SGM: a novel time-frequency algorithm based on unsupervised learning improves high-frequency oscillation detection in epilepsy

Migliorelli, Carolina; Bachiller, Alejandro; Alonso, Joan Francesc; Romero, Sergio; Aparicio, Javier Romano; Van, Julia Jacobs-Le; Mañanas, Miguel Ángel; Antonio‐Arce, Victoria San

doi:10.1088/1741-2552/ab8345

Cited by 17 publications

(15 citation statements)

References 44 publications

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“…16 studies incorporated time-frequency analysis into their HFO detection algorithms [10,14,[35][36][37][38][39][40][41][42][43][44][45][46][47][48]. 12 studies leveraged iEEG, 2 studies leveraged both iEEG and MEG, and 2 studies used scalp EEG.…”

Section: Time-frequency Domainmentioning

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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Section: Time-frequency Domainmentioning

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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“…The SGM algorithm was used to detect HFOs in the ripple band (80-200 Hz). SGM is already published and was validated using simulated and real data assessed by two experts [28]. Briefly, the algorithm consists of: (a) baseline estimation using the entropy of the autocorrelation; (b) S-Transform [29] to calculate time-frequency features; and (c) GMM-based clustering of the features to decide if events are HFO-like activity.…”

Section: Hfos Detectionmentioning

confidence: 99%

Improving the ripple classification in focal pediatric epilepsy: identifying pathological high-frequency oscillations by Gaussian mixture model clustering

et al. 2021

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Objective. High-frequency oscillations (HFOs) have emerged as a promising clinical biomarker for presurgical evaluation in childhood epilepsy. HFOs are commonly classified in stereo-encephalography as ripples (80–200 Hz) and fast ripples (200–500 Hz). Ripples are less specific and not so directly associated with epileptogenic activity because of their physiological and pathological origin. The aim of this paper is to distinguish HFOs in the ripple band and to improve the evaluation of the epileptogenic zone (EZ). Approach. This study constitutes a novel modeling approach evaluated in ten patients from Sant Joan de Deu Pediatric Hospital (Barcelona, Spain), with clearly-defined seizure onset zones (SOZ) during presurgical evaluation. A subject-by-subject basis analysis is proposed: a probabilistic Gaussian mixture model (GMM) based on the combination of specific ripple features is applied for estimating physiological and pathological ripple subpopulations. Main Results. Clear pathological and physiological ripples are identified. Features differ considerably among patients showing within-subject variability, suggesting that individual models are more appropriate than a traditional whole-population approach. The difference in rates inside and outside the SOZ for pathological ripples is significantly higher than when considering all the ripples. These significant differences also appear in signal segments without epileptiform activity. Pathological ripple rates show a sharp decline from SOZ to non-SOZ contacts and a gradual decrease with distance. Significance. This novel individual GMM approach improves ripple classification and helps to refine the delineation of the EZ, as well as being appropriate to investigate the interaction of epileptogenic and propagation networks.

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“…Two classification methods were used to analyze the group distribution of RTT patients: The Kernel Density Estimation (KDE), which represents the data using a continuous two-dimensional probability density curve that is analogous to a histogram and the Gaussian Mixture Model (GMM), which depicts the density representation as the weighted sum of Gaussian distributions. The GMM algorithm was applied to the dataset for fitting three mixture-of-Gaussian models and to assign each record to the Gaussian model it mostly belongs to [20]. As it is a probabilistic model, we filtered by probabilities to keep only those records with a probability (p) greater than 95% of belonging to its group, obtaining clearly differentiated data.…”

Section: Data Classification Based On the Data Distributionmentioning

confidence: 99%

“…The most common method to remove artifacts from the EEG has been to rule out the activity that exceeds a certain threshold (usually ± 150 µV). An alternative to this method is based on the same idea of using a threshold but calculated from the data distribution, with the mean and standard deviation (SD) of each EEG channel [20]. An adaptive threshold is obtained using a k-factor: mean + k-factor × SD.…”

Section: Introductionmentioning

confidence: 99%

Choosing Strategies to Deal with Artifactual EEG Data in Children with Cognitive Impairment

Tost

Migliorelli

Bachiller

et al. 2021

Entropy

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Rett syndrome is a disease that involves acute cognitive impairment and, consequently, a complex and varied symptomatology. This study evaluates the EEG signals of twenty-nine patients and classify them according to the level of movement artifact. The main goal is to achieve an artifact rejection strategy that performs well in all signals, regardless of the artifact level. Two different methods have been studied: one based on the data distribution and the other based on the energy function, with entropy as its main component. The method based on the data distribution shows poor performance with signals containing high amplitude outliers. On the contrary, the method based on the energy function is more robust to outliers. As it does not depend on the data distribution, it is not affected by artifactual events. A double rejection strategy has been chosen, first on a motion signal (accelerometer or EEG low-pass filtered between 1 and 10 Hz) and then on the EEG signal. The results showed a higher performance when working combining both artifact rejection methods. The energy-based method, to isolate motion artifacts, and the data-distribution-based method, to eliminate the remaining lower amplitude artifacts were used. In conclusion, a new method that proves to be robust for all types of signals is designed.

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SGM: a novel time-frequency algorithm based on unsupervised learning improves high-frequency oscillation detection in epilepsy

Cited by 17 publications

References 44 publications

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

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

Improving the ripple classification in focal pediatric epilepsy: identifying pathological high-frequency oscillations by Gaussian mixture model clustering

Choosing Strategies to Deal with Artifactual EEG Data in Children with Cognitive Impairment

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