An increased carbon dioxide production in transient hypoxia in healthy subjects at rest

Indices of pulmonary gas exchange and heart rate (HR) have been measured in 24 healthy subjects not adapted to hypoxia after hypoxic aerial mixture (HAM) (17, 15, 13 vol % of oxygen) respiration for 15 min. Using group data analysis, it has been shown that hypoxia under the conditions of inhalation of 17 and 15 vol % of O₂ caused no significant changes. Hypoxia under the conditions of 13 vol % of O₂ inhalation is a threshold one, when ventilation (SpO₂) drops below 85%. A significant increase in the lung ventilation (Ve) (10–14%, p < 0.05) and HR (11–15%, p < 0.05) have been observed in this case. Hyperpnea was accompanied by an increase in the oxygen uptake rate by 10% and carbon dioxide release rate (10–18%, p < 0.05). On the contrary, individual data analysis showed changes in the pulmonary gas exchange indices in 90% of subjects in the case of inhalation of 17 vol % of O₂ HAM. Four response types have been found: ventilation (increase in lung ventilation), hypoxic hypometabolism (decrease in oxygen consumption rate), and mobilization response (increase in oxygen utilization in the lungs), and anaerobic response, which is expressed in an increase in the carbon dioxide release rate along with an increase in the respiratory quotient. All these responses are of an individual type, but the ventilation response is developed in response to hypoxia caused by inhalation of 13 vol % of O₂ HAM and a decrease in SpO₂ below 85% in more than 60% of cases.     

Regional Blood Flow in the Upper Extremity during and after Exposure to Acute Normobaric Hypoxia

Cardiovascular indices were analyzed in young healthy males exposed to normobaric hypoxia (breathing a gas mixture containing 10% O₂ for 16 min). There was a marked variation in individual responses. A linear relationship was observed between the individual blood oxygen saturation at the end of exposure and the baseline muscle blood flow (MBF). Moreover, blood oxygen saturation decreased in subjects with an initially high forearm MBF and remained unchanged or even slightly increased in subjects with a low forearm MBF. After hypoxic exposure (10–15 min), the MBF continued to decrease, venous capacity increased, and postocclusion hyperemic response decreased. It is suggested that hypoxic exposure activates the neuroreflex mechanisms regulating the peripheral blood flow and that the peripheral vascular response to acute hypoxia depends largely on the baseline blood flow in skeletal muscles.     

Effect of Short-Term Intermittent Normobaric Hypoxia on the Regulation of External Respiration in Humans

Baseline external respiration and gas exchange values, as well as ventilatory thresholds and sensitivity to the O₂ and CO₂ stimuli in hypoxic and hypercapnic tests, were measured 1 h before and after a session of intermittent normobaric hypoxia (INH) (six repetitions with a 5-min inhalation of a gas mixture (10% O₂) alternating with a 3-min inhalation of atmospheric air). After an INH session, the background CO₂ level in the lungs increased by 10%. In the hypercapnic test, the actuation threshold of the ventilatory response did not change, whereas ventilatory sensitivity increased. The maximal pulmonary ventilation and the corresponding critical CO₂ level in the lungs also increased at the end of the test. In the hypoxic test, the ventilatory response occurred at a decreased level of blood oxygenation after an INH session, the pulmonary ventilation level being decreased and the CO₂ content in the lungs being increased at the end of the test. The data obtained evidence the maintenance of changed gas homeostasis for 1 h after an INH session. In this process, control of respiration was effected, with the hypoxic drive being weakened and the peripheral chemoreceptor sensitivity being decreased. The hypercapnic drive also increased, which may be determined by readjustment in the central mechanisms of respiratory regulation.     

Cardiorespiratory response to hypoxia in persons with different levels of creativity

The correlation between the parameters of creativity and tolerance to experimentally induced normobaric hypoxia has been studied in young healthy subjects. The subjects inhaled a low-oxygen gas mixture (10% O₂) until the arterial hemoglobin oxygen saturation (SaO₂) decreased to 80%. In the recovery period, the subjects breathed normoxic air until the SaO₂ returned to its initial value. The parameters of creativity, including the originality and fluency of producing images in Torrance’s subtests of Circles and Incomplete figures, as well as the originality and fluency of sentences composed by using nouns from distant semantic categories, were evaluated before conducting hypoxic tests. Positive relationships were found between the values of figurative originality and tolerance to hypoxia, i.e., by the time of decrease in SaO₂ and the coefficient that reflects the rate of recovery of the respiratory function. Analysis of the reactivity of the cardiovascular system showed negative correlations between the parameters of creativity, namely, the figurative originality and verbal fluency, and the heart rate under the conditions of hypoxia, as well as after the recovery of the functions of the cardiorespiratory system. An increase in the capacity for original figurative thinking also corresponded to smaller differences in the values of the heart rate during the recovery and at rest. These correlations between the characteristics of creative thinking and reactions of the cardiovascular and pulmonary systems to experimentally induced hypoxia indicate that there is a common mechanism of nervous regulation underlying adaptive behavior and maintaining homeostasis.     

Electrical activity of the brain and oxygen supply for cognitive-mnestic activity in humans under different degrees of hypoxia

Comparative analysis of the indices of oxygen supply for the body and the brain and the functional state of the brain was carried out in three experimental situations: performance of cognitive-mnestic tests under normoxic (TN) and hypoxic conditions (TH) and exposure to hypoxia in the absence of cognitive tasks (H). Each subject participated in all of the experiments. Hypoxic conditions were created by breathing of a hypoxic gas mixture (HGM) consisting of oxygen and nitrogen for 25 min. The first group (eight subjects) was exposed to moderate hypoxia, with the gas mixture containing 12% O₂ (HGM-12); the second group (eight subjects) was exposed to severe hypoxia, with the gas mixture containing 8% O₂ (HGM-8). The cognitive-mnestic activity (CMA) under both normoxia and hypoxia was continuous and included the following tests: “Arithmetic calculations,” “Memory for numerals,” “Colored figures”, and “Sensorimotor response time.” The CMA efficiency was significantly impaired only under severe hypoxia (HGM-8). The CMA efficiency was higher in some subjects of the first group (HGM-12) in the TH series as compared to that in the TN series. The EEG spectral power (SP) during CMA was decreased as compared to the background in all subjects in the TN series and in most subjects of the first group, exposed to HGM-12, whereas it was increased in all subjects of the second group, exposed to HGM-8. The EEG SP was lower in most subjects of both groups studied in the TH series as compared to that found in the H series. The rheographic index of cerebral blood flow rate was not changed compared to the background in the TN series and was increased in the H and TH series during HGM-8 treatment. The increase in cerebral blood flow was less pronounced in the TH series as compared to the H series in most subjects of the second group (HGM-8). Oxygen consumption by the body was elevated by 10–20% in the TN series. A significant increase in oxygen consumption was found in the subjects of both groups studied during hypoxia treatment (H), and it was greater in HGM-12. The following differences were found between the subjects of the two experimental groups: the increase in oxygen consumption in most subjects of the first group (HGM-12) was higher in the TH series as compared to the H series, whereas, in most subjects of the second group (HGM-8), the increase in oxygen consumption was higher in the H series. The data are discussed from the point of view of synergic and concurrent relationships between different forms of energy expenditure on structural and functional reorganization and organ-specific functions.     

Informative Value of Changes in Hand Skin Temperature in Response to Hypoxic Exposure

Residents of Magadan oblast with no experience of regular exposure to low ambient temperatures were examined to study the changes in hand skin temperature (HST) as a response to hypoxia. It was found that vasodilative responses followed by an increase in HST were typical of subjects demonstrating a high resistance to hypoxia during a 3-min rebreathing test and when breathing a gas mixture containing 8% O₂ and 92% N₂ for 14 min. Vasoconstrictor responses and a decrease in HST prevailed in subjects with a low resistance to hypoxia. Hand skin areas differed in the informative value of temperature changes in response to standard hypoxic exposure. Their characteristics may be used to select subjects for work under extreme environmental conditions and as an individual and specific marker of a human ecological portrait.__________Translated from Fiziologiya Cheloveka, Vol. 31, No. 3, 2005, pp. 108–117.Original Russian Text Copyright © 2005 by Maksimov.     

Ventilatory response of the diamondback water snake,Natrix rhombifera to hypoxia, hypercapnia and increased oxygen demand

Summary Simultaneous measurements of ventilatory frequency, tidal volume, O₂ uptake, CO₂ output and cardiac frequency were made in the diamondback water snake,Natrix rhombifera while breathing hypoxic (15% to 5% O₂ in N₂) or hypercarbic (2% to 10% CO₂ and 21% O₂ in N₂) gases. The snakes responded to hypoxia by increasing tidal volume and decreasing ventilatory frequency resulting in little change in ventilation (50% increase at 5% inspired O₂), or O₂ uptake and only a light increase in CO₂ output. Hypercarbia to 4.2% inspired CO₂ resulted in a slight hyperventilation but ventilation was depressed at 6.3% inspired CO₂ and became erratic at higher concentrations. The resting rate of O₂ uptake was maintained throughout hypercapnia. Heart rate increased during hypoxia and decreased during hypercapnia. Cutaneous O₂ uptake increased during extreme hypoxia (5% inspired O₂) and cutaneous CO₂ output increased during hypercapnia, probably due to changes in the body-to-ambient gas gradients (Crawford and Schultetus, 1970). Both pulmonary oxygen uptake and ventilation were dramatically increased immediately following 10–15 min experimental dives. The increased ventilation was achieved primarily through an increased tidal volume.     

Influences of Normobaric Hypoxia Training on Physical Fitness and Metabolic Risk Markers in Overweight to Obese Subjects

Previous studies suggested that hypoxia and exercise may have a synergistic effect on cardiovascular and metabolic risk factors. We conducted a single blind study in overweight to obese subjects to test the hypothesis that training under hypoxia (HG, n = 24, FiO₂ = 15%) results in similar or even greater improvement in body weight and metabolic risk markers compared with exercise under normoxia (NG, n = 21, FiO₂ = 21%). After an initial metabolic evaluation including incremental exercise testing, subjects trained in normoxic or hypoxic conditions thrice weekly over a 4‐week period at a heart rate corresponding to 65% of maximum oxygen uptake (VO_2max). The experimental groups were similar at the start of the investigation and weight stable during the training period. Subjects in the hypoxia group trained at a significantly lower workload (P < 0.05). Yet, both groups showed similar improvements in VO_2max and time to exhaustion. Respiratory quotient and lactate at the anaerobic threshold as well as body composition improved more in the hypoxia group. We conclude that in obese subjects, training in hypoxia elicits a similar or even better response in terms of physical fitness, metabolic risk markers, and body composition at a lower workload. The fact that workload and, therefore, mechanic strain can be reduced in hypoxia could be particularly beneficial in obese patients with orthopedic comorbidities.     

Respiratory and cardiovascular responses to acute hypoxia and hyperoxia in internally pipped chicken embryos

During the first day of hatching, the developing chicken embryo internally pips the air cell and relies on both the lungs and chorioallantoic membrane (CAM) for gas exchange. Our objective in this study was to examine respiratory and cardiovascular responses to acute changes in oxygen at the air cell or the rest of the egg during internal pipping. We measured lung (V·_O2lung) and CAM (V·_O2CAM) oxygen consumption independently before and after 60 min exposure to combinations of hypoxia, hyperoxia, and normoxia to the air cell and the remaining egg. Significant changes in V·_O2total were only observed with combined egg and air cell hypoxia (decreased V·_O2total) or egg hyperoxia and air cell hypoxia (increased V·_O2total). In response to the different O₂ treatments, a change in V·_O2lung was compensated by an inverse change in V·_O2CAM of similar magnitude. To test for the underlying mechanism, we focused on ventilation and cardiovascular responses during hypoxic and hyperoxic air cell exposure. Ventilation frequency and minute ventilation (V_E) were unaffected by changes in air cell O₂, but tidal volume (V_T) increased during hypoxia. Both V_T and V_E decreased significantly in response to decreased P_CO2. The right-to-left shunt of blood away from the lungs increased significantly during hypoxic air cell exposure and decreased significantly during hyperoxic exposure. These results demonstrate the internally pipped embryo's ability to control the site of gas exchange by means of altering blood flow between the lungs and CAM.     

Effects of hypoxia on the pulmonary microvascular permeability in adult rabbit lung

Within the last 30 years, researchers have explored what role hypoxia might play in causing permeability changes in the pulmonary microvasculature. Since the data accumulated thus far are unclear, the effects of hypoxia on microvascular transport in the isolated, Ringer's perfused adult rabbit lung was observed and the following parameters were measured or computed for both oxygenated and hypoxic perfusates: pulmonary arterial (r_a) and pulmonary venous (r_v) resistances, pulmonary capillary filtration coefficients (K_f), and pulmonary capillary endothelial reflection coefficients () for NaCl and inulin. Separate reservoir bottles were used to create the desired oxygenated (aeration of solution with 95% O₂-5% CO₂) gas mixture or hypoxic (aeration of solution with 95% N₂-5% CO₂) gas mixture. A higher, but not significant, resistance value was found during the oxygenated state. A significant increase in the pulmonary capillary filtration coefficient during hypoxia (10.72 × 10^–4±0.446 × 10^–4 cm³/s cm H₂O for the hypoxic perfusate and 8.80 × 10^–4±0.384 × 10^–4 cm³/s cm H₂O for the oxygenated perfusate) was found and a significant difference between oxygenated and hypoxic pulmonary capillary reflection coefficients for inulin was computed (oxygenated solution revealed a finding of 0.120±0.003 and the hypoxic solution revealed 0.105±0.002). These findings imply a change in the microvascular permeability during hypoxia. According to the pore theory, a change in pore number, pore size, or both could have occurred. However, from the reflection coefficient data, a change in pore radius seems most likely.     

Interactive effect of hypoxia and otolith organ engagement on cardiovascular regulation in humans.

We determined the interaction between the vestibulosympathetic reflex and the arterial chemoreflex in 12 healthy subjects. Subjects performed three trials in which continuous recordings of muscle sympathetic nerve activity (MSNA), mean arterial blood pressure (MAP), heart rate (HR), and arterial oxygen saturation were obtained. First, in prone subjects the otolith organs were engaged by use of head-down rotation (HDR). Second, the arterial chemoreflex was activated by inspiration of hypoxic gas (10% O2 and 90% N2) for 7 min with HDR being performed during minute 6. Third, hypoxia was repeated (15 min) with HDR being performed during minute 14. HDR [means +/- SE; increase (Delta)7 +/- 1 bursts/min and Delta50 +/- 11% for burst frequency and total MSNA, respectively; P < 0.05] and hypoxia (Delta6 +/- 2 bursts/min and Delta62 +/- 29%; P < 0.05) increased MSNA. Additionally, MSNA increased when HDR was performed during hypoxia (Delta11 +/- 2 bursts/min and Delta127 +/- 57% change from normoxia; P < 0.05). These increases in MSNA were similar to the algebraic sum of the individual increase in MSNA elicited by HDR and hypoxia (Delta13 +/- 1 bursts/min and Delta115 +/- 36%). Increases in MAP (Delta3 +/- 1 mmHg) and HR (Delta19 +/- 1 beats/min) during combined HDR and hypoxia generally were smaller (P < 0.05) than the algebraic sum of the individual responses (Delta5 +/- 1 mmHg and Delta24 +/- 2 beats/min for MAP and HR, respectively; P < 0.05). These findings indicate an additive interaction between the vestibulosympathetic reflex and arterial chemoreflex for MSNA. Therefore, it appears that MSNA outputs between the vestibulosympathetic reflex and arterial chemoreflex are independent of one another in humans.     

Microcirculatory reactivity features in apparently healthy individuals during acute moderate hypoxia and hyperoxia modeling

The dynamics of microvascular circulation and tissue oxygenation in response to the hypoxic test and the subsequent hyperoxia have been studied. The microcirculatory and tissue oxygenation parameters (laser Doppler flowmetry and optical tissue oximetry) were recorded in 30 apparently healthy young men during the hypoxic test (HT): breathing a gas mixture with 10% O₂ for 10 min followed by hyperoxia (30% O₂) for 3 min. It was established that, during the HT, no change in the relative level of tissue saturation with oxygen (SO₂) occurred, but the relative degree of oxygen extraction by tissues (ΔSaO₂-SO₂) decreased significantly with a rapid recovery in the hypoxic phase. This is accompanied by the activation of the neurogenic sympathetic-related vasomotor mechanisms (NT), as well as the endothelium-dependent microvascular tone component (EDTC) with a decrease in the shunting index (SI) mostly in the hyperoxic phase but not during hypoxia. The nature of the microcirculatory response to hypoxia depends on the initial level of resistance/sensitivity to hypoxia. In hypoxia-sensitive subjects, the HT causes SaO₂ and ΔSaO₂-SO₂ to decrease in the absence of significant shifts in the microcirculation regulation. Among the subjects resistant to hypoxia, HT leads to the nutritive blood flow activation by increasing the initially decreased EDTC and the neurogenic sympathetic component of microhemodynamics regulation and to a reduction of blood shunting. At the same time, ΔSaO₂-SO₂ does not significantly change, and the activation of microcirculation is also retained in the hyperoxic recovery phase. The identified functional criteria of the contribution of the endothelial and neurogenic vasomotor regulatory components of microhemodynamics in the HT substantiate the involvement of the microcirculatory component and confirm the important role of the hyperoxic phase in the adaptive response of the body to acute hypoxia/hyperoxia.     

Effect of hypoxic breathing on cutaneous temperature recovery in man

Effect of hypoxia (12% O₂) on skin temperature recovery was studied on healthy young men. Forty male volunteers free of any respiratory disorder were randomly selected to participate in the study. Skin temperature, peripheral blood flow, heart rate and end expiratoryPO₂ andPCO₂ were measured. During hyoxic ventilation the peripheral blood flow was reduced and a corresponding drop in skin temperature occurred. This was partly due to hyperventilation associated with hypoxic ventilation. The recovery of skin temperature after cooling the hand for 2 min in cold water (10–12° C) took 5.5±0.1 min during normal air breathing; during hypoxic ventilation even after 9.1±0.3 min when the skin temperature recovery curve plateaued, the skin temperature remained about 2° C below control. The results of the present investigation indicate that hypoxia interferes with the normal functioning of the thermoregulatory mechanism in man. Hyperventilation associated with hypoxic ventilation is also partly responsible for incomplete recovery of skin temperature.     

Influence of initial respiratory status on the short-and long-term activity of the trout red blood cell β-adrenergic Na+/H+ exchanger

The effects of ambient O₂ partial pressure and CO₂ partial pressure on the intensity of rainbow trout (Oncorhynchus mykiss) red blood cell -adrenergic Na⁺/H⁺ exchange were investigated. This was accomplished in vitro by continuously monitoring whole blood extracellular pH, partial pressures of O₂ and CO₂ and by measuring red blood cell water content and Na⁺ concentration before and 30 min after the addition of a catecholamine mixture (final nominal concentrations: 250 nmol·l^-1 adrenaline and 20 nmol·l^-1 noradrenaline). The experiments were performed under six different initial conditions combining two ambient partial pressures of CO₂ (1.50 and 6.75 torr) and three ambient partial pressures of O₂ (15, 30 and 150 torr). The activation of red blood cell Na⁺/H⁺ exchange (as indicated by marked reductions of whole blood pH) was followed by transient reductions in blood partial pressures of CO₂ and O₂ (2 min) resulting from the shift of the CO₂/HCO₃ ^- equilibrium within the cell and the subsequent binding of O₂ to the haemoglobin. The initial reduction in blood CO₂ partial pressure was followed by a rise reflecting the titration of plasma HCO₃ ^- by extruded H⁺. At low partial pressure of CO₂ (1.50 torr) there was a pronounced stimulatory effect of hypoxia on the initial intensity of the extracellular acidification (5 min), whereas at high CO₂ partial pressure (6.75 torr) hypoxia actually lowered the extent of the initial acidification. In all cases, Na⁺/H⁺ exchange activation was accompanied by increases in cell water content and red blood cell Na⁺ levles when measured 30 min after addition of catecholamines. Both hypercapnia and hypoxia increased the magnitude of these changes although the largest changes in cell water content and Na⁺ levels were observed under hypercapnic conditions. Thus, the long-term activity (as determined by measuring cell water and Na⁺ levels) of the Na⁺/H⁺ exchanger was enhanced both by hypercapnia and hypoxia regardless of the initial CO₂ partial pressure. The initial activity (5 min), on the other hand, although stimulated by hypercapnia was influenced by hypoxia in opposing directions depending upon the initial CO₂ partial pressure of the blood.Abbreviations RBC red blood cell(s) - Hb haemoglobin - pHe extracellular pH - P _bCO₂ blood partial pressure of CO₂ - P _bO₂ blood partial pressure of O₂     

Buoyancy control of four species of eleotrid fishes during aquatic surface respiration

Synopsis Four species of Australian Eleotridae from hypoxic habitats were examined in the laboratory to study buoyancy control in hypoxic water (<10 torr) when performing aquatic surface respiration (ASR; irrigating gills with upper millimeter of surface water). A conflict can arise here because O₂ can be reabsorbed from the swimbladder (reducing buoyancy) at a time when additional lift may be required to perform ASR. Three species were negatively buoyant and initially performed ASR while resting on the bottom in shallow water. After 24 h swimbladder lift increased to nearly neutral and ASR was performed while fish were pelagic. The fourth species remained pelagic at near neutral buoyancy in hypoxic water. With sudden exposure to hypoxia these physoclists reabsorbed between 5–27% (depending on species) of swimbladder volume (standard pressure) during the initial 30–90 min exposure to hypoxia. Additional experiments on one species (Hypseleotris galii) showed such loss to occur at O₂ tensions below 68 torr and when O₂ declined rapidly (2.17 torr min^-1). Secretion of gas compensated for losses under slower, natural rates of nocturnal O₂ decline. Eleotrids appear to reduce the conflict between respiration and buoyancy control in hypoxia by restricting gas reabsorbtion from the swimbladder and by rapidly secreting gases into the swimbladder.     

Heart rate responses to altered ambient oxygen in early (days 3–9) chick embryos in the intact egg

Normal heart rate (HR), and the HR responses to hypoxia and hyperoxia during early heart development in chick embyros have not been studied in detail, particularly in undisturbed embryos within the intact egg. HR was measured in day 3–9 chick embryos at 38 °C using relatively noninvasive impedance cardiography. Embryos were exposed to air (control) and to hypoxic (10% O₂) or hyperoxic (100% O₂) gas for a 2-h or 4-h period, during which HR was continually monitored. Control (normoxic) HR increased from about 150 beats per min (bpm) on day 3 to about 240 bpm on days 7–9. HR in very early embryos showed a variety of moderate responses to hypoxia (all survived), but as development progressed beyond day 6, hypoxic exposure induced a profound bradycardia that frequently terminated in death before the end of the measurement period. In contrast to the marked developmental changes in hypoxic sensitivity, HR showed little response to hyperoxia throughout development, suggesting no “hypoxic drive” to HR. We speculate that hypoxia has little effect early in development because of the embryo's small absolute O₂ demand, but as the embryo grows, hypoxia represents a progressively more severe perturbation. Although general trends were identified, there was considerable variation in both HR and HR responses to ambient O₂ changes between individuals of the same developmental stage. Accepted: 16 December 1998     

Production of reactive oxygen species and antioxidant enzymes of pea and soybean plants under hypoxia and high CO<Subscript>2</Subscript> concentration in medium

Generation of reactive oxygen species (ROS) and activities of antioxidant enzymes (catalase, peroxidase, ascorbate peroxidase) in pea (Pisum sativum L.) and soybean (Glycine max L.) under hypoxia (3–24 h) and high CO₂ concentration in medium were studied. In sensitive to hypoxia pea seedlings, hypoxia enhanced markedly production of superoxide anion-radical, hydroperoxides, and especially hydrogen peroxide. In more tolerant soybean plants, these changes were less pronounced. During first hours of hypoxia, activity of lipoxygenase in plant cells increased. This allows a suggestion that this enzyme is involved in the processes of hydroperoxide accumulation in plant tissues under oxygen deficit. In pea and soybean plants, a correlation between tolerance to hypoxia, the rate of ROS generation, and antioxidant enzyme activities was established. During the first hours of hypoxia, the catalase activity in soybean plants increased stronger than in sensitive to hypoxia pea plants. At longer exposure to hypoxia (24 h), peroxidases started to play the higher role in cell defense against hypoxia, but only in soybean plants. The medium with the higher CO₂ content induced higher changes in the processes of ROS accumulation and activities of lipoxygenase and antioxidant enzymes. This permits us to refer CO₂, accumulated as a product of respiration in the cells, to low-molecular signal molecules switching on plant adaptation to hypoxic stress.     

External respiration response of trained skiers to intermittent normobaric hypoxia

As part of a study on the resistance of subjects adapted to aerobic physical activity to hypoxia, the ventilatory response of trained skiers whose regular physical training is associated with hyperventilation to intermittent normobaric hypoxia has been analyzed. A test session consisted of three cycles of breathing alternately a hypoxic gas mixture (10 vol % O₂) for 5 min and normal air for 5 min. The skiers have a lower oxygen consumption rate as compared with untrained subjects, i.e., a reduced resistance to hypoxia. Therefore, the efficiency of respiration during hypoxia is lower in atheltes, which is caused by a rapid decrease in blood oxygenation, whereas during breathing normal atmospheric air, the efficiency of respiration is lower in untrained subjects.     

Blunted pulmonary pressor responses to hypoxia in blood perfused, ventilated lungs isolated from oxygen toxic rats: Possible role of prostaglandins

To determine the effects of high oxygen (O₂) tension on pulmonary vascular reactivity, we exposed rats either to 100% O₂ for 48 hrs or 40% O₂ for 3 to 5 weeks. Lungs from all rats were isolated, blood perfused and ventilated, and pressor responses to airway hypoxia and to infused angiotensin II were measured. We found that chronic subtoxic hyperoxia did not augment subsequent hypoxic vasoconstriction, and that 48 hrs of 100% O₂ markedly blunted hypoxic vasoconstriction. Meclofenamate restored hypoxic vasoconstriction to control levels in the lungs with blunted responses. Evidence for O₂ toxicity in the lungs exposed to 100% O₂ included interstitial swelling with alveolar exudates seen by light microscopy, and lung edema by water content calculations. We conclude that 1) chronic subtoxic hyperoxia does not influence subsequent hypoxic vasoconstriction, and 2) a dilator prostaglandin produced in the lung is a potent inhibitor of hypoxic vasoconstriction in O₂ toxic lungs.     

Oxygen regime in rat brain tissues under conditions of acute nitrite methemoglobinemia

Oxygen regime in rat brain tissues was studied under conditions of nitrite hypoxia. The local brain circulation (LCC) and pO₂ were recorded by polargraphic method in microareas of the brain cortex one hour after a subcutaneous injection of NaNO₂ (3 mg/100 g body mass). A LCC decrease by 55% was shown by the 30th min of the nitrite intoxication, with its restoration to 85% of the initial blood-flow by the 60th min. In some brain microareas, a pO₂ increase by 40.7% was observed by the 45th min of the action and its decrease by 32.2% by the 60th min, whereas in other microareas, a pO₂ decrease by 24.5% with its subsequent increase to 78.7% of the initial level, respectively. A statistically significant correlation is revealed between changes of the oxygen pressure in the process of development of nitrite hypoxia and the LCC dynamics. It is concluded that the circulatory disturbances developing at the first moments of the nitrite action lead to an increase of the degree of the pO₂ differentiated distribution in the brain: to hyperoxygenation in some microareas and to severe hypoxia in others, what can be the cause of functional brain disturbances under the effect of nitrogen oxides.