Automated Detection of High Frequency Oscillations in Intracranial EEG Using the Combination of Short-Time Energy and Convolutional Neural Networks

Lai, Dakun; Zhang, Xinyue; Ma, Kefei; Chen, Zichu; Chen, Wenjing; Zhang, Heng; Yuan, Han; Ding, Lei

doi:10.1109/access.2019.2923281

Cited by 32 publications

(28 citation statements)

References 29 publications

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“…We used only energy features, because they do not need information regarding the whole duration of the signal [29] and have low computational cost [38] in view of a future real-time application. Moreover, the energy computation in 5 and 10 ms windows has been already validated by [39,40].…”

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confidence: 99%

Double-Step Machine Learning Based Procedure for HFOs Detection and Classification

Sciaraffa

Klados²,

Borghini

et al. 2020

Brain Sciences

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The need for automatic detection and classification of high-frequency oscillations (HFOs) as biomarkers of the epileptogenic tissue is strongly felt in the clinical field. In this context, the employment of artificial intelligence methods could be the missing piece to achieve this goal. This work proposed a double-step procedure based on machine learning algorithms and tested it on an intracranial electroencephalogram (iEEG) dataset available online. The first step aimed to define the optimal length for signal segmentation, allowing for an optimal discrimination of segments with HFO relative to those without. In this case, binary classifiers have been tested on a set of energy features. The second step aimed to classify these segments into ripples, fast ripples and fast ripples occurring during ripples. Results suggest that LDA applied to 10 ms segmentation could provide the highest sensitivity (0.874) and 0.776 specificity for the discrimination of HFOs from no-HFO segments. Regarding the three-class classification, non-linear methods provided the highest values (around 90%) in terms of specificity and sensitivity, significantly different to the other three employed algorithms. Therefore, this machine-learning-based procedure could help clinicians to automatically reduce the quantity of irrelevant data.

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confidence: 99%

Double-Step Machine Learning Based Procedure for HFOs Detection and Classification

Sciaraffa

Klados²,

Borghini

et al. 2020

Brain Sciences

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show abstract

“…Zuo et al 33 proposed the CNN-based method for identifying the two kind of HFOs in ripple and fast-ripple separately and achieved average results with sensitivity (77.04% and 83.23% for ripples) and specificity (72.27% and 79.36% for fast ripples) compared to four traditional automated methods proposed in the RIPPLELAB toolbox 32 . The combination of short-time energy (STE) and CNN also used in recent study for identifying HFOs 60 . In their study, the performance of the system in terms of sensitivity and FDR are used to evaluate their system and compared with three related existing studies 32,36,57 .…”

Section: Discussionmentioning

confidence: 99%

Multiband entropy-based feature-extraction method for automatic identification of epileptic focus based on high-frequency components in interictal iEEG

Akter

Islam

Iimura

et al. 2020

Sci Rep

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presurgical investigations for categorizing focal patterns are crucial, leading to localization and surgical removal of the epileptic focus. this paper presents a machine learning approach using information theoretic features extracted from high-frequency subbands to detect the epileptic focus from interictal intracranial electroencephalogram (ieeG). it is known that high-frequency subbands (>80 Hz) include important biomarkers such as high-frequency oscillations (Hfos) for identifying epileptic focus commonly referred to as the seizure onset zone (SoZ). in this analysis, the multi-channel interictal ieeG signals were splitted into segments and each segment was decomposed into multiple high-frequency subbands. The different types of entropy were calculated for each of the subbands and the sparse linear discriminant analysis (sLDA) was applied to select the prominent entropy features. Due to the imbalance of SoZ and non-SoZ channels in ieeG data, the use of machine learning techniques is always tricky. to deal with the imbalanced learning problem, an adaptive synthetic oversampling approach (ADASYn) with radial basis function kernel-based SVM was used to detect the focal segments. finally, the epileptic focus was identified based on detection of focal segments on SOZ and non-SOZ channels. Eight patients were examined to observe the efficiency of the automatic detector. The experimental results and statistical tests indicate that the proposed automatic detector can identify the epileptic focus accurately and efficiently.

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“…Zuo et al 33 proposed the CNN-based method for identifying the two kind of HFOs in ripple and fast-ripple separately and achieved average results with sensitivity (77.04% and 83.23% for ripples) and specificity (72.27% and 79.36% for fast ripples) compared to four traditional automated methods proposed in the RIPPLELAB toolbox 32 . The combination of short-time energy (STE) and CNN also used in recent study for identifying HFOs 62 . In their study, the performance of the system in terms of sensitivity and FDR are used to evaluate their system and compared with three related existing studies 32,36,59 .…”

Section: Discussionmentioning

confidence: 99%

Multiband entropy-based feature-extraction method for automatic identification of epileptic focus based on high-frequency components in interictal iEEG

Akter

Islam

Iimura

et al. 2020

Preprint

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Presurgical investigations for categorizing focal patterns are crucial, leading to localization and surgical removal of the epileptic focus. This paper presents a machine learning approach using information theoretic features extracted from high-frequency subbands to detect the epileptic focus from interictal intracranial electroencephalogram (iEEG). It is known that high-frequency subbands (>80 Hz) include important biomarkers such as high-frequency oscillations (HFOs) for identifying epileptic focus commonly referred to as the seizure on-set zone (SOZ). In this analysis, the multi-channel interictal iEEG signals were splitted into segments and each segment was decomposed into multiple high-frequency subbands. The different types of entropy were calculated for each of the subbands and the sparse linear discriminant analysis (sLDA) was applied to select the prominent entropy features. Due to the imbalance of SOZ and non-SOZ channels in iEEG data, the use of machine learning techniques is always tricky. To deal with the imbalanced learning problem, an adaptive synthetic oversampling approach (ADASYN) with radial basis function kernel-based SVM was used to detect the focal segments. Finally, the epileptic focus was identified based on detection of focal segments on SOZ and non-SOZ channels. Eight patients were examined to observe the efficiency of the automatic detector. The experimental results and statistical tests indicate that the proposed automatic detector can identify the epileptic focus accurately and efficiently.

show abstract

Automated Detection of High Frequency Oscillations in Intracranial EEG Using the Combination of Short-Time Energy and Convolutional Neural Networks

Cited by 32 publications

References 29 publications

Double-Step Machine Learning Based Procedure for HFOs Detection and Classification

Double-Step Machine Learning Based Procedure for HFOs Detection and Classification

Multiband entropy-based feature-extraction method for automatic identification of epileptic focus based on high-frequency components in interictal iEEG

Multiband entropy-based feature-extraction method for automatic identification of epileptic focus based on high-frequency components in interictal iEEG

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