Best Practices in Data Analysis and Sharing in Neuroimaging using MEEG

Pernet, Cyril; Garrido, Marta I.; Gramfort, Alexandre; Maurits, Natasha; Michel, Christoph M.; Pang, Elizabeth W.; Salmelin, Riitta; Schoffelen, Jan Mathijs; Valdés‐Sosa, Pedro A.; Puce, Aina

doi:10.31219/osf.io/a8dhx

Cited by 48 publications

(49 citation statements)

References 48 publications

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“…We then computed correlations of the corresponding fingerprint vectors associated with pairs of preprocessing methods to summarize how much preprocessing affects spectral results. In addition, we averaged each spectrogram within standard frequency bands (delta: [2,4] Hz, theta: [4,7] Hz, alpha: [7,12] Hz, beta: [12,30] Hz) to form separate fingerprints for each band and computed correlations across corresponding fingerprint bands for pairs of preprocessing methods.…”

Section: F Computation Of Signal Spectral Characteristicsmentioning

confidence: 99%

“…The disagreement between the ICA-based methods (LARG and MARA) and the ASR-based methods (ASR_10* and ASR_5*) in the delta frequency band ( [2,4] Hz for this analysis) is likely due to the differences in baselining and highpass filtering that occurred at the beginning of the respective pipelines. However, ASR_10* and ASR_5* used the same input signals and even in this case, the correlations in the delta bands were much lower than in other bands.…”

Section: B Effects Of Preprocessing On Eeg Spectral Characteristicsmentioning

confidence: 99%

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How Sensitive are EEG Results to Preprocessing Methods: A Benchmarking Study

Robbins

Touryan

Mullen³

et al. 2020

Preprint

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EEG preprocessing approaches have not been standardized, and even those studies that follow best practices contain variations in the ways that the recommended methods are applied. An open question for researchers is how sensitive the results of EEG analyses are to preprocessing methods and parameters. To address this issue, we analyze the effect of preprocessing methods on downstream EEG analysis using several simple signal and event-related measures. Signal measures include recording-level channel amplitudes, study-level channel amplitude dispersion, and recording spectral characteristics. Event-related methods include ERPs and ERSPs and their correlations across methods for a diverse set of stimulus events. Our analysis also assesses differences in residual signals both in the time and spectral domains after blink artifacts have been removed. Using fully automated pipelines, we evaluate these measures across 17 EEG studies for two ICA-based preprocessing approaches (LARG, MARA) plus two variations of Artifact Subspace Reconstruction (ASR). Although the general structure of the results is similar across these preprocessing methods, there are significant differences, particularly in the low-frequency spectral features and in the residuals left by blinks. These results argue for detailed reporting of processing details and for using a federation of processing pipelines to quantify effects of processing choices.

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Section: F Computation Of Signal Spectral Characteristicsmentioning

confidence: 99%

Section: B Effects Of Preprocessing On Eeg Spectral Characteristicsmentioning

confidence: 99%

How Sensitive are EEG Results to Preprocessing Methods: A Benchmarking Study

Robbins

Touryan

Mullen³

et al. 2020

Preprint

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“…All statistical analyses were performed with python using scipy (78), mne-python (61) and scikit-learn (63) packages, except for the non-parametric factorial analysis performed in R statistical software with the ARTool (79) package and electric fields analysis performed in Matlab software. Throughout all EEG analyses, from preprocessing to statistical analyses, we tried to comply with the CODIBAS-MEEG Best Practices in Data Analysis and Sharing in Neuroimaging using MEEG initiative (80).…”

Section: Softwaresmentioning

confidence: 99%

Combined behavioral and electrophysiological evidence for a direct cortical effect of prefrontal tDCS on disorders of consciousness

Hermann¹,

Raimondo²,

Hirsch³

et al. 2019

Preprint

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Severe brain injuries can lead to long-lasting disorders of consciousness (DoC) such as vegetative state/unresponsive wakefulness syndrome (VS/UWS) or minimally conscious state (MCS). While behavioral assessment remains the gold standard to determine conscious state, EEG has proven to be a promising complementary tool to monitor the effect of new therapeutics. Encouraging results have been obtained with invasive electrical stimulation of the brain, and recent studies identified transcranial direct current stimulation (tDCS) as an effective approach in randomized controlled trials. This non-invasive and inexpensive tool may turn out to be the preferred treatment option. However, its mechanisms of action and physiological effects on brain activity remain unclear and debated. Here, we stimulated 60 DoC patients with the anode placed over left-dorsolateral prefrontal cortex in a prospective open-label study. Clinical behavioral assessment improved in twelve patients (20%) and none deteriorated. This behavioral response after tDCS coincided with an enhancement of putative EEG markers of consciousness: in comparison with non-responders, responders showed increases of power and long-range cortico-cortical functional connectivity in the theta-alpha band, and a larger and more sustained P300 suggesting improved conscious access to auditory novelty. The EEG changes correlated with electric fields strengths in prefrontal cortices, and no correlation was found on the scalp. Taken together, this prospective intervention in a large cohort of DoC patients strengthens the validity of the proposed EEG signatures of consciousness, and is suggestive of a direct causal effect of tDCS on consciousness.

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“…The long history, versatility and variety of applications of EEG makes it a data and method rich technique. The recent OHBM guideline for good practices and reproducibility in EEG (Pernet et al, 2018) lists eight preprocessing steps for standard event related potentials (identification and removal of electrodes with poor signal quality, artifact identification and removal, detrending, digital low-and high-pass filtering, data segmentation, additional identification/elimination of artifacts, baseline correction, and rereferencing) with the order of steps depending on applications and potentially augmented by additional transformation in time, frequency or time-frequency domains, projection into source space and additional connectivity measurements. This implies that while the BIDS-EEG will help data sharing, it will remain non-trivial to develop automated preprocessing pipelines of magneto- Niso et al (2018) and electrophysiological (Holdgraf et al, in preparation) prepared data such as fMRI BIDS apps (Gorgolewski et al, 2017).…”

Section: Data Analysis Pipeline and Reproducible Workflowsmentioning

confidence: 99%

BIDS-EEG: an extension to the Brain Imaging Data Structure (BIDS) Specification for electroencephalography

Pernet¹,

Appelhoff

Flandin³

et al. 2018

Preprint

Self Cite

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The Brain Imaging Data Structure (BIDS) project is a quickly evolving effort among the human brain imaging research community to create standards allowing researchers to readily organize and share study data within and between laboratories. The first BIDS standard was proposed for the MRI/fMRI research community and has now been widely adopted. More recently a magnetoencephalography (MEG) data extension, BIDS-MEG, has been published. Here we present an extension to BIDS for electroencephalography (EEG) data, BIDS-EEG, along with tools and references to a series of public EEG datasets organized using this new standard.

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Best Practices in Data Analysis and Sharing in Neuroimaging using MEEG

Cited by 48 publications

References 48 publications

How Sensitive are EEG Results to Preprocessing Methods: A Benchmarking Study

How Sensitive are EEG Results to Preprocessing Methods: A Benchmarking Study

Combined behavioral and electrophysiological evidence for a direct cortical effect of prefrontal tDCS on disorders of consciousness

BIDS-EEG: an extension to the Brain Imaging Data Structure (BIDS) Specification for electroencephalography

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