https://github.com/weiglszonja/meeg-tools

EEG/MEG data preprocessing and analyses framework
https://github.com/weiglszonja/meeg-tools

connectivity-analysis eeg-analysis eeg-preprocessing pipeline preprocessing-data time-frequency-analysis

Last synced: 6 days ago
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EEG/MEG data preprocessing and analyses framework

• Host: GitHub
• URL: https://github.com/weiglszonja/meeg-tools
• Owner: weiglszonja
• License: gpl-3.0
• Created: 2021-02-04T18:42:24.000Z (almost 4 years ago)
• Default Branch: master
• Last Pushed: 2022-05-02T13:56:48.000Z (over 2 years ago)
• Last Synced: 2024-12-02T12:42:50.965Z (20 days ago)
• Topics: connectivity-analysis, eeg-analysis, eeg-preprocessing, pipeline, preprocessing-data, time-frequency-analysis
• Language: Jupyter Notebook
• Homepage:
• Size: 120 MB
• Stars: 12
• Watchers: 2
• Forks: 4
• Open Issues: 0
• Metadata Files:
  • Readme: README.md
  • License: LICENSE

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In association with the Lyon Neuroscience Research Center (Lyon), Memo Team,

PI: [Dezso Nemeth](https://www.memoteam.org).

# meeg-tools

EEG/MEG data preprocessing and analyses framework

## Overview

The `meeg-tools` serves as a cookbook for preprocessing and analyzing EEG/MEG

signals in a semiautomatic and reproducible way. The general use-case of the

package is to use it from a Jupyter notebook. The

`tutorials` folder contains notebooks that demonstrate data operations

and transformations that are described in the Background section.

## Installation

Install the latest version from PyPI into an existing environment:

```bash

$ pip install meeg_tools

```

Since this project is under development, I would recommend installing it from

source in editable mode with pip:

```bash

$ git clone https://github.com/weiglszonja/meeg-tools.git

$ cd meeg-tools

$ pip install -e .

```

## Background

### Preprocessing

![Pipeline diagram](tutorials/static/preprocessing_pipeline_diagram.svg)

Electroencephalography (EEG) and magnetoencephalography (MEG) measures neural

activity of the brain. The signals that are recorded from multiple sensors are

inherently contaminated by noise. Preprocessing aims to attenuate noise in the

EEG/MEG data without removing meaningful signals in the process. Here, we

present a semiautomatic pipeline which can prepare the data for functional

connectivity or event related potential (ERP) analyses.

The meeg-tools package aims to serve as a semiautomatic and reproducible

framework for preprocessing EEG/MEG signals prior to time-frequency-based

analyses. It minimizes the manual steps required to clean the data based on

visual inspection and reduces the number of choices that depend on the

researcher for rejecting segments of data or interpolation of electrodes. This

package utilizes modules from mne-Python (Gramfort et al., 2013), a popular

open-source Python package for working with neurophysiological data. For

automated rejection of bad data spans and interpolation of bad electrodes it

uses the Autoreject (Jas et al., 2017) and the Random Sample Consensus (

RANSAC) (Bigdely-Shamlo et al., 2015) packages.

The general use-case of the package is to use it from a Jupyter notebook.

The `tutorials` folder contains notebooks demonstrating data operations such as

loading and writing the data along with the transformation steps that are

described below.

In order to remove high-frequency artefacts and low-frequency drifts, a

zero-phase band-pass filter (0.5 - 45 Hz) is applied to the continuous data

using mne-Python. This temporal filter adapts the filter length and transition

band size based on the cutoff frequencies. The lower and upper cutoff

frequencies can be changed in the configuration file (config.py) located at the

utils folder.

Subsequently, the filtered data is segmented into nonoverlapping segments (

epochs) to facilitate analyses. The default duration of epochs is one seconds,

however it can be changed in the configuration file.

The removal of bad data segments is done in three steps. First, epochs are

rejected based on a global threshold on the z-score (> 3) of the epoch variance

and amplitude range. To further facilitate the signal-to-noise ratio,

independent components analysis (ICA) is applied to the epochs. ICA is a

source-separation technique that decomposes the data into a set of components

that are unique sources of variance in the data. The number of components and

the algorithm to use can be specified in the configuration file. The default

method is the infomax algorithm that finds independent signals by maximizing

entropy as described by (Bell & Sejnowski, 1995), (Nadal & Parga, 1999).

Components containing blink artefacts are automatically identified using

mne-Python. The interactive visualization of ICA sources lets the user decide

which components should be rejected based on their topographies and

time-courses. The number of components that were removed from the data are

documented in the “description” field of the epochs instance “info” structure.

The final step of epoch rejection is to apply Autoreject (Jas et al., 2017) on

the ICA cleaned data. Autoreject uses unsupervised learning to estimate the

rejection threshold for the epochs. In order to reduce computation time that

increases with the number of epochs and channels, it is possibe to fit autoreject

on a representative subset of epochs (25% of total epochs). Once the parameters

are learned, the solution can be applied to any data that contains channels

that were used during fit.

The final step of preprocessing is to find and interpolate outlier channels.

The Random Sample Consensus (RANSAC) algorithm (Fischler & Bolles, 1981)

selects a random subsample of good channels to make predictions of each channel

in small non-overlapping 4 seconds long time windows. It uses a method of

spherical splines (Perrin et al., 1989) to interpolate the bad sensors.

Additionally, the EEG/MEG reference can be changed to a “virtual reference”

that is the average of all channels using mne-Python.

### Time-frequency analysis

The `tutorials` folder contains a jupyter notebook that demonstrates the usage

of some functions available in mne-Python for time-frequency analysis.

```bash

$ jupyter notebook tutorials/time_frequency_analysis_tutorial.ipynb

```

## Usage

The `tutorials` folder contains a sample jupyter notebook that demonstrates the

preprocessing pipeline.

See [this](https://mne.tools/stable/auto_tutorials/io/20_reading_eeg_data.html)

documentation about supported file formats.

```bash

$ jupyter notebook tutorials/preprocessing_tutorial_without_triggers.ipynb

```

## Tests

Run unittests from the terminal with:

```bash

$ python -m unittest

```

## Contribution

This project is under development; comments are all welcome and encouraged!

Suggestions related to this project can be made with opening an

[issue](https://github.com/weiglszonja/meeg-tools/issues/new)

at the issue tracker of the project. Contributions and enhancements to the code

can be made by forking the project first; committing changes to the forked

project and then opening a pull request from the forked branch to the master

branch of meeg-tools.

## References

Bell, A. J., & Sejnowski, T. J. (1995). An information-maximization approach to

blind separation and blind deconvolution. Neural Computation, 7(6), 1129–1159.

Bigdely-Shamlo, N., Mullen, T., Kothe, C.,

Su, K.-M., & Robbins, K. A. (2015). The PREP pipeline: standardized

preprocessing for large-scale EEG analysis. In Frontiers in Neuroinformatics (

Vol. 9). https://doi.org/10.3389/fninf.2015.00016

Fischler, M. A., & Bolles, R. C. (1981). Random sample consensus. In

Communications of the ACM (Vol. 24, Issue 6, pp. 381–395)

. https://doi.org/10.1145/358669.358692

Gramfort, A., Luessi, M., Larson, E., Engemann, D. A., Strohmeier, D.,

Brodbeck, C., Goj, R., Jas, M., Brooks, T., Parkkonen, L., & Hämäläinen, M. (

2013). MEG and EEG data analysis with MNE-Python. Frontiers in Neuroscience, 7,

267.

Jas, M., Engemann, D. A., Bekhti, Y., Raimondo, F., & Gramfort, A. (2017).

Autoreject: Automated artifact rejection for MEG and EEG data. NeuroImage, 159,

417–429.

Nadal, J.-P., & Parga, N. (1999). SENSORY CODING: INFORMATION MAXIMIZATION AND

REDUNDANCY REDUCTION. In Neuronal Information Processing (pp. 164–171)

. https://doi.org/10.1142/9789812818041_0008

Perrin, F., Pernier, J., Bertrand, O., & Echallier, J. F. (1989). Spherical

splines for scalp potential and current density mapping. Electroencephalography

and Clinical Neurophysiology, 72(2), 184–187.