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

Sciaraffa, Nicolina; Klados, Manousos A.; Borghini, Gianluca; Flumeri, Gianluca Di; Babiloni, Fabio; Aricò, Pietro

doi:10.3390/brainsci10040220

Cited by 21 publications

(23 citation statements)

References 52 publications

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“…In more recent studies, the automatic detector using the combination of short-time energy and CNN reported in 2019 achieved a sensitivity of 91.26%, a specificity of 91.52%, and a precision of 88.67% in 2700 HFO events from 5 patients [ 21 ]. Sciaraffa et al [ 27 ] proposed a new double-step machine learning method in 2020 to detect HFOs, which achieved a sensitivity of 87.40% and a specificity of 77.60%. Guo et al [ 45 ] developed a hypergraph-based detector to automatically detect HFOs in 2021, which achieved an accuracy of 90.7%, a sensitivity of 80.9%, and a specificity of 96.9%.…”

Section: Resultsmentioning

confidence: 99%

“…In early studies, researchers mostly focused on the performance of signal detection, so in terms of dividing experimental data, most of them randomly divide training set and test set from the candidate pool [ 21 , 27 , 43 , 45 , 46 ]. In clinical application, when considering a new patient, it is desirable to transfer the a priori knowledge learned from previous existing cases to the judgment of the new patient.…”

Section: Discussionmentioning

confidence: 99%

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[Retracted] Automatic Detection of High‐Frequency Oscillations Based on an End‐to‐End Bi‐Branch Neural Network and Clinical Cross‐Validation

Liu

Wei

Wang

et al. 2021

Computational Intelligence and Neuroscience

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Accurate identification of high-frequency oscillation (HFO) is an important prerequisite for precise localization of epileptic foci and good prognosis of drug-refractory epilepsy. Exploring a high-performance automatic detection method for HFOs can effectively help clinicians reduce the error rate and reduce manpower. Due to the limited analysis perspective and simple model design, it is difficult to meet the requirements of clinical application by the existing methods. Therefore, an end-to-end bi-branch fusion model is proposed to automatically detect HFOs. With the filtered band-pass signal (signal branch) and time-frequency image (TFpic branch) as the input of the model, two backbone networks for deep feature extraction are established, respectively. Specifically, a hybrid model based on ResNet1d and long short-term memory (LSTM) is designed for signal branch, which can focus on both the features in time and space dimension, while a ResNet2d with a Convolutional Block Attention Module (CBAM) is constructed for TFpic branch, by which more attention is paid to useful information of TF images. Then the outputs of two branches are fused to realize end-to-end automatic identification of HFOs. Our method is verified on 5 patients with intractable epilepsy. In intravalidation, the proposed method obtained high sensitivity of 94.62%, specificity of 92.7%, and F1-score of 93.33%, and in cross-validation, our method achieved high sensitivity of 92.00%, specificity of 88.26%, and F1-score of 89.11% on average. The results show that the proposed method outperforms the existing detection paradigms of either single signal or single time-frequency diagram strategy. In addition, the average kappa coefficient of visual analysis and automatic detection results is 0.795. The method shows strong generalization ability and high degree of consistency with the gold standard meanwhile. Therefore, it has great potential to be a clinical assistant tool.

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

[Retracted] Automatic Detection of High‐Frequency Oscillations Based on an End‐to‐End Bi‐Branch Neural Network and Clinical Cross‐Validation

Liu

Wei

Wang

et al. 2021

Computational Intelligence and Neuroscience

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show abstract

“…Class imbalance is another issue in the feature classification step of HFO detection, which is caused by the fact that the number of HFOs is significantly less than that of fHFOs in iEEG signals [19], [31]. This class imbalance will sharply drop the classification performance since the class-imbalanced data distribution between HFOs and fHFOs biases classifiers toward the majority class (i.e., the fHFO class) [32].…”

Section: Introductionmentioning

confidence: 99%

HFO Detection in Epilepsy: A Stacked Denoising Autoencoder and Sample Weight Adjusting Factors-Based Method

Wu¹,

Qin

Wan

et al. 2021

IEEE Trans. Neural Syst. Rehabil. Eng.

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High-frequency oscillations (HFOs) recorded by the intracranial electroencephalography (iEEG) are the promising biomarkers of epileptogenic zones. Accurate detection of HFOs is the key to pre-operative assessment for epilepsy. Due to the subjective bias caused by manual features and the class imbalance between HFOs and false HFOs, it is difficult to obtain satisfactory detection performance by the existing methods. To solve these problems, we put forward a novel method to accurately detect HFOs based on the stacked denoising autoencoder (SDAE) and the ensemble classifier with sample weight adjusting factors. First, the adjustable threshold of Hilbert envelopes is proposed to isolate the events of interest (EoIs) from background activities. Then, the SDAE network is utilized to automatically extract features of EoIs in the time-frequency domain. Finally, the AdaBoost-based support vector machine ensemble classifier with sample weight adjusting factors is devised to separate HFOs from EoIs by using the extracted features. These adjusting factors are used to solve the class imbalance problem by adjusting sample weights when learning the base classifiers. Our HFO detection method is evaluated by using clinical iEEG data recorded from 20 patients with medically refractory epilepsy. The experimental results show that our detection method outperforms some existing methods in terms of sensitivity and false discovery rate. In addition, the HFOs detected by our method are effective for localizing seizure onset zones.

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“…These detectors often employed multi-stage algorithms, which involved the identification of putative HFO events, extraction of features from these events, and subsequent use of the extracted features to cluster oscillatory events or train the algorithm. Akin to detectors employing time-frequency analysis, variable methods were used for the initial detection of putative HFO events including energy thresholding [54,68] and multi-feature extraction [56,59]. Methods to reject false positive HFO events included analysis of the duration of the event and amplitude threshold.…”

Section: Data Mining or Machine Learningmentioning

confidence: 99%

Detection of high-frequency oscillations in electroencephalography: A scoping review and an adaptable open-source framework

Wong

Arski

Workewych

et al. 2021

Seizure

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

Cited by 21 publications

References 52 publications

[Retracted] Automatic Detection of High‐Frequency Oscillations Based on an End‐to‐End Bi‐Branch Neural Network and Clinical Cross‐Validation

[Retracted] Automatic Detection of High‐Frequency Oscillations Based on an End‐to‐End Bi‐Branch Neural Network and Clinical Cross‐Validation

HFO Detection in Epilepsy: A Stacked Denoising Autoencoder and Sample Weight Adjusting Factors-Based Method

Detection of high-frequency oscillations in electroencephalography: A scoping review and an adaptable open-source framework

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