Heart rate variability analysis: physiological foundations and main methods

Автор: Baevsky Roman М., Chernikova Anna G.

Рубрика: Review

Статья в выпуске: 10, 2017 года.

Бесплатный доступ

The article presents the main provisions of the methodology for the analysis of heart rate variability (HRV), which is now actively and widely implemented in many fields of medicine and applied physiology. This methodology was first developed in space medicine, where, already during the first manned spaceflights, there was a need in operative assessment of the person's reactions and abilities to maintain high performance and good level of health under different stress conditions. The HRV analysis methodology is based on the measurement of a consecutive series of cardiac cycle durations, for which electrocardiography, rheocardiography, ballistic cardiography, etc., can be used. The resulting numerical series are subjected to mathematical analysis using statistical, spectral and other methods. The results are interpreted as medical and physiological criteria of the functional state of the organism. Based on the mathematical model, a probabilistic approach to the prediction of pathological conditions was proposed...

Еще

Heart rate variability, space medicine, stress, discriminant analysis

Короткий адрес: https://sciup.org/148308822

IDR: 148308822 | DOI: 10.12710/cardiometry.2017.6676

Список литературы Heart rate variability analysis: physiological foundations and main methods

Kulaichev AP. Computerized electrophysiology and functional diagnostics: Teaching aid. 4th ed. revised and suppl. Moscow: FORUM INFRA. 2007. 640 p.
Parin VV, Baevsky RM, Gazenko OG. Heart and circulation under space conditions. Cor et vasa. 1965;32:165-84
Parin VV, Baevskii RM, Gazenko OG. Achievements and problems of modern space cardiology. Kardiologiya. May 1965;22:3-11.
Baevskii RM, Zamotaev IP, Nidekker IG. Kardiologiya Mathematical analysis of sinus automatism for prognosis of rhythm disorders. 1971;11(4):65-8.
Sayers BM. The Computer and the Clinical Signal. Journal of the Royal Soc. of Medicine. May 1973; 66(5):473-7.
Akselrod S, Arbel J, Oz O, Benary V, David D. Spectral analysis of HR fluctuations in the evaluation of autonomous control during acute myocardial infarction. Computers in Cardiology. 1985; Pages 315-318.
Berger RD, Akselrod S, Gordon D, Cohen RJ. An Efficient Algorithm for Spectral Analysis of Heart Rate Variability. IEEE Transactions on Biomedical Engineering. September 1986;33(9):900-4
Adam DR, Smith JM, Akselrod S. Fluctuations in T-wave morphology and susceptibility to ventricular fibrillation. 1984;17(3):209-18.
Hon EH, Lee ST. Averaging techniques in fetal electrocardiography. Medical Electronics & Biological Engineering. March 1964;2(1):71-6.
Hon EH. Noise reduction in fetal electrocardiography. Medical arts and sciences. 1964;18:63-6.
Hon EH. Fetal electrocardiography. Anesthesiology. July 1965;26:477-86.
Kubli FW, Hon EH, Khazin AF. Observations on heart rate and pH in the human fetus during labor. American Journal of Obstetrics and Gynecology. 15 August 1969;104(8):1190-206.
Yeh SY, Betyar L, Hon EH. Computer diagnosis of fetal heart rate patterns. American Journal of Obstetrics and Gynecology. 1 December 1972;114(7):890-7.
Baevsky RM, Ivanov GG, Chireikin IV. Heart rate variability analysis in using various electrocardiography systems. Journal of arrhythmology. 2001;24:15.
Huikuri HV, Makikallio T, Airaksinusn KEJ, et al. Measurement of heart rate variability: a clinical tool or a research toy? J Am Coll Cardiol 1999;34:1878.
Jose AD, Taylor RR. Autonomic blockade by propranolol and atropine to study intrinsic myocardial function in man. J Clin Invest 1969; 48:2019.
Hirsch JA, Bishop B. Respiratory sinus arrhythmia in humans: How breathing pattern modulates heart rate. Am J Physiol 1981; 241:H620.
Eckberg DL. Human sinus arrhythmia as an index of vagal cardiac outflow. J Appl Physiol 1983;54:961.
Baevsky RM, Ivanov GG. Heart rate variability: theoretical aspects and clinical application. Ultrasound and Functional Diagnostics. 2015;2:108.
Korkushko OV, Shatilo VB, Shatilo TV, Korotkaia EV. An analysis of the autonomic regulation of cardiac rhythm at different stages in individual human development. Fiziologiia cheloveka. March 1991;17(2):31-9.
Korkushko OV, Shatilo VB, Plachinda YI. Autonomic control of cardiac chronotropic function in man as a function of age: assessment by power spectral analysis of heart rate variability. Journal of the Autonomic Nervous System. March 1991;32(3):191-8.
Khaspekova NB, Solov'eva AD, Nedostup AV, San'kova TA. Spectral analysis of heart rate variability in diagnosis of vegetative autonomic dysfunction in patients with attacks of atrial fibrillation Kardiologiia. 2004;44(11):61-5.
Shlyk NI. Management of athletic training taking into account individual heart rate variability characteristics. 1 November 2016;42(6):655-64.
Shlyk NI, Sapozhnikova EN, Kirillova TG, Semenov VG. Typoloagical characteristics of the functional state of regulatory systems in schoolchildren and young athletes (According to Heart Rate Variability Data). Human Physiology. November 2009;35(6):730-8.
Malliani A. Heart rate variability: From bench to bedside. European Journal of Internal Medicine. February 2005;16(1):12-20.
Malliani A, Montano N. Heart rate variability as a clinical tool. Italian Heart Journal. 1 August 2002;3(8):439-45.
Malliani A, Montana N, Pagani M. Physiological Background of Heart Rate Variability. Cardiac Electrophysiology Review. 1997;1(3):343-6.
Kuwahara M, Hashimoto SI, Tsubone H, Supano S. Power spectral analysis of heart rate variability in spontaneously hypertensive rats. Japanese Heart Journal. 1994;35(1):367-8.
Bucchi A, Barbuti A, Baruscotti M, DiFrancesco D. Heart rate reduction via selective 'funny' channel blockers. Current Opinion in Pharmacology. April 2007;7(2):208-13.
Elghozi JL, Julien C. Sympathetic control of short-term heart rate variability and its pharmacological modulation. Fundamental and Clinical Pharmacology. August 2007;21(4):337-47.
Fei L, Copie X, Malik M, Camm AJ. Heart rate variability: How useful for measuring postinfarction mortality risk? Cardiology Review. 1996;13(11):35-40.
Hartikainen JEK, Malik M, Staunton A. Predictive Power of Heart Rate Variability Used as a Stratifier of Cardiac Mortality after Myocardial Infarction in Patients Discharged with and Without Beta-Blocker Therapy. Annals of Noninvasive Electrocardiology. 1996;1(1):12-8.
Faber TS, Staunton A, Hnatkova K. Stepwise strategy of using short-and long-term heart rate variability for risk stratification after myocardial infarction. PACE -Pacing and Clinical Electrophysiology. 1996;19(11):1845-51.
Reardon M, Malik M. Changes in heart rate variability with age. PACE -Pacing and Clinical Electrophysiology. 1996;19(11):1863-6.
Medvedev MA, Zagulova DV, Nesterenko individual features in interpreting the indices of spectral components of the cardiac rhythm. Fiziologiia cheloveka. May-Jun 2002;28(3):54-60.
Curione M, Cugini P, Napoli A. A lower level of entropy in circadian rhythm of the sinus R-R intervals suggests a prevalence of the cardiac sympathetic regulation in early physiological pregnancy. Chronobiology International. 2005;22(4):711-22.
Murphy CA, Sloan RP, Myers MM. Pharmacologic responses and spectral analyses of spontaneous fluctuations in heart rate and blood pressure in SHR rats. Journal of the Autonomic Nervous System. December 1991;36(3):237-50.
Alipov NN, Sergeeva OV, Kuznetsova TE. Role of sympathetic and parasympathetic nervous systems in heart rate regulation in cats. Bulletin of Experimental Biology and Medicine. November 2005; 140(5):477-82.
Sal'nikov EV, Fateev MM, Sidorov AV. Effect of β-adrenoblockers on heart rate variability in awake and narcotized rats. Bulletin of Experimental Biology and Medicine. October 2007;144(4):494-7.
Sergeeva OV, Alipov NN, Smirnov VM. Effect of atropine, propranolol, and atenolol on wave structure of heart rate oscillations in rats. Bulletin of Experimental Biology and Medicine. April 2008;145(4):387-90.
Adamovich BA, Baevsky RM, Berseneva AP, Funtova II. State-of-the-art automatic evaluation of the health status in space medicine and preventive medicine. Kosmicheskaya Biologiya i Aviakosmicheskaya Meditsina. 1990;24(4):11-8.
Baranov VM, Demin YP, Kotov AN, et al. Comparative evaluation of several methods preventing orthostatic disorders during simulation of the end-of space-mission factors. Aviakosmicheskaya i Ekologicheskaya Meditsina. 2003;37(4):17-23.
Fauchier L, Babuty D, Autret ML, et al. Effect of verapamil on heart rate variability in subjects with normal hearts. American Journal of Cardiology. 1 November 1997;80(9):1234-5.
Fauchier L, Babuty D, Cosnay P. Heart rate variability in idiopathic dilated cardiomyopathy: Characteristics and prognostic value. Journal of the American College of Cardiology. October 1997;30(4):1009-14.
Pinna GD, Maestri R, La Rovere MT. Factors affecting the reliability of transfer function estimates of cardiovascular variability signals. Computers in Cardiology. 1999; Pages 639-642.
Maestri R, Pinna GD, Mortara A, et al. Assessing baroreflex sensitivity in post-myocardial infarction patients: Comparison of spectral and phenylephrine techniques. Journal of the American College of Cardiology. February 1998;31(2):344-51.
Khayutin VM, Bekbosynova MS, Lukoshkova EV. Spectral Analysis of Heart Rate Variability in Patients with Paroxysmal Supraventricular Tachycardia. Kardiologiya. 2001; 41(5):38-45.
Khayutin VM, Bekbosynova MS, Lukoshkova EV, Golitsin SP. Changes of the power of heart rate variability induced by propranolol in patients with cardiac arrhythmias. Kardiologiya. 1997;37(7):4-14.
Berntson GG, Cacioppo JT. Heart Rate Variability: A Neuroscientific Perspective for Further Studies. Cardiac Electrophysiology Review. 1999;3(4):279-82.
Bigger JT, Steinman RC, Rolnitzky LM, et al. Power law behavior of RR-interval variability in healthy middle-aged persons, patients with recent acute myocardial infarction, and patients with heart transplants. Circulation. 15 June 1996; 93(12):2142-51.
Malik M, Camm AJ, Bigger JT, et al. Heart rate variability. Standards of measurement, physiological interpretation, and clinical use. European Heart Journal. 1996;17(3):354-81.
Fallen EL. Clinical Utility of Heart Rate Variability. Cardiac Electrophysiology Review. 1997;1(3):347-51.
Akselrod S, Gordon D, Ubel FA. Power spectrum analysis of heart rate fluctuation: A quantitative probe of beat-to-beat cardiovascular control. Science. Journal of Electrocardiology. 1981;213(4504):220-2.
Baevsky RM. Noninvasive methods in space cardiology. Journal of Cardiovascular Diagnosis and Procedures. 1997;14(3):161-71.
Baevsky RM, Petrov VM, Chernikova AG. Regulation of autonomic nervous system in space and magnetic storms. Advances in Space Research. 1998;22(2):227-34.
Shakhtarin VV, Kiryachkov YY, Palyga GF, et al. Effect of normobaric hypoxia on function of some factors of the endocrine system. 1990;35(1):26-8.
Goldberger AL. Fractal Mechanisms in the Electrophysiology of the Heart. IEEE Engineering in Medicine and Biology Magazine. June 1992;11(2):47-52.
Ryan SM, Goldberger AL, Ruthazer R, et al. Spectral analysis of heart rate dynamics in elderly persons with postprandial hypotension. The American Journal of Cardiology. 15 January 1992;69(3):201-5.
Mashin VA. Factor analysis of the heart rate spectrum. Biophysics. April 2011;56(2):286-97.
Baevsky RM, Chernikova AG, Funtova II, Tank J. Assessment of individual adaptation to microgravity during long term space flight based on stepwise discriminant analysis of heart rate variability parameters. Acta Astronautica. December 2011;69(11-12):1148-52.
Baevskii RM, Chernikova AG. Assessment of adaptation risk in an individual prenosological monitoring system. Neuroscience and Behavioral Physiology. 2016; 46(4):437-45.
Grigoriev AI, Orlov OI. Telemedicine and spaceflight. Aviation Space and Env. Med. 2002;73(7):688-93.
Grigoriev AI, Kalinin YT, Buravkova LB, Mitichkin OV. Space cell physiology and space biotechnology in Russia. Advances in Space Biology and Medicine. 2002;8:215-236.

Еще

Статья обзорная