Multivariate Matching Pursuit Decomposition and Normalized Gabor Entropy for Quantification of Preictal Trends in Epilepsy

Authors

Rui Liu, Mathematics and Statistics Department, Louisiana Tech University, Ruston, LA 71272, USA.
Bharat Karumuri, Biomedical Engineering Department, Louisiana Tech University, Ruston, LA 71272, USA.
Joshua Adkinson, Mathematics and Statistics Department, Louisiana Tech University, Ruston, LA 71272, USA.
Timothy Noah Hutson, Biomedical Engineering Department, Louisiana Tech University, Ruston, LA 71272, USA.
Ioannis Vlachos, Mathematics and Statistics Department, Louisiana Tech University, Ruston, LA 71272, USA.
Leon Iasemidis, Biomedical Engineering Department, Louisiana Tech University, Ruston, LA 71272, USA.

Document Type

Article

Abstract

Quantification of the complexity of signals recorded concurrently from multivariate systems, such as the brain, plays an important role in the study and characterization of their state and state transitions. Multivariate analysis of the electroencephalographic signals (EEG) over time is conceptually most promising in unveiling the global dynamics of dynamical brain disorders such as epilepsy. We employed a novel methodology to study the global complexity of the epileptic brain en route to seizures. The developed measures of complexity were based on Multivariate Matching Pursuit (MMP) decomposition of signals in terms of time-frequency Gabor functions (atoms) and Shannon entropy. The measures were first validated on simulation data (Lorenz system) and then applied to EEGs from preictal (before seizure onsets) periods, recorded by intracranial electrodes from eight patients with temporal lobe epilepsy and a total of 42 seizures, in search of global trends of complexity before seizures onset. Out of five Gabor measures of complexity we tested, we found that our newly defined measure, the normalized Gabor entropy (NGE), was able to detect statistically significant ( 0.05) nonlinear trends of the mean global complexity across all patients over 1 h periods prior to seizures' onset. These trends pointed to a slow decrease of the epileptic brain's global complexity over time accompanied by an increase of the variance of complexity closer to seizure onsets. These results show that the global complexity of the epileptic brain decreases at least 1 h prior to seizures and imply that the employed methodology and measures could be useful in identifying different brain states, monitoring of seizure susceptibility over time, and potentially in seizure prediction.

Keywords

Gabor entropy, Lorenz system, Multivariate Matching Pursuit, complexity, epilepsy

Publication Date

5-31-2018

Publication Title

Entropy (Basel, Switzerland)

E-ISSN

1099-4300

Volume

20

Issue

6

PubMed ID

33265509

Digital Object Identifier (DOI)

10.3390/e20060419

Recommended Citation

Liu, Rui; Karumuri, Bharat; Adkinson, Joshua; Hutson, Timothy Noah; Vlachos, Ioannis; and Iasemidis, Leon, "Multivariate Matching Pursuit Decomposition and Normalized Gabor Entropy for Quantification of Preictal Trends in Epilepsy" (2018). Translational Neuroscience. 1158.
https://scholar.barrowneuro.org/neurobiology/1158