Spectral analysis of heart period variance (HPV) – a tool to stratify risk following myocardial infarction

References

• Magid N. M., Eckberg D. L., Sprenkle J. M. Low doses atropine reduces ventricular vulnerability in normal and ischemic hearts. Clinical Research 1983; 31(2)461A
   Google Scholar
• Hyndman B. W., Kitney R. I., McSayers B. A. Spontaneous rhythms in physiological control systems. Nature 1971; 233: 339–341
   PubMed Web of Science ®Google Scholar
• Luczak H., Laurig W. Analysis of heart rate variability. Ergonomics 1973; 16: 85–97
   PubMed Web of Science ®Google Scholar
• Mulder G., Mulder-Hajonides van der Meulen W. R. E. H. Mental load and die measurement of heart rate variability. Ergonomics 1973; 16: 69–83
   PubMed Web of Science ®Google Scholar
• McSayers B. A. The analysis of cardiac interbeat interval sequences and the effect of mental work load. Proceedings of the Royal Society for Medicine 1971; 64: 707–710
   PubMedGoogle Scholar
• McSayers B. A. Analysis of heart rate variability. Ergonomics 1973; 16: 17–32
   PubMedGoogle Scholar
• Womack B. F. The analysis of respiratory sinus arhythmia using spectral analysis and digital filtering. IEEE. Transactions or Biomedical Engineering 1971; 18: 399–409
   PubMedGoogle Scholar
• Akselrod S., Gordon D., Ubel F. D., Shannon D. C., Cohen R. J. Power spectrum analysis of heart rate fluctuations: a quantitative probe of beat-to-beat cardiovascular control. Science 1981; 213: 220–222
   PubMed Web of Science ®Google Scholar
• Akselrod S., Gordon D., Madwed J. B., Snidman N. C., Shannon D. C., Cohen R. J. Hemodynamic regulation: investigation by spectral analysis. American foumal of Physiology 1985; 249: H867–H875
   PubMed Web of Science ®Google Scholar
• Pagani M., Lombardi F., Guzzetti S., Rimoldi O., Furlan R., Pizzinelli P., Sandrone G., Malfatto G., Dellorto S., Piccaluga E., Turiel M., Baselli G., Cerutti S., Malliani A. Power spectral analysis of heart rate and arterial pressure variabilities as a marker of sympathovagal intersection in man and conscious dog. Circulation Research 1986; 59: 178–193
   PubMed Web of Science ®Google Scholar
• Weise F., Heydenreich R., Runge U. Contributions of sympathetic and vagal mechanisms to die genesis of heart rate fluctuations during orthostatic load: a spectral analysis. Journal of Autonomic Nervous System 1987; 21: 127–134
   PubMedGoogle Scholar
• Ludwig C. Beitrage zur Kenntnis des Einflusses der Respirationsbewegungen auf den Blutumlauf im Aorten-system. Archivest of Anatomy and Physiology 1847; 242–302
   Google Scholar
• Porges S. W., Bohrer R. E., Keren G., Cheung M. N., Franks G. J., Drasgow F. The influence of mediylphenidate on spontaneous autonomic activity and behaviour in children diagnosed as hyperactive. Psychophy-siology 1981; 18: 42–48
   PubMedGoogle Scholar
• Pomeranz B., Macaulay R. J. B., Caudill M. A., Kutz I., Adam D., Gordon D., Kilborn K. M., Barger A. C., Shannon D. C., Cohen R. J., Benson H. Assessment of autonomic functions in humans by heart rate spectral analysis. American foumal of Physiology 1985; 248, (Heart and Circulation Physiology, 17, H151-H153.
   Google Scholar
• Saul J. P., Rea R. F., Eckberg D. L., Berger R. D., Cohen R. J. Heart rate and muscle sympathetic nerve variability during reflex changes of autonomic activity. American fournal of Physiology 1990; 258: H713–H721, (Heart Circulation Physiology, 27)
   PubMed Web of Science ®Google Scholar
• Burton A. C. The range and variability of the blood flow in the human fingers and the vasomotor regulation of body temperature. American foumal of Physiology 1939; 127: 437–453
   Google Scholar
• Kitney R. I. Entrainment of the human RR interval by thermal stimuli. foumal of Physiology (London) 1975; 252: 37–38
   Google Scholar
• Magid N. M., Martin G. J., Kehoe T. A., Zheutlin D. L., Eckberg G. A., Myers P. S., Barnett E. A., Murray S. K., Gonzales G. S., Weiss J. S., Lesch M., Singer D. H. Diminished heart rate variability in sudden cardiac death. Circulation 1985; 72
   Google Scholar
• Kleiger R. E., Miller J. P., Bigger J. T., Moss A. J., and the Multicenter Post-infarction Research Group. Decreased heart rate variability and its association with increased mortality after acute myocardial infarction. American Journal of Cardiology 1987; 59: 256–262
   PubMed Web of Science ®Google Scholar
• Singer D. H., Martin G. J., Magid N., Weiss S., Schaad J. W., Kehoe R., Zheutlin T., Fintel D. J., Hsieh Ann-Ming, Lesch M. Low heart rate variability and sudden cardiac death. fournal of Electrocardiobgy 1988; S46–S55, Suppl. Issue
   Google Scholar
• Lacuna P., Caminal P., Thakor N. V., Jane R. Automatic QT interval analysis in postmyocardial infarction patients. Journal of Ambulatory Monitoring 1991; 4(2)93–111
   Google Scholar
• Myers G. A., Martin G. J., Magid N. M., Barnett P. S., Schaad J. W., Weiss J. S., Lesch M., Singer D. Power spectral analysis of heart rate variability in sudden cardiac death: comparison to other methods. IEEE Transactions on Biomedical Engineering 1986; BME-33(12)1149–1156
   Google Scholar
• Lombardi F., Sandrone G., Pernpruner S., Sala R., Garimoldi M., Cerutti S., Baselli G., Pagani M., Malliani A. Heart rate variability as an index of sympathovagal interaction after acute myocardial infarction. The American Journal of Cardiology 1987; 60: 1239–1245
   PubMed Web of Science ®Google Scholar
• Lacuna P., Thaxor N., Caminal P., Jane R. Low-pass differentiators for biological signals with known spectra: application to ECG signal processing. IEEE Transactions on Biomedical Engineering 1990; BMJE37: 420–424
   Google Scholar
• Pan J., Tompkins W. J. A real-time QRS detection algorithm. IEEE Transaction on Biomedical Engineering 1985; BME-32: 230–236
   Web of Science ®Google Scholar
• Lang E., Horvath Gy. Integrated system for ambulatory cardio-respiratory data acquisition and spectral analysis. 1993, (ISAXSENSOMED Ltd, 2131. Gödtörökignácz u9, Hungary). User's manual.
   Google Scholar
• Láng E., Caminal P., Laguna P., Horváth G., Homs E., Jané R. Spectral components of heart rate variability (HRV) as markers to stratify risk following myocardial infarction (MI). Proceedings of the V International Symposium on Biomedical Engineering. September, 26–281994. Santiago de Com-pastela, Spain, 57–58
   Google Scholar
• Láng E., Bánhidi L., Antalovits M., Izsó L., Mitsányi A., Zsuffa A., Magyar Z., Horváth Gy., Slezsák I., Majoros A., Dombi I., Molnár L. A complex psychophysiological method to assess environmental effects (temperature, illumination, sound) on objective and subjective parameters of humans in simulated work setting. ”Healthy Buildings ′94“. Proceedings of the 3rd International Conference, L. Bánhidi, J. Farkas, Z. Magyar, P. Rudnai. Technical University of Budapest, Budapest 1994; Vol. 2: 799–803
   Google Scholar
• Gray A. H., Wong D. Y. The Burg algorithm for LPC speech analysis synthesis. TFFF. Transactions on ASSP. 1980; ASSP-28(6)609–615
   Google Scholar
• Akaike H. Fittingautoregressivemodelsforprediction. Annals of the Institute of Statistics and Mathematics 1969; 21: 243–247
   Web of Science ®Google Scholar
• SPSS Inc. SPSS for Windows User's Guide Series. Release 6.0. 1993, (444 N. Michigan Avenue, Chicago, Illinois 60611, USA: SPSS Inc.)
   Google Scholar
• Calcagnini G., Biancalana G., Giubilei F., Strano S., Cerutti S. (1994) Spectral analysis of heart rate variability signal during sleep stages. Proceedings of IEEE conference: Computers in Cardiology, London, 1993. IEEE Computer Society Press, Los Alamitos, CA, 1252–1253
   Google Scholar
• Vanoli E., Adamson P. B., Ba-Lin, Pinna G. D., Lazzara R., Orr W. C. Heart rate variability during specific sleep stages. Circulation 1995; 91: 1918–1922
   PubMed Web of Science ®Google Scholar
• Bigger J. T., Hoover C. A., Jr, Steinman R. C., Rolnitzky L. M., Fleiss J. L., and The Multicenter Study Of Silent Myocardial Ischemia Investigators. Autonomic nervous system activity during myocardial ischemia in man estimated by power spectral analysis of heart period variability. American fournal of Cardiology 1990; 66: 497–498
   PubMedGoogle Scholar
• Bigger J. T., Fleiss J. L., Jr, Stfinmax R. C, Rolxitzky L. M., Kleiger R. E., Rottmax J. N. Correlation among time and frequency domain measures of heart period variability two weeks after acute myocardial infarction. American Journal of Cardiology 1992; 69: 891–898
   PubMed Web of Science ®Google Scholar
• Láng E., Szilágyi N. Significance and assessment of autonomic indices in cardiovascular reactions. Acta Physiology Hungary 1991; 78(3)241–260
   PubMedGoogle Scholar
• Sall J. P., Arai Y., Berger R. D., Lilly L. S., Colucci W. S., Cohen R. J. Assessment of autonomic regulation in chronic congestive heart failure by heart rate spectral analysis. American Journal of Cardiology 1988; 61: 1292–1299
   PubMedGoogle Scholar
• Massumi R. A., Nitter D. O. Cardiac arrhythmias associated with Cheyne-Stokes respiration: a note on the possible mechanisms. Diseases of the Chest 1968; 54: 21–32
   PubMedGoogle Scholar
• Goldberger A. L., Fixdley E. J., Blackblrn M. R., Mandell J. A. Nonlinear dynamics in heart failure: cardiopulmonary oscillations implications of long-wavelength. American Heart Journal 1984; 107: 612–615
   PubMed Web of Science ®Google Scholar
• Preiss G., Iscoe S., Polosa C. Analysis of a periodic breathing pattern associated with Mayer waves. Amerkan Journal of Physiology 1975; 228: 768–774
   PubMed Web of Science ®Google Scholar
• Krieger J. Les syndromes ďapnees du sommeil de ľadulte. Bulletin of European Physiopathology and Respiration 1986; 22: 147–189
   PubMedGoogle Scholar
• Dean R. T., Wilcox J. Possible atherogenic effects of hypoxia during obstructive sleep apnea: Sleep and breathing. Sleep 1992; 16: SI–S155, Proceedings of the Third International Conference on Sleep and Breathing, Palm Cove, Australia
   Google Scholar
• Tilkian A., Glilleminault C, Schroeder J., Lehrman K., Simmons B., Dement W. Hemodynamics in sleep-induced apnea. Annals of Internal Medicine 1976; 85: 714–719
   PubMed Web of Science ®Google Scholar
• Karfmaker J., van den Aardweg J. Low frequency oscillations in the cardiovascular system due to respiration: blood pressure variability in sleep apnoea syndrome. Blood pressure and Heart Rate Variability, M. Di Rienzo, et al, 1992, (IOS Press)
   Google Scholar
• Penzel T. Spectral analysis of blood pressure in patients with sleep-related breathing disorders during NREM and REM sleep. Sleep 1993; 16: S150–S151
   Google Scholar
• Heuner J., Ejnell H., Sellgren J., Hedner T., Wallin G. Is high and fluctuating muscle nerve sympathetic activity in the sleep apnoea syndrome of pathogenetic importance for the development of hypertension?. Journal of Hypertension 1988; 6(Suppl 4)S529–S531
   Google Scholar
• Hung J., Whitford E. G., Parsons R. W., Hillmax D. R. Association of sleep apnoea with myocardial infarction in men. Lancet 1990; 335: 261–264
   PubMedGoogle Scholar
• Koskkxvuo M., Kaprio J., Telakivi K., Partinen M., Hkikkila K., Sarna S. Snoring as a risk factor for ischemic heart disease and stroke in men. British Medical Journal 1987; 29: 416–419
   Google Scholar
• Partinen M., Jamieson A., Guilleminauut C. Long term outcome for obstructive sleep apnea patients. Chest 1989; 94: 1200–1204
   Google Scholar