A unified approach for detection of induced epileptic seizures in rats using ECoG signals

Niknazar, Mohammad; Mousavi, Seyed Reza; Motaghi, Sahel; Dehghani, Aghdas; Vahdat, Bijan Vosoughi; Shamsollahi, Mohammad Bagher; Sayyah, Mohammad; Noorbakhsh, S. Mohammad

doi:10.1016/j.yebeh.2013.01.028

Cited by 25 publications

(23 citation statements)

References 44 publications

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“…In the literature, there are a wide range of available feature extraction methods which range from the traditional methods to the non-linear methods. Traditional methods include the fourier transform and also spectral analysis whilst the non-linear methods include Lyapunov exponents [28], [40], correlation dimension [28] and similarity [41]. After feature extraction has been implemented to the raw data, the extracted features are then used and applied to the pre-determined classification technique.…”

Section: Absence Epilepsymentioning

confidence: 99%

Classification of epilepsy seizure phase using interval type-2 fuzzy support vector machines

et al. 2016

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Section: Absence Epilepsymentioning

confidence: 99%

Classification of epilepsy seizure phase using interval type-2 fuzzy support vector machines

et al. 2016

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“…A series of studies have focused on Nonlinear Dynamical Analysis (NDA) of EEG signals to extract features for detection of epilepsy (Srinivasan, Eswaran, & Sriraam, 2007; Chen et al, 2011; Niknazar et al, 2013; Yaylali, Koçak, & Jayakar, 1996; Cerf, Amri, Ouasdad, & Hirsch, 1999; Adeli, Ghosh-Dastidar, & Dadmehr, 2007; Ghosh-Dastidar, Adeli, & Dadmehr, 2007; Iasemidis et al, 2003; Van Drongelen et al, 2003; Easwaramoorthy & Uthayakumar, 2011; Zhou, Liu, Yuan, & Li, 2013; Zabihi et al, 2016; Thomasson, Hoeppner, Webber, & Zbilut, 2001; Li, Ouyang, Yao, & Guan, 2004; Ouyang, Li, Dang, & Richards, 2008; Niknazar, Mousavi, Vahdat, & Sayyah 2013). These features include Approximate Entropy (ApEn) (Srinivasan et al, 2007; Chen et al, 2011; Niknazar et al, 2013), correlation dimension (Yaylali et al, 1996; Cerf et al, 1999; Adeli et al, 2007; Ghosh-Dastidar et al, 2007), Lyapunov exponent (Niknazar et al, 2013; Adeli et al, 2007; Ghosh-Dastidar et al, 2007; Iasemidis et al, 2003), Kolmogorov entropy (Van Drongelen et al, 2003), fractal dimension (Niknazar et al, 2013; Easwaramoorthy & Uthayakumar, 2011), lacunarity (Zhou et al, 2013), and features extracted from Poincaré section (Zabihi et al, 2016) as well as Recurrence Quantification Analysis (RQA) (Niknazar et al, 2013; Thomasson et al, 2001; Li et al, 2004; Ouyang et al, 2008; Niknazar et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

“…These features include Approximate Entropy (ApEn) (Srinivasan et al, 2007; Chen et al, 2011; Niknazar et al, 2013), correlation dimension (Yaylali et al, 1996; Cerf et al, 1999; Adeli et al, 2007; Ghosh-Dastidar et al, 2007), Lyapunov exponent (Niknazar et al, 2013; Adeli et al, 2007; Ghosh-Dastidar et al, 2007; Iasemidis et al, 2003), Kolmogorov entropy (Van Drongelen et al, 2003), fractal dimension (Niknazar et al, 2013; Easwaramoorthy & Uthayakumar, 2011), lacunarity (Zhou et al, 2013), and features extracted from Poincaré section (Zabihi et al, 2016) as well as Recurrence Quantification Analysis (RQA) (Niknazar et al, 2013; Thomasson et al, 2001; Li et al, 2004; Ouyang et al, 2008; Niknazar et al, 2013). …”

Section: Introductionmentioning

confidence: 99%

Automatic Seizure Detection Based on Nonlinear Dynamical Analysis of EEG Signals and Mutual Information

Akbarian

Erfanian

2018

BCN

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Introduction:In this paper, nonlinear dynamical analysis based on Recurrence Quantification Analysis (RQA) is employed to characterize the nonlinear EEG dynamics. RQA can provide useful quantitative information on the regular, chaotic, or stochastic property of the underlying dynamics.Methods:We use the RQA-based measures as the quantitative features of the nonlinear EEG dynamics. Mutual Information (MI) was used to find the most relevant feature subset out of RQA-based features. The selected features were fed into an artificial neural network for grouping of EEG recordings to detect ictal, interictal, and healthy states. The performance of the proposed procedure was evaluated using a database for different classification cases.Results:The combination of five selected features based on MI achieved 100% accuracy, which demonstrates the superiority of the proposed method.Conclusion:The results showed that the nonlinear dynamical analysis based on Rcurrence Quantification Analysis (RQA) can be employed as a suitable approach for characterizing the nonlinear EEG dynamics and detecting the seizure.

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“…The EEG has since become one of most useful tools for studying the cognitive processes and the physiology/pathology of the brain [8,9], especially the processes involved in epileptic seizures [10,11]. Currently, these methods mainly include traditional linear methods such as Fourier transforms and spectral analysis [12] and nonlinear methods such as Lyapunov exponents [13], correlation dimension [14] and similarity [15,16]. In particular, a series of entropy-based approaches has been widely used since they can quantify the complexity (regularity) of an EEG signal [17][18][19].…”

Section: Introductionmentioning

confidence: 99%

Using Permutation Entropy to Measure the Changes in EEG Signals During Absence Seizures

Yan

Liu

et al. 2014

Entropy

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Abstract:In this paper, we propose to use permutation entropy to explore whether the changes in electroencephalogram (EEG) data can effectively distinguish different phases in human absence epilepsy, i.e., the seizure-free, the pre-seizure and seizure phases. Permutation entropy is applied to analyze the EEG data from these three phases, each containing 100 19-channel EEG epochs of 2 s duration. The experimental results show the mean value of PE gradually decreases from the seizure-free to the seizure phase and provides evidence that these three different seizure phases in absence epilepsy can be effectively distinguished. Furthermore, our results strengthen the view that most frontal electrodes carry useful information and patterns that can help discriminate among different absence seizure phases.

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A unified approach for detection of induced epileptic seizures in rats using ECoG signals

Cited by 25 publications

References 44 publications

Classification of epilepsy seizure phase using interval type-2 fuzzy support vector machines

Classification of epilepsy seizure phase using interval type-2 fuzzy support vector machines

Automatic Seizure Detection Based on Nonlinear Dynamical Analysis of EEG Signals and Mutual Information

Using Permutation Entropy to Measure the Changes in EEG Signals During Absence Seizures

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