Comparison of Respiratory and Circulatory Human Responses to Progressive Hypoxia and Hypercapnia

Serebrovskaya, Tatiana V.

doi:10.1159/000196022

Cited by 20 publications

(6 citation statements)

References 16 publications

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“…Also, there is an interaction between the baroreceptors and the chemoreflex responses to hypoxia (39). Concerning hemodynamic response to progressive isocapnic hypoxia developed in parallel to ventilatory response, Serebrovskaya (37) assumed that parallel reflex reactions of respiration and circulation may be induced by the impulses from the peripheral chemoreceptors sensitive to the hypoxia simultaneously reaching the respiratory and vasomotor centers. From several reports mentioned above, because the mechanism of BP response to hypoxia is complicated and the significant correlations between ␦HVR and ␦⌬SBP/⌬Sa O 2 by endurance training and detraining cannot establish cause and effect, it cannot be proved that the changes in the SBP response in the present study are simply induced by the changes in ventilatory response to hypoxia as proposed by Insalaco et al (15), but it seems reasonable to suppose that there is an interaction between the changes in the SBP and ventilatory responses to isocapnic hypoxia by endurance training and detraining.…”

Section: Discussionmentioning

confidence: 99%

Cardiovascular response to hypoxia after endurance training at altitude and sea level and after detraining

Katayama¹,

Sato²,

Morotome³

et al. 2000

Journal of Applied Physiology

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The purpose of this study was to elucidate 1) the effects of endurance exercise training during hypoxia or normoxia and of detraining on ventilatory and cardiovascular responses to progressive isocapnic hypoxia and 2) whether the change in the cardiovascular response to hypoxia is correlated to changes in the hypoxic ventilatory response (HVR) after training and detraining. Seven men (altitude group) performed endurance training using a cycle ergometer in a hypobaric chamber of simulated 4,500 m, whereas the other seven men (sea-level group) trained at sea level (K. Katayama, Y. Sato, Y. Morotome, N. Shima, K. Ishida, S. Mori, and M. Miyamura. J. Appl. Physiol. 86: 1805-1811, 1999). The HVR, systolic and diastolic blood pressure responses (DeltaSBP/DeltaSa(O(2)), DeltaDBP/DeltaSa(O(2))), and heart rate response (DeltaHR/DeltaSa(O(2)); Sa(O(2)) is arterial oxygen saturation) to progressive isocapnic hypoxia were measured before and after training and during detraining. DeltaSBP/DeltaSa(O(2)) increased significantly in the altitude group and decreased significantly in the sea-level group after training. The changed DeltaSBP/DeltaSa(O(2)) in both groups was restored during 2 wk of detraining, as were the changes in HVR, whereas there were no changes in the DeltaDBP/DeltaSa(O(2)) and DeltaHR/DeltaSa(O(2)) throughout the experimental period. The changes in DeltaSBP/DeltaSa(O(2)) after training and detraining were significantly correlated with those in HVR. These results suggest that DeltaSBP/DeltaSa(O(2)) to progressive isocapnic hypoxia is variable after endurance training during hypoxia and normoxia and after detraining, as is HVR, but DeltaDBP/DeltaSa(O(2)) and DeltaHR/DeltaSa(O(2)) are not. It also suggests that there is an interaction between the changes in DeltaSBP/DeltaSa(O(2)) and HVR after endurance training or detraining.

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Section: Discussionmentioning

confidence: 99%

Cardiovascular response to hypoxia after endurance training at altitude and sea level and after detraining

Katayama¹,

Sato²,

Morotome³

et al. 2000

Journal of Applied Physiology

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“…In both studies, 2 weeks of IHT increased the hypoxic ventilatory response, which was taken to indicate an increased hypoxic responsiveness of the carotid body with altitude acclimatization. Examination of the time course has suggested that the enhancement of ventilatory sensitivity begins with the first hypoxic exposure, and approaches a plateau by the third day (Serebrovskaya, 1992;Serebrovskaya and Ivashkevich, 1992). If so, then in normal humans only a few minutes of daily hypoxic exposure rapidly induces detectable increments in hypoxic ventilatory response, a hallmark of altitude acclimatization.…”

Section: Intermittent Hypoxic Training and Ventilationmentioning

confidence: 99%

Intermittent Hypoxia Research in the Former Soviet Union and the Commonwealth of Independent States: History and Review of the Concept and Selected Applications

Serebrovskaya

2002

High Altitude Medicine & Biology

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118

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This review aims to summarize the basic research in the field of intermittent hypoxia in the Soviet Union and the Commonwealth of Independent States (CIS) that scientists in other Western countries may not be familiar with, since Soviet scientists were essentially cut off from the global scientific community for about 60 years. In the 1930s the concept of repeated hypoxic training was developed and the following induction methods were utilized: repeated stays at high-mountain camps for several weeks, regular high altitude flights by plane, training in altitude chambers, and training by inhalation of low-oxygen-gas mixtures. To the present day, intermittent hypoxic training (IHT) has been used extensively for altitude preacclimatization; for the treatment of a variety of clinical disorders, including chronic lung diseases, bronchial asthma, hypertension, diabetes mellitus, Parkinson's disease, emotional disorders, and radiation toxicity, in prophylaxis of certain occupational diseases; and in sports. The basic mechanisms underlying the beneficial effects of IHT are mainly in three areas: regulation of respiration, free-radical production, and mitochondrial respiration. It was found that IHT induces increased ventilatory sensitivity to hypoxia, as well as other hypoxia-related physiological changes, such as increased hematopoiesis, alveolar ventilation and lung diffusion capacity, and alterations in the autonomic nervous system. Due to IHT, antioxidant defense mechanisms are stimulated, cellular membranes become more stable, Ca(2+) elimination from the cytoplasm is increased, and O(2) transport in tissues is improved. IHT induces changes within mitochondria, involving NAD-dependent metabolism, that increase the efficiency of oxygen utilization in ATP production. These effects are mediated partly by NO-dependent reactions. The marked individual variability both in animals and humans in the response to, and tolerance of, hypoxia is described. Studies from the Soviet Union and the CIS significantly contributed to the understanding of intermittent hypoxia and its possible beneficial effects and should stimulate further research in this direction in other countries.

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“…In men, acute hypercapnia leads to a pressor response in the systemic circulation (14,15,17), which is at least partially mediated via an increased sympathetic tone (17), but this response has not been reported in female subjects. The purpose of this study was to investigate the pressor effect of acute hyperoxic hypercapnia during the normal menstrual cycle.…”

mentioning

confidence: 96%

Hypercapnic blood pressure response is greater during the luteal phase of the menstrual cycle

Edwards

Wilcox²,

Polo³

et al. 1996

Journal of Applied Physiology

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We investigated the cardiovascular responses to acute hypercapnia during the menstrual cycle. Eleven female subjects with regular menstrual cycles performed hypercapnic rebreathing tests during the follicular and luteal phases of their menstrual cycles. Ventilatory and cardiovascular variables were recorded breath by breath. Serum progesterone and estradiol were measured on each occasion. Serum progesterone was higher during the luteal [50.4 +/- 9.6 (SE) nmol/l] than during the follicular phase (2.1 +/- 0.7 nmol/l; P < 0.001), but serum estradiol did not differ (follicular phase, 324 +/- 101 pmol/l; luteal phase, 162 +/- 71 pmol/l; P = 0.61). The systolic blood pressure responses during hypercapnia were 2.0 +/- 0.3 and 4.0 +/- 0.5 mmHg/Torr (1 Torr = 1 mmHg rise in end-tidal PCO2) during the follicular and luteal phases, respectively, of the menstrual cycle (P < 0.01). The diastolic blood pressure responses were 1.1 +/- 0.2 and 2.1 +/- 0.3 mmHg/Torr during the follicular and luteal phases, respectively (P < 0.002). Heart rate responses did not differ during the luteal (1.7 +/- 0.3 beats.min-1.Torr-1) and follicular phases (1.4 +/- 0.3 beats.min-1.Torr-1; P = 0.59). These data demonstrate a greater pressor response during the luteal phase of the menstrual cycle that may be related to higher serum progesterone concentrations.

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Comparison of Respiratory and Circulatory Human Responses to Progressive Hypoxia and Hypercapnia

Cited by 20 publications

References 16 publications

Cardiovascular response to hypoxia after endurance training at altitude and sea level and after detraining

Cardiovascular response to hypoxia after endurance training at altitude and sea level and after detraining

Intermittent Hypoxia Research in the Former Soviet Union and the Commonwealth of Independent States: History and Review of the Concept and Selected Applications

Hypercapnic blood pressure response is greater during the luteal phase of the menstrual cycle

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