Automatic seizure detection using three-dimensional CNN based on multi-channel EEG

Wei, Xiaoyan; Zhou, Lin; Chen, Ziyi; Zhang, Liangjun; Zhou, Yi

doi:10.1186/s12911-018-0693-8

Cited by 98 publications

(44 citation statements)

References 43 publications

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“…In this way, each time window, or segment, has 1280 data points in the 11D space. e data segmentation allows to increase the number of training samples, which is mandatory, especially in deep learning [26,29]. For the training of the network, the data from seizures were segmented with an overlap with the previous window of 0.1484 s, 0.5508 s, 1 s, for patient #5, patient #6, and patient #9, respectively.…”

Section: Eeg Segmentation and Datamentioning

confidence: 99%

“…e results, presented in terms of median true positive rate labelling by seconds is 74%, which the authors claimed to be higher than that of commercially available seizure detection software. In [29], each single-channel EEG signal is converted into a 2D plot and the plots corresponding to 22 different EEG channels are combined in 3D images depending on the mutual correlation of the intensities between the electrodes. en, using 3D kernels, a 3D CNN, with 4 convolutional layers, 3 max pooling layers, and 2 fully connected layers, has been built to detect interictal, preictal, and ictal stages in 13 epileptic patients.…”

Section: Introductionmentioning

confidence: 99%

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Convolutional Neural Network for Seizure Detection of Nocturnal Frontal Lobe Epilepsy

et al. 2020

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The Nocturnal Frontal Lobe Epilepsy (NFLE) is a form of epilepsy in which seizures occur predominantly during sleep. In other forms of epilepsy, the commonly used clinical approach mainly involves manual inspection of encephalography (EEG) signals, a laborious and time-consuming process which often requires the contribution of more than one experienced neurologist. In the last decades, numerous approaches to automate this detection have been proposed and, more recently, machine learning has shown very promising performance. In this paper, an original Convolutional Neural Network (CNN) architecture is proposed to develop patient-specific seizure detection models for three patients affected by NFLE. The performances, in terms of accuracy, sensitivity, and specificity, exceed by several percentage points those in the most recent literature. The capability of the patient-specific models has been also tested to compare the obtained seizure onset times with those provided by the neurologists, with encouraging results. Moreover, the same CNN architecture has been used to develop a cross-patient seizure detection system, resorting to the transfer-learning paradigm. Starting from a patient-specific model, few data from a new patient are enough to customize his model. This contribution aims to alleviate the task of neurologists, who may have a robust indication to corroborate their clinical conclusions.

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Section: Eeg Segmentation and Datamentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Convolutional Neural Network for Seizure Detection of Nocturnal Frontal Lobe Epilepsy

et al. 2020

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“…For each input modality, different architectures were evaluated depending on the dimensionality of the data (1D or 2D). In another study, the authors proposed the use of 3D inputs from multi-channel EEG recordings 22 ; the results over 13 patients with 159 seizures demonstrated that 3D models surpassed 2D models in metrics such as accuracy, specificity and sensitivity in about two points. However, 3D models have a larger number of parameters to be learned, and thus require much more training samples.…”

Section: Introductionmentioning

confidence: 99%

Automatic seizure detection based on imaged-EEG signals through fully convolutional networks

Gómez

Arbeláez

Navarrete

et al. 2020

Sci Rep

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Seizure detection is a routine process in epilepsy units requiring manual intervention of well-trained specialists. This process could be extensive, inefficient and time-consuming, especially for long term recordings. We proposed an automatic method to detect epileptic seizures using an imaged-EEG representation of brain signals. To accomplish this, we analyzed EEG signals from two different datasets: the CHB-MIT Scalp EEG database and the EPILEPSIAE project that includes scalp and intracranial recordings. We used fully convolutional neural networks to automatically detect seizures. For our best model, we reached average accuracy and specificity values of 99.3% and 99.6%, respectively, for the CHB-MIT dataset, and corresponding values of 98.0% and 98.3% for the EPILEPSIAE patients. For these patients, the inclusion of intracranial electrodes together with scalp ones increased the average accuracy and specificity values to 99.6% and 58.3%, respectively. Regarding the other metrics, our best model reached average precision of 62.7%, recall of 58.3%, F-measure of 59.0% and AP of 54.5% on the CHB-MIT recordings, and comparatively lowers performances for the EPILEPSIAE dataset. For both databases, the number of false alarms per hour reached values less than 0.5/h for 92% of the CHB-MIT patients and less than 1.0/h for 80% of the EPILEPSIAE patients. Compared to recent studies, our lightweight approach does not need any estimation of pre-selected features and demonstrates high performances with promising possibilities for the introduction of such automatic methods in the clinical practice.

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“…These studies have been based on different deep neural network structures, such as a fully connected neural network (FCNN) 24 , convolutional neural network (CNN) 22,[25][26][27] , and recurrent neural network (RNN) 28 . These different neural networks can automatically learn discriminative features from various types of data input, including raw temporal EEG 26 , FFT results 25 , 2-dimensional (2D) representation of STFT results 29 , and 2D images of raw EEG 27 . The adoption of different input forms and network structures typically makes it difficult to directly compare performance among different deep learning methods.…”

mentioning

confidence: 99%

“…Furthermore, these studies adopted different window sizes for EEG segmentation (e.g., 1-25 , 2-29 , 3-22 , 5- 24,27 , 8-26 , and 23.6-s 28 windows). In addition, the classifiers were trained and tested on different datasets including public EEG datasets such as the Bonn 22,28 , CHB-MIT 25,29 , and Freiburg 25 datasets, or their own datasets 24,27 . Thus, it is almost impossible to directly compare the results of different studies to ascertain an optimal combination of input modalities and network structures.…”

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confidence: 99%

Comparison of different input modalities and network structures for deep learning-based seizure detection

Cho

Jang

2020

Sci Rep

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The manual review of an electroencephalogram (EEG) for seizure detection is a laborious and errorprone process. Thus, automated seizure detection based on machine learning has been studied for decades. Recently, deep learning has been adopted in order to avoid manual feature extraction and selection. In the present study, we systematically compared the performance of different combinations of input modalities and network structures on a fixed window size and dataset to ascertain an optimal combination of input modalities and network structures. The raw time-series EEG, periodogram of the EEG, 2D images of short-time Fourier transform results, and 2D images of raw EEG waveforms were obtained from 5-s segments of intracranial EEGs recorded from a mouse model of epilepsy. A fully connected neural network (FCNN), recurrent neural network (RNN), and convolutional neural network (CNN) were implemented to classify the various inputs. The classification results for the test dataset showed that CNN performed better than FCNN and RNN, with the area under the curve (AUC) for the receiver operating characteristics curves ranging from 0.983 to 0.984, from 0.985 to 0.989, and from 0.989 to 0.993 for FCNN, RNN, and CNN, respectively. As for input modalities, 2D images of raw EEG waveforms yielded the best result with an AUC of 0.993. Thus, CNN can be the most suitable network structure for automated seizure detection when applied to the images of raw EEG waveforms, since CNN can effectively learn a general spatially-invariant representation of seizure patterns in 2D representations of raw EEG.

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Automatic seizure detection using three-dimensional CNN based on multi-channel EEG

Cited by 98 publications

References 43 publications

Convolutional Neural Network for Seizure Detection of Nocturnal Frontal Lobe Epilepsy

Convolutional Neural Network for Seizure Detection of Nocturnal Frontal Lobe Epilepsy

Automatic seizure detection based on imaged-EEG signals through fully convolutional networks

Comparison of different input modalities and network structures for deep learning-based seizure detection

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