Authors: Subha D. Puthankattil, Paul K. Joseph

Abstract:

Analyzing brain signals of the patients suffering from the state of depression may lead to interesting observations in the signal parameters that is quite different from a normal control. The present study adopts two different methods: Time frequency domain and nonlinear method for the analysis of EEG signals acquired from depression patients and age and sex matched normal controls. The time frequency domain analysis is realized using wavelet entropy and approximate entropy is employed for the nonlinear method of analysis. The ability of the signal processing technique and the nonlinear method in differentiating the physiological aspects of the brain state are revealed using Wavelet entropy and Approximate entropy.

Keywords: EEG, Depression, Wavelet entropy, Approximate entropy, Relative Wavelet energy, Multiresolution decomposition.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1094265

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References:

[1] Subha D.P., Paul K. Joseph, R. U. Acharya, L. C. Min, " EEG signal Analysis: A Survey," Journal of Medical Systems, Springer, vol. 34, no. 2, pp. 195-212, March 2010.
[2] Wallace B. Mendelson, David A. Sack, Steven P. James, Joseph V. Martin, Richard Wagner, Debra Garnett, John Milton and Thomas A. Wehr, "Frequency Analysis of the Sleep EEG in Depression," Psychiatry Research, vol. 21, pp. 89-94, 1987.
[3] Yang Li, Yingjie Li, Shanbao Tong, Yingying Tang, Yisheng Zhu, "More normal EEGs of depression patients during mental arithmetic than rest," Proceedings of NFSI & ICFBI, October 12-14 , pp. 165-168, 2007.
[4] Debener S., Beauducel A., Nessler D., Brocke B., Heilemann H., Kayser J., "Is resting anterior EEG alpha asymmetry a trait marker for depression? Findings for healthy adults and clinically depressed patients," Neuropsychobiology, vol.41, pp. 31-37, 2000.
[5] Sarbadhikari S.N., Chakrabarty K., "Chaos in the brain: a short review alluding to epilepsy, depression, exercise and lateralization," Med. Eng. Phy., vol. 23, pp. 445-455, 2001.
[6] V. Knott, C. Mahoney, S. Kennedy and K. Evans, "EEG Power, frequency, asymmetry and coherence in male depression," Psychiatry Res., vol. 106, pp. 123-140, 2001.
[7] Rosso O. A., Blanco S., Yordanova J., Kolev V., Figliola A., Schurmann M., Basar E., "Wavelet entropy: a new tool for analysis of short duration brain electrical signals," Journal of Neuroscience methods, vol. 105, pp. 65-75, 2001.
[8] M. D. Salwani, Y. Jasmy, "Relative Wavelet Energy as a tool to select suitable wavelet for artifact removal in EEG," Ist International conference on Computers, Communications and Signal processing with special track on Biomedical Engineering, CCSP 2005, Malaysia, November 14-16, pp. 282-287, 2005.
[9] JaeseungJeong, Moo KwangJoung, Soo Yong Kim, "Quantification of emotion by nonlinear analysis of the chaotic dynamics of electroencephalograms during perception of 1/f music,” Biol. Cybern., vol. 78, pp. 217-225, 1998.
[10] Steve Pincus, "Approximate entropy (ApEn) as a complexity measure," Chaos 5, pp. 110-117, 1995.
[11] Srinivasan V., Eswaran C., Sriram N., "Approximate entropy-based epileptic EEG detection using artificial neural networks," IEEE transactions on information technology in biomedicine, vol. 11, no. 3, pp. 288-295, 2007.
[12] Mallat S, " A theory for multiresolution signal decomposition the wavelet representation”, IEEE Trans. Pattern Anal. Mach.Intell.,vol. 11, no.7, pp. 673-693,1989.
[13] Rosso O. A., Blanco S., Yordanova J., Kolev V., Figliola A., Schurmann M., Basar E., "Wavelet entropy: a new tool for analysis of short duration brain electrical signals," Journal of Neuroscience methods, vol. 105, pp. 65-75, 2001.
[14] O. A. Rosso and A. Figliola, "Order/disorder in Brain Electrical Activity," Revv.Mex.Fis., vol. 50, pp. 149-155, 2004.
[15] Guo L, Rivero D, Seoane JA , Pazos A, Classification of EEG Signals using Relative Wavelet Energy and Artificial Neural Networks, Proc 1st ACM/SIGEVO Summit on Genetic and evolutionary Computation, pp.177-184,2009.
[16] Shannon C. E., "A mathematical theory of communication," Bell Syst Tech-nol J, vol. 27, pp. 379-23, pp. 623-56, July, October, 1948.
[17] Rosso O. A., M. T .Martin, A. Figliola, K. Keller, A. Plastino, "EEG analysis using wavelet based information tools," Journal of Neuroscience methods, vol. 153, pp. 163-182, 2006.
[18] Joshua S. Richman and J. Randall Moorman, "Physiological time series analysis using approximate entropy and sample entropy," Am. J. physiol. Heart CircPhysiol, vol. 278, pp. H2039-H2049, 2000.
[19] S. M. Pincus and Burton H. Singer," Randomness and degrees of irregularity", Proc. Natl. Acad. Sci. USA, vol. 93, pp. 2083-2088, 1996.
[20] S. M. Pincus, "Assessing serial irregularity and its implications for health," Ann. NY Acad. Sci., vol. 954, pp. 245-267, 2001.
[21] S. M. Pincus, A. L. Goldberger, "Physiological time-series analysis: what does regularity quantify? " Am. J. Physiol., vol. 266, pp. H1643-H1656, 1994.