, Kai J. Miller, Kirstie Whitaker, Stephan Bickel, Aysegul Gunduz, Brett L. Foster, Appelhoff, Stefan [0000-0001-8002-0877], D'Ambrosio, Sasha [0000-0002-6600-6419], Devinsky, Orrin [0000-0003-0044-4632], Flinker, Adeen [0000-0003-1247-1283], Gorgolewski, Krzysztof J [0000-0003-3321-7583], Groen, Iris [0000-0002-5536-6128], Hamilton, Liberty [0000-0003-0182-2500], Lundstrom, Brian N [0000-0002-5310-5549], Oostenveld, Robert [0000-0002-1974-1293], Piantoni, Gio [0000-0002-5308-926X], Ramsey, Nick F [0000-0002-7136-259X], Stolk, Arjen [0000-0003-3798-4923], Winawer, Jonathan [0000-0001-7475-5586], Zehl, Lyuba [0000-0002-5947-9939], and Apollo - University of Cambridge Repository

Subjects

Statistics and Probability, 010504 meteorology & atmospheric sciences, Computer science, 1.1 Normal biological development and functioning, Datasets as Topic, Information Storage and Retrieval, Neuroimaging, Library and Information Sciences, computer.software_genre, 01 natural sciences, Intracranial Electroencephalography, Data publication and archiving, Education, 03 medical and health sciences, Underpinning research, medicine, Humans, lcsh:Science, 030304 developmental biology, 0105 earth and related environmental sciences, 0303 health sciences, Comment, Neurosciences, Brain, Cognitive neuroscience, Electroencephalography, Human brain, Data structure, Brain Disorders, Computer Science Applications, Metadata, Electrophysiology, medicine.anatomical_structure, Temporal resolution, Neurological, lcsh:Q, Data mining, ddc:500, Statistics, Probability and Uncertainty, computer, Software, Information Systems

Abstract

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.

Published

2019

13. MEG-BIDS, the brain imaging data structure extended to magnetoencephalography

Author

François Tadel, Sylvain Baillet, Robert Oostenveld, Elizabeth Bock, Vladimir Litvak, Julia Guiomar Niso Galan, Jeremy T. Moreau, Guillaume Flandin, Mainak Jas, Richard N. Henson, Jan-Mathijs Schoffelen, Joseph Wexler, Krzysztof J. Gorgolewski, Alexandre Gramfort, Teon L. Brooks, Apollo-University Of Cambridge Repository, Gorgolewski, Krzysztof J [0000-0003-3321-7583], Brooks, Teon L [0000-0001-7344-3230], Henson, Richard N [0000-0002-0712-2639], Oostenveld, Robert [0000-0002-1974-1293], Baillet, Sylvain [0000-0002-6762-5713], and Apollo - University of Cambridge Repository

Subjects

0301 basic medicine, Statistics and Probability, 110 000 Neurocognition of Language, Computer science, Brain activity and meditation, Medicina, Neuroimaging, Library and Information Sciences, 150 000 MR Techniques in Brain Function, Education, 03 medical and health sciences, 0302 clinical medicine, Software, medicine, Humans, Telecomunicaciones, Modality (human–computer interaction), Information retrieval, medicine.diagnostic_test, business.industry, Comment, Brain, Magnetoencephalography, Data structure, Computer Science Applications, Research data, Metadata, Electrophysiology, 030104 developmental biology, Feature (computer vision), Statistics, Probability and Uncertainty, business, 030217 neurology & neurosurgery, Information Systems, Neuroscience

Abstract

Contains fulltext : 202961.pdf (Publisher’s version ) (Open Access) We present a significant extension of the Brain Imaging Data Structure (BIDS) to support the specific aspects of magnetoencephalography (MEG) data. MEG measures brain activity with millisecond temporal resolution and unique source imaging capabilities. So far, BIDS was a solution to organise magnetic resonance imaging (MRI) data. The nature and acquisition parameters of MRI and MEG data are strongly dissimilar. Although there is no standard data format for MEG, we propose MEG-BIDS as a principled solution to store, organise, process and share the multidimensional data volumes produced by the modality. The standard also includes well-defined metadata, to facilitate future data harmonisation and sharing efforts. This responds to unmet needs from the multimodal neuroimaging community and paves the way to further integration of other techniques in electrophysiology. MEG-BIDS builds on MRI-BIDS, extending BIDS to a multimodal data structure. We feature several data-analytics software that have adopted MEG-BIDS, and a diverse sample of open MEG-BIDS data resources available to everyone. 12 p.

Published

2018