A control system for arterial blood gases

A system was developed to control arterial O2 and CO2 partial pressure (Pao2, and Paco2) simultaneously and independently of each other. The system makes changes in inspired fractional concentration of O2 and CO2 based on values for end-tidal O2 and CO2 partial pressure. The system was applied in 23 normal subjects. In attempts to maintain a Pao2 of 90 Torr and a Paco2 of 40 Torr, arterial blood gases were 91.1 +/- 6.5 (SD) Torr for Pao2 and 41.2 +/- 3.2 Torr for Paco2. In attempts to maintain a Pao2 of 40 Torr and a Paco2 of 40 Torr, arterial blood gases were 40.4 +/- 3.9 Torr for Pao2 and 38.9 +/- 2.5 Torr for Paco2. In attempts to maintain a Pao2 of 90 Torr and a Paco2 of 55 Torr, arterial blood gases were 98.1 +/- 11.5 Torr for Pao2 and 52.8 +/- 3.4 Torr for Paco2. Coefficients of variations ranged from 7.1 to 11.7% for Pao2 and 6.4 to 7.8% for Paco2.     

Carotid bodies are required for ventilatory acclimatization to chronic hypoxia

We have compared the ventilatory responses of intact and carotid body-denervated (CBD) goats to moderate [partial pressure of O2 in arterial blood; (Pao2) approximately 44 Torr] and severe (Pao2 approximately 33 Torr) many time points for up to 7 days of hypobaria. In the intact group there were significant time-dependent decreases in partial pressure of CO2 in arterial blood (PaCO2) in both moderate and severe hypoxemia (approximately-7 and -11 Torr) that were largely complete by 8 h of hypoxemia and maintained throughout. Acute restoration of normoxia in chronically hypoxic intact animals produced time-dependent increases in Paco2 over 2 h, but hypocapnia persisted relative to sea-level control. Arterial plasma [HCO3-] and [H+] decreased, and [Cl-] increased with a time course and magnitude consistent with developing hypocapnia. Chronic CBD, per se, resulted in a sustained, partially compensated respiratory acidosis, as PaCO2 rose 6 Torr and base excess rose 3 mEq/1, [Cl-] fell 1 mEq/1, and pHa fell 0.01 units. During exposure to identical levels of arterial hypoxemia as in the intact group. CBD animals showed no significant changes in PaCO2, [H+]a, or [HCO3-]a at any time during moderate or severe hypoxemia. Plasma [C1-] remained within the normal range throughout exposure to moderate hypoxia and increased in severe hypoxia. In a few instances some hypocapnia was observed, but this was highly inconsistent and was always less than one-third of that observed in intact goats. In contrast to intact goats, acute restorations of normoxia in the chronically hypoxic CBD goats always caused hyperventilation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Arterial blood gases in conscious rats exposed to hypoxia, hypercapnia, or both.

Adult male rats were anesthetized and catheters were implanted in the caudal artery. Soon after recovery from short-lasting anesthesia, a total of 20 groups of six each were individually exposed to five different oxygen levels varying from 21.0 to 9.0% combined with four CO2 levels ranging from 0 to 12.9% at a mean barometric pressure of 744 Torr. Arterial blood samples were collected and analyzed for pH, Po2, and Pco2 before and near the end of 20-min exposures. During an air-breathing control period, pH averaged 7.466 plus or minus 0.020 SD, Paco2 41.2 plus or minus 1.9 Torr and Pao2 91.8 plus or minus 3.5 Torr. During hypoxia, Pao2 levels were similar to that of acutely hypoxic humans. Rats apparently differ from man in that blood buffering is greater, resulting in a higher pH during air breathing and a smaller [H-+] increase with increasing Paco2. Differences between arterial and inspired CO2 were about 10 Torr at 60 and 90 Torr Plco2 and were not influenced by Plo2.     

Cerebrovascular responsiveness to steady-state changes in end-tidal CO2 during passive heat stress.

This study tested the hypothesis that passive heat stress alters cerebrovascular responsiveness to steady-state changes in end-tidal CO(2) (Pet(CO(2))). Nine healthy subjects (4 men and 5 women), each dressed in a water-perfused suit, underwent normoxic hypocapnic hyperventilation (decrease Pet(CO(2)) approximately 20 Torr) and normoxic hypercapnic (increase in Pet(CO(2)) approximately 9 Torr) challenges under normothermic and passive heat stress conditions. The slope of the relationship between calculated cerebrovascular conductance (CBVC; middle cerebral artery blood velocity/mean arterial blood pressure) and Pet(CO(2)) was used to evaluate cerebrovascular CO(2) responsiveness. Passive heat stress increased core temperature (1.1 +/- 0.2 degrees C, P < 0.001) and reduced middle cerebral artery blood velocity by 8 +/- 8 cm/s (P = 0.01), reduced CBVC by 0.09 +/- 0.09 CBVC units (P = 0.02), and decreased Pet(CO(2)) by 3 +/- 4 Torr (P = 0.07), while mean arterial blood pressure was well maintained (P = 0.36). The slope of the CBVC-Pet(CO(2)) relationship to the hypocapnic challenge was not different between normothermia and heat stress conditions (0.009 +/- 0.006 vs. 0.009 +/- 0.004 CBVC units/Torr, P = 0.63). Similarly, in response to the hypercapnic challenge, the slope of the CBVC-Pet(CO(2)) relationship was not different between normothermia and heat stress conditions (0.028 +/- 0.020 vs. 0.023 +/- 0.008 CBVC units/Torr, P = 0.31). These results indicate that cerebrovascular CO(2) responsiveness, to the prescribed steady-state changes in Pet(CO(2)), is unchanged during passive heat stress.     

Cardiovascular responses to hypoxia and hypercapnia in barodenervated rats

Experiments were performed to examine the role of the arterial baroreceptors in the cardiovascular responses to acute hypoxia and hypercapnia in conscious rats chronically instrumented to monitor systemic hemodynamics. One group of rats remained intact, whereas a second group was barodenervated. Both groups of rats retained arterial chemoreceptive function as demonstrated by augmented ventilation in response to hypoxia. The cardiovascular effects to varying inspired levels of O2 and CO2 were examined and compared between intact and barodenervated rats. No differences between groups were noted in response to mild hypercapnia (5% CO2); however, the bradycardia and reduction in cardiac output observed in intact rats breathing 10% CO2 were eliminated by barodenervation. In addition, hypocapnic hypoxia caused a marked fall in blood pressure and total peripheral resistance (TPR) in barodenervated rats compared with controls. Similar differences in TPR were observed between the groups in response to isocapnic and hypercapnic hypoxia as well. It is concluded that the arterial baroreflex is an important component of the overall cardiovascular responses to both hypercapnic and hypoxic stimuli in the conscious rat.     

Ventilatory acclimatization to hypoxia is not dependent on cerebral hypocapnic alkalosis

We previously demonstrated that, in awake goats, 6 h of hypoxic carotid body perfusion during systemic normoxia produced time-dependent hyperventilation that is typical of ventilatory acclimatization to hypoxia (VAH). The hypocapnic alkalosis that occurred could have produced VAH by inducing cerebral vasoconstriction and brain lactic acidosis even though systemic arterial normoxia was maintained. In the present study we tested the hypothesis that hypocapnic alkalosis is a necessary component of VAH. Goats were prepared so that one carotid body could be perfused, from an extracorporeal circuit, with blood in which gas tensions could be controlled independently from the blood perfusing the systemic arterial system, including the brain. Using this preparation we carried out 4 h of hypoxic carotid body perfusion while maintaining systemic arterial (and brain) normoxia in awake goats. Expired minute ventilation (VE) was measured while CO2 was added to inspired air to maintain normocapnia. Carotid body PCO2 and PO2 were maintained near 40 Torr during the 4-h carotid body perfusion. Control mean VE was 8.65 +/- 0.48 l/min (mean +/- SE). With acute carotid body hypoxia (30 min) VE increased to 21.73 +/- 2.02 l/min (P less than 0.05); over the ensuing 3.5 h of carotid body hypoxia, VE progressively increased to 39.14 +/- 4.14 l/min (P less than 0.05). These data indicate that neither cerebral hypoxia nor hypocapnic alkalosis are required to produce VAH. After termination of the 4-h carotid body stimulation, hyperventilation was not maintained in these studies, i.e., there was no deacclimatization. This suggests that acclimatization and deacclimatization are produced by different mechanisms.     

Hypoxic adaptation of the rat carotid body

Three types of hypoxia with different levels of carbon dioxide (hypocapnic, isocapnic, and hypercapnic hypoxia) have been called systemic hypoxia. The systemic hypoxic carotid bodies were enlarged several fold, but the degree of enlargement was different for each. The mean short and long axes of hypocapnic and isocapnic hypoxic carotid bodies were 1.6 (short axis) and 1.8-1.9 (long axis) times larger than normoxic control carotid bodies, respectively. Those of hypercapnic hypoxic carotid bodies were 1.2 (short axis) and 1.5 (long axis) times larger than controls, respectively. The rate of enlargement in hypercapnic hypoxic carotid bodies was lower than in hypocapnic and isocapnic hypoxic carotid bodies. The rate of vascular enlargement in hypercapnic hypoxic carotid bodies was also smaller than in hypocapnic and isocapnic hypoxic carotid bodies. Thus, the enlargement of hypoxic carotid bodies is mainly due to vascular dilation. Different levels of arterial CO2 tension change the peptidergic innervation during chronically hypoxic exposure. The characteristic vascular arrangement was under the control of altered peptidergic innervation. During the course of hypoxic adaptation, the enlargement of the carotid bodies with vascular expansion began soon after the start of hypoxic exposure. During the course of recovery, the shrinking of the carotid bodies with vascular contraction also started at a relatively early period after the termination of chronic hypoxia. These processes during the course of hypoxic adaptation and during the course of recovery were under the control of peptidergic innervation. These findings may provide a standard for further studies of hypoxic carotid bodies.     

Regional pulmonary blood flow during 96 hours of hypoxia in conscious sheep

The effects of acute hypoxia on regional pulmonary perfusion have been studied previously in anesthetized, artificially ventilated sheep (J. Appl. Physiol. 56: 338-342, 1984). That study indicated that a rise in pulmonary arterial pressure was associated with a shift of pulmonary blood flow toward dorsal (nondependent) areas of the lung. This study examined the relationship between the pulmonary arterial pressor response and regional pulmonary blood flow in five conscious, standing ewes during 96 h of normobaric hypoxia. The sheep were made hypoxic by N2 dilution in an environmental chamber [arterial O2 tension (PaO2) = 37-42 Torr, arterial CO2 tension (PaCO2) = 25-30 Torr]. Regional pulmonary blood flow was calculated by injecting 15-micron radiolabeled microspheres into the superior vena cava during normoxia and at 24-h intervals of hypoxia. Pulmonary arterial pressure increased from 12 Torr during normoxia to 19-22 Torr throughout hypoxia (alpha less than 0.049). Pulmonary blood flow, expressed as %QCO or ml X min-1 X g-1, did not shift among dorsal and ventral regions during hypoxia (alpha greater than 0.25); nor were there interlobar shifts of blood flow (alpha greater than 0.10). These data suggest that conscious, standing sheep do not demonstrate a shift in pulmonary blood flow during 96 h of normobaric hypoxia even though pulmonary arterial pressure rises 7-10 Torr. We question whether global hypoxic pulmonary vasoconstriction is, by itself, beneficial to the sheep.     

Cerebral oxygen availability by NIR spectroscopy during transient hypoxia in humans

The effects of mild hypoxia on brain oxyhemoglobin, cytochrome a,a3 redox status, and cerebral blood volume were studied using near-infrared spectroscopy in eight healthy volunteers. Incremental hypoxia reaching 70% arterial O2 saturation was produced in normocapnia [end-tidal PCO2 (PETCO2) 36.9 +/- 2.6 to 34.9 +/- 3.4 Torr] or hypocapnia (PETCO2 32.8 +/- 0.6 to 23.7 +/- 0.6 Torr) by an 8-min rebreathing technique and regulation of inspired CO2. Normocapnic hypoxia was characterized by progressive reductions in arterial PO2 (PaO2, 89.1 +/- 3.5 to 34.1 +/- 0.1 Torr) with stable PETCO2, arterial PCO2 (PaCO2), and arterial pH and resulted in increases in heart rate (35%) systolic blood pressure (14%), and minute ventilation (5-fold). Hypocapnic hypoxia resulted in progressively decreasing PaO2 (100.2 +/- 3.6 to 28.9 +/- 0.1 Torr), with progressive reduction in PaCO2 (39.0 +/- 1.6 to 27.3 +/- 1.9 Torr), and an increase in arterial pH (7.41 +/- 0.02 to 7.53 +/- 0.03), heart rate (61%), and ventilation (3-fold). In the brain, hypoxia resulted in a steady decline of cerebral oxyhemoglobin content and a decrease in oxidized cytochrome a,a3. Significantly greater loss of oxidized cytochrome a,a3 occurred for a given decrease in oxyhemoglobin during hypocapnic hypoxia relative to normocapnic hypoxia. Total blood volume response during hypoxia also was significantly attenuated by hypocapnia, because the increase in volume was only half that of normocapnic subjects. We conclude that cytochrome a,a3 oxidation level in vivo decreases at mild levels of hypoxia. PaCO is an important determinant of brain oxygenation, because it modulates ventilatory, cardiovascular, and cerebral O2 delivery responses to hypoxia.     

In vivo evaluation of transcutaneous CO2 partial pressure monitoring

Correlation between transcutaneous and arterial CO2 partial pressure (Ptcco2, and Paco2) under normal and hemorrhagic shock conditions was evaluated in rabbits. Under normal conditions the Paco2-to-Ptcco2 least-squares regression line had a slope of 1.03 an intercept of 4.57 Torr, and a root mean variance of +/- 3.79 Torr. Under hemorrhagic shock conditions the slope remained similar, but the intercept increased, producing a significant difference between arterial and transcutaneous values. The correlation line shifts to the left so that, for a given Paco2, the Ptcco2 value increases. The transcutaneous response time (90%) under conditions produced by breathing 10% CO2 lagged 2.8 +/- 1.4 min behind that of the breathing 10% CO2 lagged 2.8 +/- 1.4 min behind that of the Paco2. The difference between transcutaneous and arterial CO2 observed during hemorrhagic shock and the lag in transcutaneous response time can be altered by topical application of dimethyl sulfoxide, by altering both flow and permeability. These results indicate that good Ptcco2-to-Paco2 correlation exists under normal conditions and that hemorrhagic shock will produce tissue CO2 accumulation and therefore higher than arterial Ptcco2 values.     

Effects of acetazolamide on cerebral acid-base balance

Acetazolamide (AZ) inhibition of brain and blood carbonic anhydrase increases cerebral blood flow by acidifying cerebral extracellular fluid (ECF). This ECF acidosis was studied to determine whether it results from high PCO2, carbonic acidosis (accumulation of H2CO3), or lactic acidosis. Twenty rabbits were anesthetized with pentobarbital sodium, paralyzed, and mechanically ventilated with 100% O2. The cerebral cortex was exposed and fitted with thermostatted flat-surfaced pH and PCO2 electrodes. Control values (n = 14) for cortex ECF were pH 7.10 +/- 0.11 (SD), PCO2 42.2 +/- 4.1 Torr, PO2 107 +/- 17 Torr, HCO3- 13.8 +/- 3.0 mM. Control values (n = 14) for arterial blood were arterial pH (pHa) 7.46 +/- 0.03 (SD), arterial PCO2 (PaCO2) 32.0 +/- 4.1 Torr, arterial PO2 (PaO2) 425 +/- 6 Torr, HCO3- 21.0 +/- 2.0 mM. After intravenous infusion of AZ (25 mg/kg), end-tidal PCO2 and brain ECF pH immediately fell and cortex PCO2 rose. Ventilation was increased in nine rabbits to bring ECF PCO2 back to control. The changes in ECF PCO2 then were as follows: pHa + 0.04 +/- 0.09, PaCO2 -8.0 +/- 5.9 Torr, HCO3(-)-2.7 +/- 2.3 mM, PaO2 +49 +/- 62 Torr, and changes in cortex ECF were as follows: pH -0.08 +/- 0.04, PCO2 -0.2 +/- 1.6 Torr, HCO3(-)-1.7 +/- 1.3 mM, PO2 +9 +/- 4 Torr. Thus excess acidity remained in ECF after ECF PCO2 was returned to control values. The response of intracellular pH, high-energy phosphate compounds, and lactic acid to AZ administration was followed in vivo in five other rabbits with 31P and 1H nuclear magnetic resonance spectroscopy.(ABSTRACT TRUNCATED AT 250 WORDS)     

Independence of exercise hyperpnea and acidosis during high-intensity exercise in ponies

We investigated arterial PCO2 (PaCO2) and pH (pHa) responses in ponies during 6-min periods of high-intensity treadmill exercise. Seven normal, seven carotid body-denervated (2 wk-4 yr) (CBD), and five chronic (1-2 yr) lung (hilar nerve)-denervated (HND) ponies were studied during three levels of constant load exercise (7 mph-11%, 7 mph-16%, and 7 mph-22% grade). Mean pHa for each group of ponies became alkaline in the first 60 s (between 7.45 and 7.52) (P less than 0.05) at all work loads. At 6 min pHa was at or above rest at 7 mph-11%, moderately acidic at 7 mph-16% (7.32-7.35), and markedly acidic at 7 mph-22% (7.20-7.27) for all groups of ponies. Yet with no arterial acidosis at 7 mph 11%, normal ponies decreased PaCO2 below rest (delta PaCO2) by 5.9 Torr at 90 s and 7.8 Torr by 6 min of exercise (P less than 0.05). With a progressively more acid pHa at the two higher work loads in normal ponies, delta PaCO2 was 7.3 and 7.8 Torr by 90 s and 9.9 and 11.4 Torr by 6 min, respectively (P less than 0.05). CBD ponies became more hypocapnic than the normal group at 90 s (P less than 0.01) and tended to have greater delta PaCO2 at 6 min. The delta PaCO2 responses in normal and HND ponies were not significantly different (P greater than 0.1).(ABSTRACT TRUNCATED AT 250 WORDS)     

Ventilatory interaction between hypoxia and [H+] at chemoreceptors of man.

By measuring ventilation during isocapnic progressive hypoxia, peripheral chemoreceptor sensitivity to acute hypoxia (deltaV40) was measured in five normal young men under four sets of conditions: 1) at sea level at the subject's resting PCO2, 2) at sea level with PCO2 5 Torr above resting PCO2, 3) after 24 h at a simulated altitude of 4,267 m (PB = 447 Torr) at the subject's resting PCO2 measured during acute hyperoxia, and 4) after 24 h at high altitude, with PCO2 elevated to the subject's sea-level resting PCO2. With this experimental design, we were able to systematically vary the PCO2 and [H+] at the peripheral and central chemoreceptors of man. When mean pHa was decreased from 7.424 to 7.377 without significant change in PACO2, the mean deltaV40 increased from 18.0 to 55.9 1/min. Conversely, when mean PACO2 was altered between 33.8 and 41.6 Torr with pHa held relatively constant, the mean deltaV40 did not change. This suggests that it is the H+ and not CO2 which interacts with hypoxia in stimulating the ventilation of man. An additional finding was that the intrinsic sensitivity of the peripheral chemoreceptors to acute hypoxia did not change during 24 h of acclimatization to high altitude.     

Ventilatory acclimatization to hypoxia is not dependent on arterial hypoxemia

Goats were prepared so that one carotid body (CB) could be perfused with blood in which the gas tensions could be controlled independently from the blood perfusing the systemic arterial system, including the brain. Since one CB is functionally adequate, the nonperfused CB was excised. To determine whether systemic arterial hypoxemia is necessary for ventilatory acclimatization to hypoxia (VAH), the CB was perfused with hypoxic normocapnic blood for 6 h [means +/- SE: partial pressure of carotid body O2 (PcbO2), 40.6 +/- 0.3 Torr; partial pressure of carotid body CO2 (PcbCO2), 38.8 +/- 0.2 Torr] while the awake goat breathed room air to maintain systemic arterial normoxia. In control periods before and after CB hypoxia the CB was perfused with hyperoxic normocapnic blood. Changes in arterial PCO2 (PaCO2) were used as an index of changes in ventilation. Acute hypoxia (0.5 h of hypoxic perfusion) resulted in hyperventilation sufficient to reduce average PaCO2 by 6.7 Torr from control (P less than 0.05). Over the subsequent 5.5 h of hypoxic perfusion, average PaCO2 decreased further, reaching 4.8 Torr below that observed acutely (P less than 0.05). Acute CB hyperoxic perfusion (20 min) following 6 h of hypoxia resulted in only partial restoration of PaCO2 toward control values; PaCO2 remained 7.9 Torr below control (P less than 0.05). The progressive hyperventilation that occurred during and after 6 h of CB hypoxia with concomitant systemic normoxia is similar to that occurring with total body hypoxia. We conclude that systemic (and probably brain) hypoxia is not a necessary requisite for VAH.     

Morning attenuation in cerebrovascular CO2 reactivity in healthy humans is associated with a lowered cerebral oxygenation and an augmented ventilatory response to CO2.

We hypothesized that, in healthy subjects without pharmacological intervention, an overnight reduction in cerebrovascular CO(2) reactivity would be associated with an elevated hypercapnic ventilatory [ventilation (VE)] responsiveness and a reduction in cerebral oxygenation. In 20 healthy male individuals with no sleep-related disorders, continuous recordings of blood velocity in the middle cerebral artery, arterial blood pressure, VE, end-tidal gases, and frontal cortical oxygenation using near infrared spectroscopy were monitored during hypercapnia (inspired CO(2), 5%), hypoxia [arterial O(2) saturation (Sa(O(2))) approximately 84%], and during a 20-s breath hold to investigate the related responses to hypercapnia, hypoxia, and apnea, respectively. Measurements were conducted in the evening (6-8 PM) and in the early morning (6-8 AM). From evening to morning, the cerebrovascular reactivity to hypercapnia was reduced (5.3 +/- 0.6 vs. 4.6 +/- 1.1%/Torr; P < 0.05) and was associated with a reduced increase in cerebral oxygenation (r = 0.39; P < 0.05) and an elevated morning hypercapnic VE response (r = 0.54; P < 0.05). While there were no overnight changes in cerebrovascular reactivity or VE response to hypoxia, there was greater cerebral desaturation for a given Sa(O(2)) in the morning (AM, -0.45 +/- 0.14 vs. PM, -0.35 +/- 0.14%/Sa(O(2)); P < 0.05). Following the 20-s breath hold, in the morning, there was a smaller surge middle cerebral artery velocity and cerebral oxygenation (P < 0.05 vs. PM). These data indicate that normal diurnal changes in the cerebrovascular response to CO(2) influence the hypercapnic ventilatory response as well as the level of cerebral oxygenation during changes in arterial Pco(2); this may be a contributing factor for diurnal changes in breathing stability and the high incidence of stroke in the morning.     

Influence of arterial O2 on the susceptibility to posthyperventilation apnea during sleep.

To investigate the contribution of the peripheral chemoreceptors to the susceptibility to posthyperventilation apnea, we evaluated the time course and magnitude of hypocapnia required to produce apnea at different levels of peripheral chemoreceptor activation produced by exposure to three levels of inspired P(O2). We measured the apneic threshold and the apnea latency in nine normal sleeping subjects in response to augmented breaths during normoxia (room air), hypoxia (arterial O2 saturation = 78-80%), and hyperoxia (inspired O2 fraction = 50-52%). Pressure support mechanical ventilation in the assist mode was employed to introduce a single or multiple numbers of consecutive, sigh-like breaths to cause apnea. The apnea latency was measured from the end inspiration of the first augmented breath to the onset of apnea. It was 12.2 +/- 1.1 s during normoxia, which was similar to the lung-to-ear circulation delay of 11.7 s in these subjects. Hypoxia shortened the apnea latency (6.3 +/- 0.8 s; P < 0.05), whereas hyperoxia prolonged it (71.5 +/- 13.8 s; P < 0.01). The apneic threshold end-tidal P(CO2) (Pet(CO2)) was defined as the Pet(CO2)) at the onset of apnea. During hypoxia, the apneic threshold Pet(CO2) was higher (38.9 +/- 1.7 Torr; P < 0.01) compared with normoxia (35.8 +/- 1.1; Torr); during hyperoxia, it was lower (33.0 +/- 0.8 Torr; P < 0.05). Furthermore, the difference between the eupneic Pet(CO2) and apneic threshold Pet(CO2) was smaller during hypoxia (3.0 +/- 1.0 Torr P < 001) and greater during hyperoxia (10.6 +/- 0.8 Torr; P < 0.05) compared with normoxia (8.0 +/- 0.6 Torr). Correspondingly, the hypocapnic ventilatory response to CO2 below the eupneic Pet(CO2) was increased by hypoxia (3.44 +/- 0.63 l.min(-1).Torr(-1); P < 0.05) and decreased by hyperoxia (0.63 +/- 0.04 l.min(-1).Torr(-1); P < 0.05) compared with normoxia (0.79 +/- 0.05 l.min(-1).Torr(-1)). These findings indicate that posthyperventilation apnea is initiated by the peripheral chemoreceptors and that the varying susceptibility to apnea during hypoxia vs. hyperoxia is influenced by the relative activity of these receptors.     

Hypercapnia and response of cerebral blood flow to hypoxia in newborn lambs

Individual effects of hypoxic hypoxia and hypercapnia on the cerebral circulation are well described, but data on their combined effects are conflicting. We measured the effect of hypoxic hypoxia on cerebral blood flow (CBF) and cerebral O2 consumption during normocapnia (arterial PCO2 = 33 +/- 2 Torr) and during hypercapnia (60 +/- 2 Torr) in seven pentobarbital-anesthetized lambs. Analysis of variance showed that neither the magnitude of the hypoxic CBF response nor cerebral O2 consumption was significantly related to the level of arterial PCO2. To determine whether hypoxic cerebral vasodilation during hypercapnia was restricted by reflex sympathetic stimulation we studied an additional six hypercapnic anesthetized lambs before and after bilateral removal of the superior cervical ganglion. Sympathectomy had no effect on base-line CBF during hypercapnia or on the CBF response to hypoxic hypoxia. We conclude that the effects of hypoxic hypoxia on CBF and cerebral O2 consumption are not significantly altered by moderate hypercapnia in the anesthetized lamb. Furthermore, we found no evidence that hypercapnia results in a reflex increase in sympathetic tone that interferes with the ability of cerebral vessels to dilate during hypoxic hypoxia.     

Venoarterial CO(2) difference during regional ischemic or hypoxic hypoxia.

To test the role of blood flow in tissue hypoxia-related increased veno-arterial PCO(2) difference (DeltaPCO(2)), we decreased O(2) delivery (&Ddot;O(2)) by either decreasing flow [ischemic hypoxia (IH)] or arterial PO(2) [hypoxic hypoxia (HH)] in an in situ, vascularly isolated, innervated dog hindlimb perfused with a pump-membrane oxygenator system. Twelve anesthetized and ventilated dogs were studied, with systemic hemodynamics maintained within normal range. In the IH group (n = 6), hindlimb DO(2) was progressively lowered every 15 min by decreasing pump-controlled flow from 60 to 10 ml. kg(-1). min(-1), with arterial PO(2) constant at 100 Torr. In the HH group (n = 6), hindlimb DO(2) was progressively lowered every 15 min by decreasing PO(2) from 100 to 15 Torr, when flow was constant at 60 ml. kg(-1). min(-1). Limb DO(2), O(2) uptake (VO(2)), and DeltaPCO(2) were obtained every 15 min. Below the critical DO(2), VO(2) decreased, indicating dysoxia, and O(2) extraction ratio (VO(2)/DO(2)) rose continuously and similarly in both groups, reaching a maximal value of approximately 90%. DeltaPCO(2) significantly increased in IH but never differed from baseline in HH. We conclude that absence of increased DeltaPCO(2) does not preclude the presence of tissue dysoxia and that decreased flow is a major determinant in increased DeltaPCO(2).     

Hypercapnic cerebral vascular reactivity is decreased, in humans, during sleep compared with wakefulness.

During wakefulness, increases in the partial pressure of arterial CO(2) result in marked rises in cortical blood flow. However, during stage III-IV, non-rapid eye movement (NREM) sleep, and despite a relative state of hypercapnia, cortical blood flow is reduced compared with wakefulness. In the present study, we tested the hypothesis that, in normal subjects, hypercapnic cerebral vascular reactivity is decreased during stage III-IV NREM sleep compared with wakefulness. A 2-MHz pulsed Doppler ultrasound system was used to measure the left middle cerebral artery velocity (MCAV; cm/s) in 12 healthy individuals while awake and during stage III-IV NREM sleep. The end-tidal Pco(2) (Pet(CO(2))) was elevated during the awake and sleep states by regulating the inspired CO(2) load. The cerebral vascular reactivity to CO(2) was calculated from the relationship between Pet(CO(2)) and MCAV by using linear regression. From wakefulness to sleep, the Pet(CO(2)) increased by 3.4 Torr (P < 0.001) and the MCAV fell by 11.7% (P < 0.001). A marked decrease in cerebral vascular reactivity was noted in all subjects, with an average fall of 70.1% (P = 0.001). This decrease in hypercapnic cerebral vascular reactivity may, at least in part, explain the stage III-IV NREM sleep-related reduction in cortical blood flow.     

No effect of brain blood flow on ventilatory depression during sustained hypoxia

Minute ventilation (VE) during sustained hypoxia is not constant but begins to decline within 10-25 min in adult humans. The decrease in brain tissue PCO2 may be related to this decline in VE, because hypoxia causes an increase in brain blood flow, thus resulting in enhanced clearance of CO2 from the brain tissue. To examine the validity of this hypothesis, we measured VE and arterial and internal jugular venous blood gases simultaneously and repeatedly in 15 healthy male volunteers during progressive and subsequent sustained isocapnic hypoxia (arterial PO2 = 45 Torr) for 20 min. It was assumed that jugular venous PCO2 was an index of brain tissue PCO2. Mean VE declined significantly from the initial (16.5 l/min) to the final phase (14.1 l/min) of sustained hypoxia (P less than 0.05). Compared with the control (50.9 Torr), jugular venous PCO2 significantly decreased to 47.4 Torr at the initial phase of hypoxia but did not differ among the phases of hypoxia (47.2 Torr for the intermediate phase and 47.7 Torr for the final phase). We classified the subjects into two groups by hypoxic ventilatory response during progressive hypoxia at the mean value. The decrease in VE during sustained hypoxia was significant in the low responders (n = 9) [13.2 (initial phase) to 9.3 l/min (final phase of hypoxia), P less than 0.01], but not in the high responders (n = 6) (20.9-21.3 l/min, NS). This finding could not be explained by the change of arterial or jugular venous gases, which did not significantly change during sustained hypoxia in either group.(ABSTRACT TRUNCATED AT 250 WORDS)