Mostefa Mesbah scite author profile

Abstract-The detection of seizure in the newborn is a critical aspect of neurological research. Current automatic detection techniques are difficult to assess due to the problems associated with acquiring and labelling newborn electroencephalogram (EEG) data. A realistic model for newborn EEG would allow confident development, assessment and comparison of these detection techniques. This paper presents a model for newborn EEG that accounts for its self-similar and nonstationary nature. The model consists of background and seizure submodels. The newborn EEG background model is based on the short-time power spectrum with a time-varying power law. The relationship between the fractal dimension and the power law of a power spectrum is utilized for accurate estimation of the short-time power law exponent. The newborn EEG seizure model is based on a well-known time-frequency signal model. This model addresses all significant time-frequency characteristics of newborn EEG seizure which include; multiple components or harmonics, piecewise linear instantaneous frequency laws and harmonic amplitude modulation. Estimates of the parameters of both models are shown to be random and are modelled using the data from a total of 500 background epochs and 204 seizure epochs. The newborn EEG background and seizure models are validated against real newborn EEG data using the correlation coefficient. The results show that the output of the proposed models have a higher correlation with real newborn EEG than currently accepted models (a 10% and 38% improvement for background and seizure models, respectively).

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IF estimation for multicomponent signals using image processing techniques in the time–frequency domain

Rankine

2007

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A time-frequency approach for newborn seizure detection

Boashah

Mesbah²

2001

IEEE Eng. Med. Biol. Mag.

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Time-Frequency Feature Extraction of Newborn EEG Seizure Using SVD-Based Techniques

Hassanpour

Mesbah

Boashash

2004

EURASIP J. Adv. Signal Process.

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The nonstationary and multicomponent nature of newborn EEG seizures tends to increase the complexity of the seizure detection problem. In dealing with this type of problems, time-frequency-based techniques were shown to outperform classical techniques. This paper presents a new time-frequency-based EEG seizure detection technique. The technique uses an estimate of the distribution function of the singular vectors associated with the time-frequency distribution of an EEG epoch to characterise the patterns embedded in the signal. The estimated distribution functions related to seizure and nonseizure epochs were used to train a neural network to discriminate between seizure and nonseizure patterns.

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Range Entropy: A Bridge between Signal Complexity and Self-Similarity

Omidvarnia

Mesbah

Pedersen

et al. 2018

Entropy

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Approximate entropy (ApEn) and sample entropy (SampEn) are widely used for temporal complexity analysis of real-world phenomena. However, their relationship with the Hurst exponent as a measure of self-similarity is not widely studied. Additionally, ApEn and SampEn are susceptible to signal amplitude changes. A common practice for addressing this issue is to correct their input signal amplitude by its standard deviation. In this study, we first show, using simulations, that ApEn and SampEn are related to the Hurst exponent in their tolerance r and embedding dimension m parameters. We then propose a modification to ApEn and SampEn called range entropy or RangeEn. We show that RangeEn is more robust to nonstationary signal changes, and it has a more linear relationship with the Hurst exponent, compared to ApEn and SampEn. RangeEn is bounded in the tolerance r-plane between 0 (maximum entropy) and 1 (minimum entropy) and it has no need for signal amplitude correction. Finally, we demonstrate the clinical usefulness of signal entropy measures for characterisation of epileptic EEG data as a real-world example.

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Time‚ÄìFrequency Methodology for Newborn Electroencephalographic Seizure Detection

Boashash¹,

Mesbah²

2002

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Neonatal EEG at scalp is focal and implies high skull conductivity in realistic neonatal head models

et al. 2014

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Signal Enhancement by Time-Frequency Peak Filtering

Boashash

Mesbah

2004

IEEE Trans. Signal Process.

111

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Mostefa Mesbah

A Nonstationary Model of Newborn EEG

IF estimation for multicomponent signals using image processing techniques in the time–frequency domain

A time-frequency approach for newborn seizure detection

Time-Frequency Feature Extraction of Newborn EEG Seizure Using SVD-Based Techniques

Range Entropy: A Bridge between Signal Complexity and Self-Similarity

Time‚ÄìFrequency Methodology for Newborn Electroencephalographic Seizure Detection

Neonatal EEG at scalp is focal and implies high skull conductivity in realistic neonatal head models

Signal Enhancement by Time-Frequency Peak Filtering

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