The morphology of high frequency oscillations (HFO) does not improve delineating the epileptogenic zone

Burnos, Sergey; Frauscher, Birgit; Zelmann, Rina; Haegelen, Claire; Sarnthein, Johannes; Gotman, Jean

doi:10.1016/j.clinph.2016.01.002

Cited by 79 publications

(90 citation statements)

References 38 publications

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“…In accord with other published literature (Burnos et al, 2016), both true and false ripples on spike rates were equivalently increased in the SOZ as compared with the NSOZ.…”

Section: Discussionsupporting

confidence: 91%

Utilization of independent component analysis for accurate pathological ripple detection in intracranial EEG recordings recorded extra- and intra-operatively

Shimamoto

Waldman

Orosz

et al. 2018

Clinical Neurophysiology

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Objective To develop and validate a detector that identifies ripple (80–200 Hz) events in intracranial EEG (iEEG) recordings in a referential montage and utilizes independent component analysis (ICA) to eliminate or reduce high-frequency artifact contamination. Also, investigate the correspondence of detected ripples and the seizure onset zone (SOZ). Methods iEEG recordings from 16 patients were first band-pass filtered (80–600 Hz) and Infomax ICA was next applied to derive the first independent component (IC1). IC1 was subsequently pruned, and an artifact index was derived to reduce the identification of high-frequency events introduced by the reference electrode signal. A Hilbert detector identified ripple events in the processed iEEG recordings using amplitude and duration criteria. The identified ripple events were further classified and characterized as true or false ripple on spikes, or ripples on oscillations by utilizing a topographical analysis to their time-frequency plot, and confirmed by visual inspection. Results The signal to noise ratio was improved by pruning IC1. The precision of the detector for ripple events was 91.27 ± 4.3%, and the sensitivity of the detector was 79.4 ± 3.0% (N = 16 patients, 5842 ripple events). The sensitivity and precision of the detector was equivalent in iEEG recordings obtained during sleep or intra-operatively. Across all the patients, true ripple on spike rates and also the rates of false ripple on spikes, that were generated due to filter ringing, classified the seizure onset zone (SOZ) with an area under the receiver operating curve (AUROC) of >76%. The magnitude and spectral content of true ripple on spikes generated in the SOZ was distinct as compared with the ripples generated in the NSOZ (p < .001). Conclusions Utilizing ICA to analyze iEEG recordings in referential montage provides many benefits to the study of high-frequency oscillations. The ripple rates and properties defined using this approach may accurately delineate the seizure onset zone. Significance Strategies to improve the spatial resolution of intracranial EEG and reduce artifact can help improve the clinical utility of HFO biomarkers.

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“…In accord with other published literature (Burnos et al, 2016), both true and false ripples on spike rates were equivalently increased in the SOZ as compared with the NSOZ.…”

Section: Discussionsupporting

confidence: 91%

Utilization of independent component analysis for accurate pathological ripple detection in intracranial EEG recordings recorded extra- and intra-operatively

Shimamoto

Waldman

Orosz

et al. 2018

Clinical Neurophysiology

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“…Though it remains uncertain that true HFOs exhibit superior accuracy for delineating epileptogenic brain regions, as compared with sharply contoured IES events (Burnos et al, 2016), the subject merits further investigation. Furthermore, only true ripple on spike events can be assigned properties such as mean spectral content, power, and duration.…”

Section: Discussionmentioning

confidence: 99%

“…Utilization of this method will assist in the determination of whether true HFO events are generated by distinct mechanisms as compared with false HFO events. Further, it will aid in the investigation of true and false RonS with respect to understanding and differentiating their mechanisms of generation (Schevon et al, 2009; Keller et al, 2010), utility for identifying epileptogenic regions (Burnos et al, 2016), role during seizures (Eissa et al, 2016), and also their ability to disrupt normal cognition (Horak et al, 2017). The topographical method we describe is one of many “computer vision” based approaches to identifying multiple distinct brief oscillatory events that overlap in time, but are unique in spectral content (Burnos et al, 2014; Kucewicz et al, 2017).…”

Section: Discussionmentioning

confidence: 99%

A method for the topographical identification and quantification of high frequency oscillations in intracranial electroencephalography recordings

Waldman

Shimamoto

Song

et al. 2018

Clinical Neurophysiology

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Objective To develop a reliable software method using a topographic analysis of time-frequency plots to distinguish ripple (80–200 Hz) oscillations that are often associated with EEG sharp waves or spikes (RonS) from sinusoid-like waveforms that appear as ripples but correspond with digital filtering of sharp transients contained in the wide bandwidth EEG. Methods A custom algorithm distinguished true from false ripples in one second intracranial EEG (iEEG) recordings using wavelet convolution, identifying contours of isopower, and categorizing these contours into sets of open or closed loop groups. The spectral and temporal features of candidate groups were used to classify the ripple, and determine its duration, frequency, and power. Verification of detector accuracy was performed on the basis of simulations, and visual inspection of the original and band-pass filtered signals. Results The detector could distinguish simulated true from false ripple on spikes (RonS). Among 2934 visually verified trials of iEEG recordings and spectrograms exhibiting RonS the accuracy of the detector was 88.5% with a sensitivity of 81.8% and a specificity of 95.2%. The precision was 94.5% and the negative predictive value was 84.0% (N = 12). Among, 1,370 trials of iEEG recording exhibiting RonS that were reviewed blindly without spectrograms the accuracy of the detector was 68.0%, with kappa equal to 0.01 ± 0.03. The detector successfully distinguished ripple from high spectral frequency ‘fast ripple’ oscillations (200–600 Hz), and characterize ripple duration and spectral frequency and power. The detector was confounded by brief bursts of gamma (30–80 Hz) activity in 7.31 ± 6.09% of trials, and in 30.2 ± 14.4% of the true RonS detections ripple duration was underestimated. Conclusions Characterizing the topographic features of a time-frequency plot generated by wavelet convolution is useful for distinguishing true oscillations from false oscillations generated by filter ringing. Significance Categorizing ripple oscillations and characterizing their properties can improve the clinical utility of the biomarker.

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“…The morphology of HFOs does not improve delineation of the EZ either [56]. Analyzing the EEG characteristics associated with ripples may be useful for identifying pathological ripples.…”

Section: High-frequency Oscillationsmentioning

confidence: 95%

Advances of Intracranial Electroencephalography in Localizing the Epileptogenic Zone

Jin

Wang

2016

Neurosci. Bull.

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Intracranial electroencephalography (iEEG) provides the best precision in estimating the location and boundary of an epileptogenic zone. Analysis of iEEG in the routine EEG frequency range (0.5-70 Hz) remains the basis in clinical practice. Low-voltage fast activity is the most commonly reported ictal onset pattern in neocortical epilepsy, and low-frequency high-amplitude repetitive spiking is the most commonly reported ictal onset pattern in mesial temporal lobe epilepsy. Recent studies using wideband EEG recording have demonstrated that examining higher (80-1000 Hz) and lower (0.016-0.5 Hz) EEG frequencies can provide additional diagnostic information and help to improve the surgical outcome. In addition, novel computational techniques of iEEG signal analysis have provided new insights into the epileptic network. Here, we review some of these recent advances. Although these sophisticated and advanced techniques of iEEG analysis show promise in localizing the epileptogenic zone, their utility needs to be further validated in larger studies.

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The morphology of high frequency oscillations (HFO) does not improve delineating the epileptogenic zone

Cited by 79 publications

References 38 publications

Utilization of independent component analysis for accurate pathological ripple detection in intracranial EEG recordings recorded extra- and intra-operatively

Utilization of independent component analysis for accurate pathological ripple detection in intracranial EEG recordings recorded extra- and intra-operatively

A method for the topographical identification and quantification of high frequency oscillations in intracranial electroencephalography recordings

Advances of Intracranial Electroencephalography in Localizing the Epileptogenic Zone

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