Role of carotid body activity responsible for hypoxic ventilatory decline in awake humans

Long, W. Q., G. G. Giesbrecht, and N. R. Anthonisen. Ventilatory response to moderate hypoxia in awakechemodenervated cats. J. Appl. Physiol. 74(2): 805-810, 1993.In humans and cats the ventilatory response to 30 min ofmoderate hypoxia (arterial PO₂ 40-55Torr) is biphasic: ventilation increases sharply for the first 5 minand then declines. In humans there is evidence that the decline isdependent on the initial increase. We therefore examined ventilatoryresponses to moderate isocapnic hypoxia in awake cats with and withoutcarotid body denervation. Cats underwent denervation or a shamoperation. Then they were studied in a Drorbaugh-Fenn plethysmographwhile ventilation, arterial PO₂, and end-tidal PO₂ and PCO₂ weremeasured. Three sham-operated and four denervated cats were studiedwith room air as the control. Sham animals demonstrated a biphasicresponse: ventilation rose to 211% of control at 5 min and fell to114% of control at 25 min. Denervated animals showed neither theinitial increase nor the subsequent decrease in ventilation. Threesham-operated and three denervated cats were studied with 2%CO₂ added to the inspirate. Results were similar: intactcats showed a biphasic response to hypoxia, whereas denervated catsshowed neither an increase nor a decrease in ventilation. Preliminaryexperiments showed that hypoxia was not associated with changes inCO₂ output or systemic blood pressure in either denervatedor intact animals. We conclude that depression of ventilation does notoccur in awake denervated cats in response to moderate hypoxiaand that the decline in ventilation that occurs in intact cats is insome way dependent on peripheral chemoreceptor output.

     

Selected contribution: variation in acute hypoxic ventilatory response is linked to mouse chromosome 9.

Genetic determinants confer variation among inbred mouse strains with respect to the magnitude and pattern of breathing during acute hypoxic challenge. Specifically, inheritance patterns derived from C3H/HeJ (C3) and C57BL/6J (B6) parental strains suggest that differences in hypoxic ventilatory response (HVR) are controlled by as few as two genes. The present study demonstrates that at least one genetic determinant is located on mouse chromosome 9. This genotype-phenotype association was established by phenotyping 52 B6C3F2 (F2) offspring for HVR characteristics. A genome-wide screen was performed using microsatellite DNA markers (n = 176) polymorphic between C3 and B6 mice. By computing log-likelihood values (LOD scores), linkage analysis compared marker genotypes with minute ventilation (&Vdot;E), tidal volume (VT), and mean inspiratory flow (VT/TI, where TI is inspiratory time) during acute hypoxic challenge (inspired O2 fraction = 0.10, inspired CO2 fraction = 0.03 in N2). A putative quantitative trait locus (QTL) positioned in the vicinity of D9Mit207 was significantly associated with hypoxic VE (LOD = 4.5), VT (LOD = 4.0), and VT/TI (LOD = 5.1). For each of the three HVR characteristics, the putative QTL explained more than 30% of the phenotypic variation among F(2) offspring. In conclusion, this genetic model of differential HVR characteristics demonstrates that a locus approximately 33 centimorgans from the centromere on mouse chromosome 9 confers a substantial proportion of the variance in VE, VT, and VT/TI during acute hypoxic challenge.     

Potentiation of hypoxic ventilatory response by hyperoxia in the conscious rat: putative role of nitric oxide

In humans, the hypoxic ventilatory response(HVR) is augmented when preceded by a short hyperoxic exposure (Y. Honda, H. Tani, A. Masuda, T. Kobayashi, T. Nishino, H. Kimura, S. Masuyama, and T. Kuriyama. J. Appl.Physiol. 81: 1627-1632, 1996). To examine whetherneuronal nitric oxide synthase (nNOS) is involved in such hyperoxia-induced HVR potentiation, 17 male Sprague-Dawley adult ratsunderwent hypoxic challenges (10%O₂-5%CO₂-balanceN₂) preceded either by 10 min ofroom air (O₂) or of 100%O₂(+O₂). At least 48 h later,similar challenges were performed after the animals received theselective nNOS inhibitor 7-nitroindazole (25 mg/kg ip). InO₂ runs, minute ventilation(E)increased from 121.3 ± 20.5 (SD) ml/min in room air to 191.7 ± 23.8 ml/min in hypoxia (P < 0.01). After +O₂,E increasedfrom 114.1 ± 19.8 ml/min in room air to 218.4 ± 47.0 ml/min inhypoxia (+O₂ vs.O₂:P < 0.005, ANOVA). After7-nitroindazole administration, HVR was not affected in theO₂ treatment group withE increasingfrom 113.7 ± 17.8 ml/min in room air to 185.8 ± 35.0 ml/min inhypoxia (P < 0.01).However, HVR potentiation in+O₂-exposed animals was abolished(111.8 ± 18.0 ml/min in room air to 184.1 ± 35.6 ml/min inhypoxia; +O₂ vs.O₂:P not significant). We conclude that in the conscious rat nNOS activation mediates essential components ofthe HVR potentiation elicited by a previous short hyperoxic exposure.

     

Low acute hypoxic ventilatory response and hypoxic depression in acute altitude sickness

Persons with acute altitude sickness hypoventilate at high altitude compared with persons without symptoms. We hypothesized that their hypoventilation was due to low initial hypoxic ventilatory responsiveness, combined with subsequent blunting of ventilation by hypocapnia and/or prolonged hypoxia. To test this hypothesis, we compared eight subjects with histories of acute altitude sickness with four subjects who had been asymptomatic during prior altitude exposure. At a simulated altitude of 4,800 m, the eight susceptible subjects developed symptoms of altitude sickness and had lower minute ventilations and higher end-tidal PCO2's than the four asymptomatic subjects. In measurements made prior to altitude exposure, ventilatory responsiveness to acute hypoxia was reduced in symptomatic compared to asymptomatic subjects, both when measured under isocapnic and poikolocapnic (no added CO2) conditions. Diminution of the poikilocapnic relative to the isocapnic hypoxic response was similar in the two groups. Ventilation fell, and end-tidal PCO2 rose in both groups during 30 min of steady-state hypoxia relative to values observed acutely. After 4.5 h at 4,800 m, ventilation was lower than values observed acutely at the same arterial O2 saturation. The reduction in ventilation in relation to the hypoxemia present was greater in symptomatic than in asymptomatic persons. Thus the hypoventilation in symptomatic compared to asymptomatic subjects was attributable both to a lower acute hypoxic response and a subsequent greater blunting of ventilation at high altitude.     

Attenuated carotid body hypoxic sensitivity after prolonged hypoxic exposure

Prolonged exposure to hypoxia is accompanied by decreased hypoxic ventilatory response (HVR), but the relative importance of peripheral and central mechanisms of this hypoxic desensitization remain unclear. To determine whether the hypoxic sensitivity of peripheral chemoreceptors decreases during chronic hypoxia, we measured ventilatory and carotid sinus nerve (CSN) responses to isocapnic hypoxia in five cats exposed to simulated altitude of 5,500 m (barometric pressure 375 Torr) for 3-4 wk. Exposure to 3-4 wk of hypobaric hypoxia produced a decrease in HVR, measured as the shape parameter A in cats both awake (from 53.9 +/- 10.1 to 14.8 +/- 1.8; P less than 0.05) and anesthetized (from 50.2 +/- 8.2 to 8.5 +/- 1.8; P less than 0.05). Sustained hypoxic exposure decreased end-tidal CO2 tension (PETCO2, 33.3 +/- 1.2 to 28.1 +/- 1.3 Torr) during room-air breathing in awake cats. To determine whether hypocapnia contributed to the observed depression in HVR, we also measured eucapnic HVR (PETCO2 33.3 +/- 0.9 Torr) and found that HVR after hypoxic exposure remained lower than preexposed value (A = 17.4 +/- 4.2 vs. 53.9 +/- 10.1 in awake cats; P less than 0.05). A control group (n = 5) was selected for hypoxic ventilatory response matched to the baseline measurements of the experimental group. The decreased HVR after hypoxic exposure was associated with a parallel decrease in the carotid body response to hypoxia (A = 20.6 +/- 4.8) compared with that of control cats (A = 46.9 +/- 6.3; P less than 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)     

Augmented hypoxic ventilatory response in men at altitude.

To test the hypothesis that the hypoxic ventilatory response (HVR) of an individual is a constant unaffected by acclimatization, isocapnic 5-min step HVR, as delta VI/delta SaO2 (l.min-1.%-1, where VI is inspired ventilation and SaO2 is arterial O2 saturation), was tested in six normal males at sea level (SL), after 1-5 days at 3,810-m altitude (AL1-3), and three times over 1 wk after altitude exposure (PAL1-3). Equal medullary central ventilatory drive was sought at both altitudes by testing HVR after greater than 15 min of hyperoxia to eliminate possible ambient hypoxic ventilatory depression (HVD), choosing for isocapnia a P'CO2 (end tidal) elevated sufficiently to drive hyperoxic VI to 140 ml.kg-1.min-1. Mean P'CO2 was 45.4 +/- 1.7 Torr at SL and 33.3 +/- 1.8 Torr on AL3, compared with the respective resting control end-tidal PCO2 of 42.3 +/- 2.0 and 30.8 +/- 2.6 Torr. SL HVR of 0.91 +/- 0.38 was unchanged on AL1 (30 +/- 18 h) at 1.04 +/- 0.37 but rose (P less than 0.05) to 1.27 +/- 0.57 on AL2 (3.2 +/- 0.8 days) and 1.46 +/- 0.59 on AL3 (4.8 +/- 0.4 days) and remained high on PAL1 at 1.44 +/- 0.54 and PAL2 at 1.37 +/- 0.78 but not on PAL3 (days 4-7). HVR was independent of test SaO2 (range 60-90%). Hyperoxic HCVR (CO2 response) was increased on AL3 and PAL1. Arterial pH at congruent to 65% SaO2 was 7.378 +/- 0.019 at SL, 7.44 +/- 0.018 on AL2, and 7.412 +/- 0.023 on AL3.(ABSTRACT TRUNCATED AT 250 WORDS)     

Time domains of the hypoxic ventilatory response in ectothermic vertebrates

Over a decade has passed since Powell et al. (Respir Physiol 112:123–134, 1998) described and defined the time domains of the hypoxic ventilatory response (HVR) in adult mammals. These time domains, however, have yet to receive much attention in other vertebrate groups. The initial, acute HVR of fish, amphibians and reptiles serves to minimize the imbalance between oxygen supply and demand. If the hypoxia is sustained, a suite of secondary adjustments occur giving rise to a more long-term balance (acclimatization) that allows the behaviors of normal life. These secondary responses can change over time as a function of the nature of the stimulus (the pattern and intensity of the hypoxic exposure). To add to the complexity of this process, hypoxia can also lead to metabolic suppression (the hypoxic metabolic response) and the magnitude of this is also time dependent. Unlike the original review of Powell et al. (Respir Physiol 112:123–134, 1998) that only considered the HVR in adult animals, we also consider relevant developmental time points where information is available. Finally, in amphibians and reptiles with incompletely divided hearts the magnitude of the ventilatory response will be modulated by hypoxia-induced changes in intra-cardiac shunting that also improve the match between O₂ supply and demand, and these too change in a time-dependent fashion. While the current literature on this topic is reviewed here, it is noted that this area has received little attention. We attempt to redefine time domains in a more ‘holistic’ fashion that better accommodates research on ectotherms. If we are to distinguish between the genetic, developmental and environmental influences underlying the various ventilatory responses to hypoxia, however, we must design future experiments with time domains in mind.     

Intermittent hypoxia augments carotid body and ventilatory response to hypoxia in neonatal rat pups.

Carotid bodies are functionally immature at birth and exhibit poor sensitivity to hypoxia. Previous studies have shown that continuous hypoxia at birth impairs hypoxic sensing at the carotid body. Intermittent hypoxia (IH) is more frequently experienced in neonatal life. Previous studies on adult animals have shown that IH facilitates hypoxic sensing at the carotid bodies. On the basis of these studies, in the present study we tested the hypothesis that neonatal IH facilitates hypoxic sensing of the carotid body and augments ventilatory response to hypoxia. Experiments were performed on 2-day-old rat pups that were exposed to 16 h of IH soon after the birth. The IH paradigm consisted of 15 s of 5% O2 (nadir) followed by 5 min of 21% O2 (9 episodes/h). In one group of experiments (IH and control, n = 6 pups each), sensory activity was recorded from ex vivo carotid bodies, and in the other (IH and control, n = 7 pups each) ventilation was monitored in unanesthetized pups by plethysmography. In control pups, sensory response of the carotid body was weak and was slow in onset (approximately 100 s). In contrast, carotid body sensory response to hypoxia was greater and the time course of the response was faster (approximately 30 s) in IH compared with control pups. The magnitude of the hypoxic ventilatory response was greater in IH compared with control pups, whereas changes in O2 consumption and CO2 production during hypoxia were comparable between both groups. The magnitude of ventilatory stimulation by hyperoxic hypercapnia (7% CO2-balance O2), however, was the same between both groups of pups. These results demonstrate that neonatal IH facilitates carotid body sensory response to hypoxia and augments hypoxic ventilatory chemoreflex.     

Human hypoxic ventilatory response with blood dopamine content under intermittent hypoxic training

Adaptation to intermittent hypoxia can enhance a hypoxic ventilatory response (HVR) in healthy humans. Naturally occurring oscillations in blood dopamine (DA) level may modulate these responses. We have measured ventilatory response to hypoxia relative to blood DA concentration and its precursor DOPA before and after a 2-week course of intermittent hypoxic training (IHT). Eighteen healthy male subjects (mean 22.8+/-2.1 years old) participated in the study. HVRs to isocapnic, progressive, hypoxic rebreathing were recorded and analyzed using piecewise linear approximation. Rebreathing lasted for 5-6 min until inspired O2 reached 8 to 7%. IHT consisted of three identical daily rebreathing sessions separated by 5-min breaks for 14 consecutive days. Before and after the 2-week course of IHT, blood was sampled from the antecubital vein to measure DA and DOPA content. The investigation associated pretraining high blood DA and DOPA values with low HVR (r = -0.66 and -0.75, respectively), elevated tidal volume (r = 0.58 and 0.37) and vital capacity (r = 0.69 and 0.58), and reduced respiratory frequency (r = -0.89 and -0.82). IHT produced no significant change in ventilatory responses to mild hypoxic challenge (Peto2 from 110 to 70-80 mm Hg; 1 mm Hg = 133.3 Pa) but elicited a 96% increase in ventilatory response to severe hypoxia (from 70-80 to 45 mm Hg). Changes in HVRs were not accompanied by statistically significant shifts in blood DA content (24% change), although a twofold increase in DOPA concentration was observed. Individual subject's changes in DA and DOPA content were not correlated with HVR changes when these two parameters were evaluated in relation to the IHT. We hypothesize that DA flowing to the carotid body through the blood may provoke DA autoreceptor-mediated inhibition of endogenous DA synthesis-release, as shown in our baseline data.     

Effect of brain blood flow on hypoxic ventilatory response in humans

To assess the effect of brain blood flow on hypoxic ventilatory response, we measured arterial and internal jugular venous blood gases and ventilation simultaneously and repeatedly in eight healthy male humans in two settings: 1) progressive and subsequent sustained hypoxia, and 2) stepwise and progressive hypercapnia. Ventilatory response to progressive isocapnic hypoxia [arterial O2 partial pressure 155.9 +/- 4.0 (SE) to 46.7 +/- 1.5 Torr] was expressed as change in minute ventilation per change in arterial O2 saturation and varied from -0.16 to -1.88 [0.67 +/- 0.19 (SE)] l/min per % among subjects. In the meanwhile, jugular venous PCO2 (PjCO2) decreased significantly from 51.0 +/- 1.1 to 47.3 +/- 1.0 Torr (P less than 0.01), probably due to the increase in brain blood flow, and stayed at the same level during 15 min of sustained hypoxia. Based on the assumption that PjCO2 reflects the brain tissue PCO2, we evaluated the depressant effect of fall in PjCO2 on hypoxic ventilatory response, using a slope for ventilation-PjCO2 line which was determined in the second set of experiments. Hypoxic ventilatory response corrected with this factor was -1.31 +/- 0.33 l/min per %, indicating that this factor modulated hypoxic ventilatory response in humans. The ventilatory response to progressive isocapnic hypoxia did not correlate with this factor but significantly correlated with the withdrawal test (modified transient O2 test), which was performed on a separate day. Accordingly we conclude that an increase in brain blood flow during exposure to moderate hypoxia may substantially attenuate the ventilatory response but that it is unlikely to be the major factor of the interindividual variation of progressive isocapnic hypoxic ventilatory response in humans.     

The acute hypoxic ventilatory response: testing the adaptive significance in human populations

The acute Hypoxic Ventilatory Response (HVR) is an important component of human hypoxia tolerance, hence presumably physiological adaptation to high altitude. We measured the isocapnic HVR (L min(-1) %(-1)) in two genetically divergent low altitude southern African populations. The HVR does not differ between African Xhosas (X) and Caucasians (C) (X:-0.34+/-0.36; C:-0.42+/-0.33; P > 0.34), but breathing patterns do. Among all Xhosa subjects, size-independent tidal volume was smaller (X: 0.75+/-0.20; C: 1.11+/-0.32 L; P < 0.01), breathing frequency higher (X: 22.2+/-5.7; C: 14.3+/-4.2 breaths min(-1); P < 0.01) and hypoxic oxygen saturation lower than among Caucasians (X: 78.4+/-4.7%; C: 81.7+/-4.7%; P < 0.05). The results remained significant if subjects from Xhosa and Caucasian groups were matched for gender, body mass index and menstrual cycle phase in the case of females. The latter also employed distinct breathing patterns between populations in normoxia. High repeatability (intra-class correlation coefficient) of the HVR in both populations (0.77-0.87) demonstrates that one of the prerequisites for natural selection, consistent between-individual variation, is met. Finally, we explore possible relationships between inter-population genetic distances and HVR differences among Xhosa, European, Aymara Amerindians, Tibetan and Chinese populations. Inter-population differences in the HVR are not attributable to genetic distance (Mantel Z-test, P = 0.59). The results of this study add novel support for the hypothesis that differences in the HVR, should they be found between other human populations, may reflect adaptation to hypoxia rather than genetic divergence through time.     

Effects of carotid body hypocapnia during ventilatory acclimatization to hypoxia

Dwinell, M. R., P. L. Janssen, J. Pizarro, and G. E. Bisgard. Effects of carotid body hypocapnia during ventilatory acclimatization to hypoxia. J. Appl.Physiol. 82(1): 118-124, 1997.Hypoxicventilatory sensitivity is increased during ventilatory acclimatizationto hypoxia (VAH) in awake goats, resulting in a time-dependent increasein expired ventilation (E). Theobjectives of this study were to determine whether the increasedcarotid body (CB) hypoxic sensitivity is dependent on the level of CB CO₂ and whether the CBCO₂ gain is changed during VAH.Studies were carried out in adult goats with CB blood gases controlled by an extracorporeal circuit while systemic (central nervous system) blood gases were regulated independently by the level of inhaled gases. Acute E responsesto CB hypoxia (CB PO₂ 40 Torr) and CBhypercapnia (CB PCO₂ 50 and 60 Torr)were measured while systemic normoxia and isocapnia were maintained. CBPO₂ was then lowered to 40 Torr for 4 h while the systemic blood gases were kept normoxic and normocapnic.During the 4-h CB hypoxia, E increasedin a time-dependent manner. Thirty minutes after return to normoxia,the ventilatory response to CB hypoxia was significantly increasedcompared with the initial response. The slope of the CBCO₂ response was also elevatedafter VAH. An additional group of goats(n = 7) was studied with asimilar protocol, except that CB PCO₂was lowered throughout the 4-h hypoxic exposure to prevent reflexhyperventilation. CB PCO₂ wasprogressively lowered throughout the 4-h CB hypoxic period to maintainE at the control level. After the 4-hCB hypoxic exposure, the ventilatory response to hypoxia was alsosignificantly elevated. However, the slope of the CBCO₂ response was not elevatedafter the 4-h hypoxic exposure. These results suggest that CBsensitivity to both O₂ andCO₂ is increased after 4 h of CBhypoxia with systemic isocapnia. The increase in CB hypoxic sensitivityis not dependent on the level of CBCO₂ maintained during the 4-hhypoxic period.

     

Role of endogenous opiates in hypoxic ventilatory response in the newborn primate

The effects of opiate receptor antagonism by naltrexone hydrochloride on the biphasic hypoxic ventilatory response in the infant Macaca nemestrina have been investigated. Minute ventilation, tidal volume, and respiratory frequency were measured in six animals from timed gestations before and during inhalation of a hypoxic gas mixture. All studies were completed in non-rapid-eye-movement sleep. Arterial blood gases were obtained during each stimulus period. All animals demonstrated the typical biphasic ventilatory response to acute moderate-severe hypoxemia. After the administration of naltrexone hydrochloride to block opiate receptors, the animals still manifested a biphasic hypoxic response that was no different than that noted prior to drug administration. Naltrexone hydrochloride had no effect on room air resting ventilation in any of the animals. Our data suggest that endogenous opiates play no physiological role in the acute ventilatory response to moderate-severe hypoxia in the newborn subhuman primate.