Authors: V. I. Thajudin Ahamed, P. Dhanasekaran, Paul Joseph K.

Abstract:

Analysis of heart rate variability (HRV) has become a popular non-invasive tool for assessing the activities of autonomic nervous system. Most of the methods were hired from techniques used for time series analysis. Currently used methods are time domain, frequency domain, geometrical and fractal methods. A new technique, which searches for pattern repeatability in a time series, is proposed for quantifying heart rate (HR) time series. These set of indices, which are termed as pattern repeatability measure and pattern repeatability ratio are able to distinguish HR data clearly from noise and electroencephalogram (EEG). The results of analysis using these measures give an insight into the fundamental difference between the composition of HR time series with respect to EEG and noise.

Keywords: Approximate entropy, heart rate variability, noise, pattern repeatability, and sample entropy.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1084766

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 1686

References:

[1] Bhattacharya J., "Complexity analysis of spontaneous EEG," Acta. Neurobiol. Exp,. vol. 60, pp. 495-50, 2000
[2] Faber R., Baumert M., Stepan H., Wessel N., Voss A. and Walther T. "Baroreflex sensitivity, heart rate, and blood pressure variability in hypertensive pregnancy disorders," Journal of Human Hypertension, vol. 18, 707-712, 2004.
[3] Parati G, Frattola A, Omboni S, Mancia G, and Di Rienzo M., "Analysis of heart rate and blood pressure variability in the assessment of autonomic regulation in arterial hypertension," Clin Sci. (Colch), vol. 91 Supl., pp. 129-132, 1996.
[4] S. K. Ramchurn, D. Baijnath, and A. Murray, "Low-dimentional chaotic behaviour in heart rate variability," Computers in Cardiology, vol. 27, pp. 473-476, 2000.
[5] R. U. Acharya, A. Kumar, P. S. Bhat, C. M. Lim, S. S. Iyengar, N. Kannathai, and S. M. Krishnan, "Classification of cardiac abnormalities using heart rate signals," Med. Biol. Eng. Comput. , vol. 42, pp. 288- 293, 2004.
[6] G. Krsacic, A. Krsacic, M. Martinis, E. Vargovic, A. Knezevic, A. Smalcelj, M. Jemberk-Gostovic, D. Gamberger, and T. Smuc, "Nonlinear analysis of heart rate variability in patients with coronary heart disease," Computers in Cardiology, vol. 29, pp. 673-675, 2002.
[7] Rajendra Acharya U., Kannathal N. Ong Wai Sing, Luk Yi Ping, and TjiLeng Chua, "Heart rate analysis of normal subjects in various age groups," Biomedical Engineering Online, vol. 3 no. 24, 2004,
[8] Fuan Sztajzel, "Heart rate variability: a noninvasive electrocardiographic method to measure the autonomic nervous system," Swiss Med. Wkly., vol. 134, pp. 514 - 522, 2004.
[9] D. Cysarz, P. Van Leeuwen and H. Bettermann, "Irregularities and nonlinearities in fetal heart period time series in the course of pregnancy," Herzschr Elektrophys, vol. 11, pp. 127-130, 2000.
[10] R. U. Acharya, C. Lim, and P. Joseph, "Heart rate variability analysis using correlation dimension and detrended fluctuation analysis," ITBMRBM, vol. 23, 333-339, 2002.
[11] Paul Joseph, U Rajendra Acharya, Chua Kok Poo. Johny Chee, Lim Choo Min, S S Iyengar, and Hock Wei, "Effect of reflexological stimulation on heart rate variability," ITBM-RBM, vol. 25, 40-45, 2004.
[12] Burioka N et al. Approximate Entropy in the Electroencephalogram During Wake and Sleep. Clinical EEG and Neuroscience 2005; 36: 1.
[13] Jordi Almitras, "Understanding of autonomic sympathovagal balance from short-term heart rate variations. Are we analyzing noise," Comparative Biochemistry and Physiology, Part A 124, 447-460, 1999.
[14] Task force of the European Society of Cardiology and North American Society of Pacing and Electrophysiology, "Heart rate variability, standards of measurement, physiological interpretation, and clinical use," Circ., vol. 93. no. 5, pp. 1043-1065, 1996.
[15] P. Van Leeuwen and H. Bettermann, "The status of nonlinear dynamics in the analysis of heart rate variability, editorial," Herzschr Elektrophys, vol. 11, pp. 127-130, 2000.
[16] Otakar Fojt and Jiri Holcik, "Applying nonlinear dynamics to ECG signal processing," IEEE Engg. Med. Biol. Soc., pp. 96-101, March/April 1998.
[17] S.M. Pincus. Approximate entropy as a measure of system complexity. Proc. Natl. Acad. Sci. USA, vol. 88, no. 6, 2297-2301, March 15,1991
[18] J. S. Richmann and J. R. Moormann "Physiological time-series analysis using approximate entropy and sample entropy," Am. J.. Physiol. Heart Circ. Physiol., vol. 278, H2039 - H2049, 2000.
[19] Douglas E. Lake, Joshua S. Richman, M. Pamela Griffin, and J. Randall Moormann, "Sample entropy analysis of neonatal heart rate variability," Am. J. Physiol. Regu.l Integr. Comp. Physiol,, vol. 283, pp. 789-797, 2002.
[20] M. Costa, A. L. Goldberger, and C. K. Peng, "Multiscale entropy analysis of complex physiological time series," Physical Revew Letters, vol. 89 no. 6, Aug. 2002.
[21] M Costa, C. K. Peng A. L Goldberger. and J. M. Housdorff, "Multiscale entropy analysis of human gait dynamics," Physica A, vol. 330, pp. 53- 60, 2003.
[22] www.physionet.org
[23] V. I. Thajudin Ahamed, P. Dhanasekharan, N. G. Karthick, Pual K. Joseph, A. Naseem, and T. K. Abdul Jaleel, "A novel pattern recognition technique for quantification of heart rate variability," Proceedings of the international conference on biomedical and pharmaceutical engineering, ICBPE, Singapore, 2006, pp. 110 - 113