Abstract
Objective. Interictal epileptiform discharges (IEDs) occur between two seizures onsets. IEDs are mainly captured by intracranial recordings and are often invisible over the scalp. This study proposes a model based on tensor factorization to map the time-frequency (TF) features of scalp EEG (sEEG) to the TF features of intracranial EEG (iEEG) in order to detect IEDs from over the scalp with high sensitivity. Approach. Continuous wavelet transform is employed to extract the TF features. Time, frequency, and channel modes of IED segments from iEEG recordings are concatenated into a four-way tensor. Tucker and CANDECOMP/PARAFAC decomposition techniques are employed to decompose the tensor into temporal, spectral, spatial, and segmental factors. Finally, TF features of both IED and non-IED segments from scalp recordings are projected onto the temporal components for classification. Main results. The model performance is obtained in two different approaches: within- and between-subject classification approaches. Our proposed method is compared with four other methods, namely a tensor-based spatial component analysis method, TF-based method, linear regression mapping model, and asymmetric–symmetric autoencoder mapping model followed by convolutional neural networks. Our proposed method outperforms all these methods in both within- and between-subject classification approaches by respectively achieving 84.2% and 72.6% accuracy values. Significance. The findings show that mapping sEEG to iEEG improves the performance of the scalp-based IED detection model. Furthermore, the tensor-based mapping model outperforms the autoencoder- and regression-based mapping models.
Highlights
In [20], the authors show that when only Interictal epileptiform discharges (IEDs) are concatenated into a tensor the method provides significantly better performance as compared to when both IEDs and nonIEDs are included in the concatenation
The performance of MStI-CANDECOMP/PARAFAC decomposition (CPD) is comparable with MStI-TD and it classifies IED and non-IEDs with 81.3% accuracy and
Recall that the accuracy value includes those of scalp-invisible spikes, which are over 80% of the total spikes, too
Summary
Experiments pteThe iEEG was used as the ground truth for scoring the IEDs by an expert epileptologist who scored the IEDs based on the morphology and spatial distribution of the observed waveforms and put them in different groups.In our previous work [24], the scoring method has been completely described. The iEEG was used as the ground truth for scoring the IEDs by an expert epileptologist who scored the IEDs based on the morphology and spatial distribution of the observed waveforms and put them in different groups. Scalp-visible IED by considering the concurrent iEEG iii. Scalp-visible IED without considering the concurrent iEEG. All three groups of IEDs fall within the same IED class. 2. In the scalp-invisible IED segment, there is no sign of epileptiform discharges in the scalp channels, while the FO channels capture the IED waveforms. In the “scalp-visible IED by considering the concurrent iEEG”, a weak IED waveform can be detected in the scalp channels by referencing to the concurrent iEEG. In the “scalp-visible IED without considering the concurrent iEEG”, the epileptiform discharges are individually observable from the scalp channels
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