Abstract
The sympatho-vagal nerve interaction at the heart was studied by means of power spectrum analysis of heart rate variability in seven Caucasians (aged 27–35 years) in resting supine and sitting positions before and during 35 days of a sojourn at 5050 m above sea level (asl) and in six Sherpas (aged 22–30 years) at high altitude only. A high frequency peak (HF)-central frequency between 0.20 and 0.33 Hz, a low frequency peak (LF)-central frequency between 0.08 and 0.14 Hz, and a very low frequency component ( < 0.05 Hz), no peak observed, were found in the power spectrum in both positions and independent of altitude. The peak powers, as a percentage of the total power, were affected by both body position and altitude. At sea level the change from a supine to a sitting position yielded a decrease in percentage HF from 25 (SEM 1.9)% to 6.2 (SEM 1.5) % (P < 0.05) and a significant increase in the ratio between LF and HF powers (LF : HF) from 1.7 (SEM 0.4) to 6.9 (SEM 1.6). At altitude compared to sea level in the supine position, percentage HF decreased from 25% to 10.9 (SEM 1.0)% (P < 0.05) and the LF:HF ratio increased from 1.7 to 4.8 (SEM 0.7) (P < 0.05). No changes occurred at altitude in the sitting position either in the peak powers or in the LF:HF ratio, but the central frequency of HF peak increased significantly from 0.25 (SEM 0.02) Hz to 0.32 (SEM 0.01) Hz. In the Sherpas comparable results to the Caucasians were found in both body positions. The high LF:HF ratios observed at altitude in both body positions and groups would suggest that hypoxia caused a shift of sympatho-vagal nerve interaction at rest toward a dominance of the sympathetic system, which was found at sea level only in the sitting position. An acclimatization period of 10 days higher than 2850 m asl and 1 month at 5050 m asl did not modify the interactions of the autonomic systems.
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References
Akaike H (1970) Statistical predictor identification. Am Int Stat Math 22:203–217
Akselrod S, Gordon D, Ubel FA, Shannon DC, Barger AC, Cohen RJ (1981) Power spectrum analysis of heart rate fluctuations: a quantitative probe of beat-to-beat cardiovascular control. Science 213:220–222
Bartoli F, Baselli G, Cerutti S (1985) AR identification and spectral estimate applied to the R-R interval measurements. J Biom Comput 16:201–215
Baselli G, Cerutti S, Civardi S, Liberati D, Lombardi F, Malliani A, Pagani M (1986) Spectral and cross-spectral analysis of heart rate and arterial pressure variability signals. Comput Biomed Res 19:520–534
Bernardi L, Salvucci F, Suardi R, Soldà PL, Calciati A, Perlini S, Falcone C, Ricciardi L (1990) Evidence for an intrinsic mechanism regulating heart rate variability in the transplanted and in the intact heart during submaximal dynamic exercise? Cardiovasc Res 24:969–981
Cunningham WL, Becker EJ, Kreuzer F (1965) Catecholamines in plasma and urine at high altitude. J Appl Physiol 20:607–610
Farinelli CCJ, Kayser B, Binzoni T, Cerretelli P, Girardier L (1994) Autonomic nervous control of heart rate at altitude (5050 m). Eur J Appl Physiol 69:502–507
Hughson RE, Yamamoto Y, McCullough RE, Sutton JR, Reeves JT (1994) Sympathetic and parasympathetic indicators of heart rate control at altitude studied by spectral analysis. J Appl Physiol 77:2537–2542
Kamath MV, Fallen EL (1993) Power spectral analysis of heart rate variability: a noninvasive signature of cardiac autonomic function. Crit Rev Biomed Eng 21:245–311
Kay SM, Marple SL (1981) Spectrum analysis: a modern perspective. Proc IEEE 69:1380–1419
Mazzeo RS, Bender PR, Brooks GA, Butterfield GA, Groves BM, Sutton JR, Wolfe EE, Reeves JT (1991) Arterial catecholamine responses during exercise with acute and chronic high altitude exposure. Am J Physiol 261:E419-E424
Mekjavic IB, Moric C, Goldberg SV, Morrison JB, Walsh ML, Banister EW, Schoene RB (1991) Exercise breathing pattern during chronic altitude exposure. Eur J Appl Physiol 62:61–65
Moore LG, Cymerman A, Huang SY, McCullough RE, McCullough RG, Rock PB, Young AJ, Young PM, Bloedow D, Weil JV, Reeves JT (1987) Propranolol blocks metabolic rate increase but not ventilatory acclimatization to 4300 m. Resp Physiol 70:195–204
Pagani M, Lombardi F, Guzzetti S, Rimoldi O, Furlan R, Pizzinelli P, Sandrone G, Malfatto G, Dell'Orto S, Piccaluga E, Turiel M, Baselli G, Cerutti S, Malliani A (1986) Power spectral analysis of heart rate and arterial pressure variabilities as a marker of sympatho-vagal interaction in man and conscious dog. Circ Res 59:178–193
Patwardhan AR, Evans JM, Bruce EN, Eckberg DL, Knapp CF (1995) Voluntary control of breathing does not alter vagal modulation of heart rate. J Appl Physiol 78:2087–2094
Perini R, Orizio C, Milesi S, Biancardi L, Baselli G, Veicsteinas A (1993) Body position affects the power spectrum of heart rate variability during dynamic exercise. Eur J Appl Physiol 66:207–213
Pilardeau P, Richalet JP, Bouissou P, Vaysse J, Larmignat P, Boom A (1990) Salivar flow and composition in humans exposed to acute altitude hypoxia. Eur J Appl Physiol 59:450–453
Pomeranz B, Macaulay RJB, Caudill MA, Kutz I, Adam D, Gordon D, Kilborn KM, Barger AC, Shannon DC, Cohen RJ, Benson H (1985) Assessment of autonomic function in humans by heart rate spectral analysis. Am J Physiol 248:14151–11153
Reeves JT, Mazzeo RS, Wolfel EE, Young AJ (1992) Increased arterial pressure after acclimatization to 4300 m: possible role of norepinephrine. Int J Sports Med 13:S18-S21
Richalet JP (1990) The heart and adrenergic system in hypoxia. In: Sutton JR, Coates G, Remmers JE (eds) Hypoxia: the adaptations. Decker, Toronto, pp 231–240
Richalet JP, Larmignat P, Rathat C, Keromes A, Baud P, Lhoste F (1988) Decreased cardiac response to isoproterenol infusion in acute and chronic hypoxia. J Appl Physiol 65:1957–1961
Richalet JP, Kacimi R, Antezana AM (1992) The control of cardiac chronotropic function in hypobaric hypoxia. Int J Sports Med 13:522–524
Saito M, Mano T, Iwase S, Koga K, Abe H, Yamazaki Y (1988) Responses in muscle sympathetic activity to acute hypoxia in humans. J Appl Physiol 65:1548–1552
Sayers BMcA (1973) Analysis of heart rate variability. Ergonomics 16:17–32
Saul JP (1990) Beat-to-beat variations of heart rate reflect modulation of cardiac autonomic outflow. News Physiol Sci 5:32–37
Saul JP, Arai Y, Berger RD, Lilly LS, Colucci WS, Cohen RJ (1988) Assessment of autonomic regulation in chronic congestive heart failure by heart rate spectral analysis. Am J Cardiol 61:1292–1299
Ward MP, Milledge JS, West JB (1989) High altitude medicine and physiology. Chapman and Hall Medical, London
West JB, Lahiri S (1984) High altitude and man. American Physiological Society, Bethesda
Wolfe BB, Voelkel NF (1983) Effects of hypoxia on atrial muscarinic cholinergic receptors and cardiac parasympathetic responsiveness. Biochem Pharmacol 32:1999–2002
Yamamoto Y, Hughson RL, Peterson JC (1991) Autonomic control of heart rate during exercise studied by heart rate variability spectral analysis. J Appl Physiol 71:1136–1142
Yamamoto Y, Hughson RL, Sutton JR, Houston CS, Cymerman A, Fallen EL, Kamath MV (1993) Operation Everest II: an indication of deterministic chaos in human heart rate variability at simulated extreme altitude. Biol Cybern 69:205–212
Zetterberg LH (1978) Estimation of parameters for a linear difference equation with application to EEG analysis. Math Biosci 5:227–275
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Perini, R., Milesi, S., Biancardi, L. et al. Effects of high altitude acclimatization on heart rate variability in resting humans. Eur J Appl Physiol 73, 521–528 (1996). https://doi.org/10.1007/BF00357674
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DOI: https://doi.org/10.1007/BF00357674