Abstract
A new statistic has been developed to quantify the amount of regularity in data. This statistic, ApEn (approximate entropy), appears to have potential application throughout medicine, notably in electrocardiogram and related heart rate data analyses and in the analysis of endocrine hormone release pulsatility. The focus of this article is ApEn. We commence with a simple example of what we are trying to discern. We then discuss exact regularity statistics and practical difficulties of using them in data analysis. The mathematic formula development for ApEn concludes the Solution section. We next discuss the two key input requirements, followed by an account of a pilot study successfully applying ApEn to neonatal heart rate analysis. We conclude with the important topic of ApEn as a relative (not absolute) measure, potential applications, and some caveats about appropriate usage of ApEn. Appendix A provides example ApEn and entropy computations to develop intuition about these measures. Appendix B contains a Fortran program for computing ApEn. This article can be read from at least three viewpoints. The practitioner who wishes to use a “black box” to measure regularity should concentrate on the exact formula, choices for the two input variables, potential applications, and caveats about appropriate usage. The physician who wishes to apply ApEn to heart rate analysis should particularly note the pilot study discussion. The more mathematically inclined reader will benefit from discussions of the relative (comparative) property of ApEn and from Appendix A.
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Kluge KA, Harper RM, Schechtman VL, et al. Spectral analysis assessment of respiratory sinus arrhythmia in normal infants and infants who subsequently died of sudden infant death syndrome. Pediatr Res 1988;24:677–682
Goldberger AL, Bhargava V, West BJ, Mandell AJ. On a mechanism of cardiac instability: the fractal hypothesis. Biophys J 1985;48:525–528
Goldberger AL, West BJ. Fractals in physiology and medicine. Yale J Biol Med 1987;60:421–435
Grassberger P, Procaccia I. Estimation of the Kolmogorov entropy from a chaotic signal. Phys Rev A 1983;28:2591–2593
Takens F. Invariants related to dimension and entropy. In: Atas do 13. Rio de Janeiro: Col. Brasiliero de Matematicas, 1983
Santen RJ, Bardin CW, Episodic luteinizing hormone secretion in man. Pulse analysis, clinical interpretation, physiologic mechanisms. J Clin Invest 1973;52:2617–2628
Van Cauter E. Quantitative methods for the analysis of circadian and episodic hormone fluctuations. In: Van Cauter E, Copinschi G, eds. Human pituitary hormones: circadian and episodic variations. The Hague: Martinus Nijhoff, 1981:1–25
Feynman RP. The Feynman lectures on physics, vol. 1. Reading, MA: Addison-Wesley, 1963:44.10–44.13
Billingsley P. Ergodic theory and information. New York: Wiley, 1965:60–94
Eckmann JP, Ruelle D. Ergodic theory of chaos and strange attractors. Rev Mod Phys 1985;57:617–656
Crutchfield JP, Packard NH. Symbolic dynamics of one-dimensional maps: entropies, finite precursor, and noise. Int J Theor Phys 1982;21:433–465
Wolf A, Swift JB, Swinney HL, Vastano JA. Determining Lyapunov exponents from a time-series. Physica 1985;16D:285–317
Greenside HS, Wolf A, Swift J, Pignataro T. The impracticality of a box-counting algorithm for calculating the dimensionality of strange attractors. Phys Rev A 1982;25:3453–3456
Fraser AM. Information and entropy in strange attractors. IEEE Trans IT 1989;35(2):245–262
Ruelle D. An inequality for the entropy of differentiable maps. Bol Soc Bras Mat 1978;9:83
Lambalk CB, de Koning J, van Kessel H, et al. Calculation of the intra-assay variation per assay and its relevance to luteinizing hormone pulse detection. In: Crowley WF, Hofler JG, eds. The episodic secretion of hormones. New York: Wiley, 1987:67–73
Aarimaa T, Oja R, Antila K, Valimaki I. Interaction of heart rate and respiration in newborn babics. Pediatr Res 1988;24:745–750
Merriam GR. Methods of characterizing episodic hormone secretion. In: Crowley WF, Hofler JG, eds. The episodic secretion of hormones. New York: Wiley, 1987:47–65
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I. M. G. is an active-duty Naval officer. The opinions expressed herein are those of the authors and are not to be construed as reflecting the views of the Navy Department, the Naval Service at large, or the Department of Defense.
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Pincus, S.M., Gladstone, I.M. & Ehrenkranz, R.A. A regularity statistic for medical data analysis. J Clin Monitor Comput 7, 335–345 (1991). https://doi.org/10.1007/BF01619355
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DOI: https://doi.org/10.1007/BF01619355