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Abstract
ObjectiveIntracranial electroencephalographic (iEEG) recordings contain “bad channels”, which show non-neuronal signals. Here, we developed a new method that automatically detects iEEG bad channels using machine learning of seven signal features. MethodsThe features quantified signals’ variance, spatial–temporal correlation and nonlinear properties. Because the number of bad channels is usually much lower than the number of good channels, we implemented an ensemble bagging classifier known to be optimal in terms of stability and predictive accuracy for datasets with imbalanced class distributions. This method was applied on stereo-electroencephalographic (SEEG) signals recording during low frequency stimulations performed in 206 patients from 5 clinical centers. ResultsWe found that the classification accuracy was extremely good: It increased with the number of subjects used to train the classifier and reached a plateau at 99.77% for 110 subjects. The classification performance was thus not impacted by the multicentric nature of data. ConclusionsThe proposed method to automatically detect bad channels demonstrated convincing results and can be envisaged to be used on larger datasets for automatic quality control of iEEG data. SignificanceThis is the first method proposed to classify bad channels in iEEG and should allow to improve the data selection when reviewing iEEG signals.
Highlights
We propose here a methodological approach that automatically identifies the bad channels from Intracranial electroencephalographic (iEEG) recordings using ensemble bagging machine learning
It was applied to multicentre large datasets that contained bad channels as found in standard continuous recordings, and disconnected channels during direct electrical stimulations
The main property of the method is the use of different features and ensemble bagging classifier to identify the bad channels and to cope with datasets with imbalanced class distributions
Summary
(electrocorticography, ECoG) (Fernández and Loddenkemper, 2013), are used to localize the epileptogenic zone in some patients with drug-resistant focal epilepsy where other non-invasive measures are limited. These techniques permit to collect prominent data for assessing brain dynamics in pathological and physiological conditions. They allow studying human brain connectivity by measuring intracranial responses to direct electrical stimulations (DES) (David et al, 2010; Selimbeyoglu and Parvizi, 2010; Keller et al, 2014). The signals recorded on the two electrodes of stimulation become automatically noisy because the inputs of the amplifier are no longer measuring brain signals
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