Maturational and anesthetic effects on apneic thresholds in lambs

Periods of apnea are relatively common in newborns but rare in older infants. Postnatal changes in the response of the central neural respiratory circuits to afferent inputs may have a role in the age-related incidence of apnea. Therefore we determined the central neural apneic threshold to CO2 and superior laryngeal nerve (SLN) stimulation in halothane-anesthetized newborn (4- to 7-day-old) and older (45- to 56-day-old) lambs. The animals were vagotomized, paralyzed, and mechanically ventilated with hyperoxic gas. Phrenic nerve activity served as a monitor of central respiratory output. The CO2 and SLN apneic thresholds were defined as the arterial PCO2 when phrenic activity began after hyperventilation, and the quantity of current applied to the SLN that abolished phrenic activity, respectively. At equivalent concentrations of halothane, newborn lambs had higher CO2 apneic thresholds (P less than 0.05) and lower SLN apneic thresholds (P less than 0.05) than did older lambs. Increasing concentrations of halothane decreased (P less than 0.05) the SLN apneic threshold and increased (P less than 0.05) the CO2 apneic threshold. Equal incremental changes in halothane concentration induced similar changes in the apneic thresholds of both ages of lambs. The data suggest that with maturation, the central neural respiratory circuits become more responsive to CO2 and less responsive to SLN afferents. Halothane alters central neural responsiveness to these inputs in both ages similarly.     

Measurement of the CO2 apneic threshold in newborn infants: possible relevance for periodic breathing and apnea.

We measured the PCO2 apneic threshold in preterm and term infants. We hypothesized that, compared with adult subjects, the PCO2 apneic threshold in neonates is very close to the eupneic PCO2, likely facilitating the appearance of periodic breathing and apnea. In contrast with adults, who need to be artificially hyperventilated to switch from regular to periodic breathing, neonates do this spontaneously. We therefore measured the apneic threshold as the average alveolar PCO2 (PaCO2) of the last three breaths of regular breathing preceding the first apnea of an epoch of periodic breathing. We also measured the PaCO2 of the first three breaths of regular breathing after the last apnea of the same periodic breathing epoch. In preterm infants, eupneic PaCO2 was 38.6 +/- 1.4 Torr, the preperiodic PaCO2 apneic threshold was 37.3 +/- 1.4 Torr, and the postperiodic PaCO2 was 37.2 +/- 1.4 Torr. In term infants, the eupneic PaCO2 was 39.7 +/- 1.1 Torr, the preperiodic PaCO2 apneic threshold was 38.7 +/- 1.0 Torr, and the postperiodic value was 37.9 +/- 1.2 Torr. This means that the PaCO2 apneic thresholds were 1.3 +/- 0.1 and 1.0 +/- 0.2 Torr below eupneic PaCO2 in preterm and term infants, respectively. The transition from eupneic PaCO2 to PaCO2 apneic threshold preceding periodic breathing was accompanied by a minor and nonsignificant increase in ventilation, primarily related to a slight increase in frequency. The findings suggest that neonates breathe very close to their PCO2 apneic threshold, the overall average eupneic PCO2 being only 1.15 +/- 0.2 Torr (0.95-1.79, 95% confidence interval) above the apneic threshold. This value is much lower than that reported for adult subjects (3.5 +/- 0.4 Torr). We speculate that this closeness of eupneic and apneic PCO2 thresholds confers great vulnerability to the respiratory control system in neonates, because minor oscillations in breathing may bring eupneic PCO2 below threshold, causing apnea.     

Effects of changes in CO2 partial pressure on the sensation of respiratory drive

The purpose of this study was to determine whether a change in respiratory sensation accompanies an increase in CO2 partial pressure (PCO2) in the absence of any changes in the level and pattern of thoracic displacement and respiratory muscle force. Eleven normal subjects were artificially hyperventilated with a positive-pressure mechanical respirator. In separate trials the tidal volume (VT) was set at 10 and 18 ml/kg and the frequency of ventilation (f) was adjusted to maintain the base-line end-tidal PCO2 at approximately 30 Torr. Thereafter, at a constant controlled VT and f, the PCO2 was progressively increased by raising the inspired CO2 concentration. There were no changes in respiratory motor activity as determined from the peak inspiratory airway pressure (Paw) until the PCO2 reached 40.8 +/- 1.0 and 40.1 +/- 1.0 (SE) Torr in the large and small VT trials, respectively. Initially there was no conscious awareness of the change in respiratory activity. Subjects first signaled that ventilatory needs were not being satisfied only after a further increase in PCO2 to 44.7 +/- 1.3 and 42.3 +/- 1.0 (SE) Torr in the large and small VT trials and after the Paw had fallen to 55-60% of the base-line value. The results suggest that changes in respiratory sensation produced by increasing chemical drive are a consequence of increases in respiratory efferent activity, but a direct effect of changes in PCO2 on respiratory sensation cannot be excluded.     

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.     

Triangularis sterni and phrenic nerve responses to progressive brain hypoxia.

Activity of the respiratory muscles that are not normally active during eupnea (genioglossal and abdominal) has been shown to be more vulnerable to hypoxic depression than inspiratory diaphragmatic activity. We hypothesized that respiratory muscles that are active at eupnea would be equally vulnerable to isocapnic progressive brain hypoxia (PBH). Phrenic (PHR) and triangularis sterni nerve (TSN) activity were recorded in anesthetized peripherally chemodenervated vagotomized ventilated cats. Hypercapnia [arterial PCO2 (PaCO2) = 57 +/- 3 (SE) Torr] produced parallel increases in peak PHR and TSN activity. PBH [0.5% CO-40% O2-59.5% N2, arterial O2 content (CaO2) reduced from 13.1 +/- 1.0 to 3.7 +/- 0.3 vol%] resulted in parallel decreases of peak PHR and TSN activity to neural apnea. PBH was continued until PHR gasping ensued (CaO2 = 2.9 +/- 0.2 vol%); TSN activity remained silent during gasping. After 6-12 min of recovery (95% O2-5% CO2; CaO2 = 7.8 +/- 0.8 vol%; PaCO2 = 55 +/- 2 Torr), peak PHR activity was increased to 110 +/- 18% (% of activity at 9% CO2) whereas peak TSN activity was augmented to 269 +/- 89%. The greater augmentation of TSN activity during the recovery period could not be explained solely by hypercapnia. In conclusion, we found that 1) TSN expiratory and PHR inspiratory activities are equally vulnerable to hypoxic depression and 2) recovery from severe hypoxia is characterized by a profound augmentation of TSN expiratory activity.     

Influence of pregnancy on ventilatory and carotid body neural output responsiveness to hypoxia in cats

Pregnancy increases ventilation and ventilatory sensitivity to hypoxia and hypercapnia. To determine the role of the carotid body in the increased hypoxic ventilatory response, we measured ventilation and carotid body neural output (CBNO) during progressive isocapnic hypoxia in 15 anesthetized near-term pregnant cats and 15 nonpregnant females. The pregnant compared with nonpregnant cats had greater room-air ventilation [1.48 +/- 0.24 vs. 0.45 +/- 0.05 (SE) l/min BTPS, P less than 0.01], O2 consumption (29 +/- 2 vs. 19 +/- 1 ml/min STPD, P less than 0.01), and lower end-tidal PCO2 (30 +/- 1 vs. 35 +/- 1 Torr, P less than 0.01). Lower end-tidal CO2 tensions were also observed in seven awake pregnant compared with seven awake nonpregnant cats (28 +/- 1 vs. 31 +/- 1 Torr, P less than 0.05). The ventilatory response to hypoxia as measured by the shape of parameter A was twofold greater (38 +/- 5 vs. 17 +/- 3, P less than 0.01) in the anesthetized pregnant compared with nonpregnant cats, and the CBNO response to hypoxia was also increased twofold (58 +/- 11 vs. 29 +/- 5, P less than 0.05). The increased CBNO response to hypoxia in the pregnant compared with the nonpregnant cats persisted after cutting the carotid sinus nerve while recording from the distal end, indicating that the increased hypoxic sensitivity was not due to descending central neural influences. We concluded that greater carotid body sensitivity to hypoxia contributed to the increased hypoxic ventilatory responsiveness observed in pregnant cats.     

Effect of gender on the development of hypocapnic apnea/hypopnea during NREM sleep.

We hypothesized that a decreased susceptibility to the development of hypocapnic central apnea during non-rapid eye movement (NREM) sleep in women compared with men could be an explanation for the gender difference in the sleep apnea/hypopnea syndrome. We studied eight men (age 25-35 yr) and eight women in the midluteal phase of the menstrual cycle (age 21-43 yr); we repeated studies in six women during the midfollicular phase. Hypocapnia was induced via nasal mechanical ventilation for 3 min, with respiratory frequency matched to eupneic frequency. Tidal volume (VT) was increased between 110 and 200% of eupneic control. Cessation of mechanical ventilation resulted in hypocapnic central apnea or hypopnea, depending on the magnitude of hypocapnia. Nadir minute ventilation in the recovery period was plotted against the change in end-tidal PCO(2) (PET(CO(2))) per trial; minute ventilation was given a value of 0 during central apnea. The apneic threshold was defined as the x-intercept of the linear regression line. In women, induction of a central apnea required an increase in VT to 155 +/- 29% (mean +/- SD) and a reduction of PET(CO(2)) by -4.72 +/- 0.57 Torr. In men, induction of a central apnea required an increase in VT to 142 +/- 13% and a reduction of PET(CO(2)) by -3.54 +/- 0.31 Torr (P = 0.002). There was no difference in the apneic threshold between the follicular and the luteal phase in women. Premenopausal women are less susceptible to hypocapnic disfacilitation during NREM sleep than men. This effect was not explained by progesterone. Preservation of ventilatory motor output during hypocapnia may explain the gender difference in sleep apnea.     

Splanchnic hemodynamics and gut mucosal-arterial PCO(2) gradient during systemic hypocapnia.

The effects of hypocapnia [arterial PCO(2) (Pa(CO(2))) 15 Torr] on splanchnic hemodynamics and gut mucosal-arterial P(CO(2)) were studied in seven anesthetized ventilated dogs. Ileal mucosal and serosal blood flow were estimated by using laser Doppler flowmetry, mucosal PCO(2) was measured continuously by using capnometric recirculating gas tonometry, and serosal surface PO(2) was assessed by using a polarographic electrode. Hypocapnia was induced by removal of dead space and was maintained for 45 min, followed by 45 min of eucapnia. Mean Pa(CO(2)) at baseline was 38.1 +/- 1.1 (SE) Torr and decreased to 13.8 +/- 1.3 Torr after removal of dead space. Cardiac output and portal blood flow decreased significantly with hypocapnia. Similarly, mucosal and serosal blood flow decreased by 15 +/- 4 and by 34 +/- 7%, respectively. Also, an increase in the mucosal-arterial PCO(2) gradient of 10.7 Torr and a reduction in serosal PO(2) of 30 Torr were observed with hypocapnia (P < 0.01 for both). Hypocapnia caused ileal mucosal and serosal hypoperfusion, with redistribution of flow favoring the mucosa, accompanied by increased PCO(2) gradient and diminished serosal PO(2).     

Evidence for pulmonary CO2 chemosensitivity: effects on ventilation

To determine whether there is a pulmonary chemoreceptor for CO2 that influences spontaneous ventilation (VE), we separated the systemic and pulmonary circulations and controlled partial pressure of CO2 (PCO2) independently in each circuit under hyperoxic conditions and measured VE. Dogs were anesthetized with ketamine and maintained with 1% halothane. Systemic venous return was drained from the right atrium and passed through an oxygenator and heat exchanger; blood was returned to the ascending aorta. An identical bypass was established for the pulmonary circulation, draining blood from the left atrium and returning it to the pulmonary artery. The heart was fibrillated; all cannulas were brought through the chest wall; and the median sternotomy was closed. Blood flow through both circuits was maintained at 0.080 l . kg-1 . min-1. Systemic PCO2 (PSCO2) was held constant at three different nonoscillatory levels. At each level, pulmonary PCO2 (PpCO2) was randomly varied between approximately 7 and 85 Torr. With PSCO2 at 43.5 +/- 0.4 Torr, VE increased 2.67 +/- 0.61 l . min-1 as PpCO2 was varied between these limits. With PSCO2 at 63.8 +/- 2.5 Torr, VE increased 3.95 +/- 0.73 l . min-1 over these same limits of PpCO2. With PSCO2 below 25--30 Torr, the dogs were apneic and no longer responded to changes in PpCO2. The effect of PpCO2 on VE was abolished by vagotomy. These results suggest the presence of a CO2 chemoreceptor in the lung that interacts with the nonpulmonary chemoreceptors in the control of VE.     

Hyperventilation, alkalosis, prostaglandins, and pulmonary circulation of the newborn

This study was designed to determine whether the effects of hyperventilation on the pulmonary circulation of the newborn lamb were 1) due to mechanical factors or to respiratory alkalosis; and 2) mediated by prostaglandins. Six control lambs were studied during normal ventilation and during hyperventilation with, and without, decreased carbon dioxide (CO2). Five lambs were given indomethacin and studied similarly. In control lambs, hyperventilation with decreased CO2 decreased pulmonary arterial pressure from 26 +/- 2.2 to 18 +/- 1.0 (SE) Torr (P less than or equal to 0.005) and pulmonary vascular resistance from 0.099 +/- 0.035 to 0.070 +/- 0.011 Torr X kg-1 X min-1 (P less than or equal to 0.015). Hyperventilation with normal CO2 did not affect the pulmonary circulation. Hyperventilation with decreased CO2 increased pulmonary arterial concentrations of 6-ketoprostaglandin F1 alpha, a major metabolite of prostacyclin, in control lambs but not in the indomethacin-treated lambs. However, it affected the pulmonary circulation of the control- and indomethacin-treated lambs similarly. In conclusion, hyperventilation affected the pulmonary circulation by respiratory alkalosis not by mechanical factors and prostaglandins did not mediate its effects.     

Brain hypoxia preferentially stimulates genioglossal EMG responses to CO2

Although the dominant respiratory response to hypoxia is stimulation of breathing via the peripheral chemoreflex, brain hypoxia may inhibit respiration. We studied the effects of two levels of brain hypoxia without carotid body stimulation, produced by inhalation of CO, on ventilatory (VI) and genioglossal (EMGgg) and diaphragmatic (EMGdi) responses to CO2 rebreathing in awake, unanesthetized goats. Neither delta VI/delta PCO2 nor VI at a PCO2 of 60 Torr was significantly different between the three conditions studied (0%, 25%, and 50% carboxyhemoglobin, HbCO). There were also no significant changes in delta EMGdi/delta PCO2 or EMGdi at a PCO2 of 60 Torr during progressive brain hypoxia. In contrast, delta EMGgg/delta PCO2 and EMGgg at a PCO2 of 60 Torr were significantly increased at 50% HbCO compared with either normoxia or 25% HbCO (P less than 0.05). The PCO2 threshold at which inspiratory EMGgg appeared was also decreased at 50% HbCO (45.6 +/- 2.6 Torr) compared with normoxia (55.0 +/- 1.4 Torr, P less than 0.02) or 25% HbCO (53.4 +/- 1.6 Torr, P less than 0.02). We conclude that moderate brain hypoxia (50% HbCO) in awake, unanesthetized animals results in disproportionate augmentation of EMGgg relative to EMGdi during CO2 rebreathing. This finding is most likely due to hypoxic cortical depression with consequent withdrawal of tonic inhibition of hypoglossal inspiratory activity.     

Increased propensity for apnea via dopamine-induced carotid body inhibition in sleeping dogs.

We determined the effects of specific carotid body chemoreceptor inhibition on the propensity for apnea during sleep. We reduced the responsiveness of the carotid body chemoreceptors using intravenous dopamine infusions during non-rapid eye movement sleep in six dogs. Then we quantified the difference in end-tidal Pco(2) (Pet(CO(2))) between eupnea and the apneic threshold, the "CO(2) reserve," by gradually reducing Pet(CO(2)) transiently with pressure support ventilation at progressively increased tidal volume until apnea occurred. Dopamine infusions decreased steady-state eupneic ventilation by 15 +/- 6%, causing a mean CO(2) retention of 3.9 +/- 1.9 mmHg and a brief period of ventilatory instability. The apneic threshold Pet(CO(2)) rose 5.1 +/- 1.9 Torr; thus the CO(2) reserve was narrowed from -3.9 +/- 0.62 Torr in control to -2.7 +/- 0.78 Torr with dopamine. This decrease in the CO(2) reserve with dopamine resulted solely from the 20.5 +/- 11.3% increase in plant gain; the slope of the ventilatory response to CO(2) below eupnea was unchanged from normal. We conclude that specific carotid chemoreceptor inhibition with dopamine increases the propensity for apnea during sleep by narrowing the CO(2) reserve below eupnea. This narrowing is due solely to an increase in plant gain as the slope of the ventilatory response to CO(2) below eupnea was unchanged from normal control. These findings have implications for the role of chemoreceptor inhibition/stimulation in the genesis of apnea and breathing periodicity during sleep.     

PCO(2) in the large intestine of mice, rats, guinea pigs, and dogs and effects of the dietary substrate.

PCO(2) in the lumen and serosa of cecum and colon was measured in rats, guinea pigs, and dogs to examine the relationship between serosal PCO(2) and the incidence of intestinal necrotic lesions after administration of gas-carrier contrast agents in rodents. The effects of the dietary substrate were tested in a group of mice maintained on a diet based on glucose as the only carbohydrate source. The anesthetic used was a fentanyl-fluanison-midazolam mixture (rodents) and pentobarbital (dogs). PCO(2) was measured in vivo and postmortem, and the kinetics of the postmortem serosal PCO(2) [transmural CO(2) flux (J(CO(2)))] was calculated. PCO(2) in the cecal serosa and lumen, respectively, was 64 +/- 4 and 392 +/- 18 Torr in rats, 67 +/- 3 and 276 +/- 17 Torr in guinea pigs, and 73 +/- 6 and 137 +/- 7 Torr in mice on glucose-based diet. In the colon serosa and lumen of dogs, PCO(2) was 30 +/- 6 and 523 +/- 67 Torr, respectively. Serosal PCO(2) increased rapidly after death in rats and slower in guinea pigs and mice, and the slowest change was observed in dogs. Compared with dogs, serosal PCO(2) and J(CO(2)) of rats and guinea pigs were significantly higher. Serosal PCO(2) of guinea pigs was similar to that of rats, whereas the J(CO(2)) of guinea pigs was significantly lower. These data suggest a causal relationship between the ability of the cecal and colonic wall to act as a barrier to CO(2) diffusion and the presence of characteristic gas-carrier contrast agent-induced intestinal lesions in mice and rats and their absence in guinea pigs, dogs, and other species.     

Blood osmolality during in vivo changes of CO2 pressure

In 16 experiments male subjects, age 22.4 +/- 0.5 (SE) yr, inspired CO2 for 15 min (8% end-tidal CO2) or hyperventilated for 30 min (2.5% end-tidal CO2). Osmolality (Osm) and acid-base status of arterialized venous blood were determined at short intervals until 30 min after hypo- and hypercapnia, respectively. During hypocapnia [CO2 partial pressure (PCO2) -2.31 +/- 0.32 kPa (-17.4 Torr), pH + 0.19 units], Osm decreased by 3.9 +/- 0.3 mosmol/kg H2O; during hypercapnia [PCO2 + 2.10 +/- 0.28 kPa (+15.8 Torr), pH -0.12 units], Osm increased by 5.8 +/- 0.7 mosmol/kg H2O. Presentation of the data in Osm-PCO2 or Osm-pH diagrams yields hysteresis loops probably caused by exchange between blood and tissues. The dependence of Osm on PCO2 must result mainly from CO2 buffering and therefore from the formation of bicarbonate. In spite of the different buffer capacities in various body compartments, water exchange allows rapid restoration of osmotic equilibrium throughout the organism. Thus delta Osm/delta pH during a PCO2 jump largely depends on the mean buffer capacity of the whole body. The high estimated buffer value during hypercapnia (38 mmol/kg H2O) compared with hypocapnia (19 mmol/kg H2O) seems to result from very strong muscle buffering during moderate acidosis.     

Respiratory responses to ventilatory loading following low cervical spinal cord injury

This study compared the respiratory responses to ventilatory loading in 8 normal subjects and 11 quadriplegic patients with low cervical spinal cord transection. Progressive hypercapnia was produced by rebreathing. Rebreathing trials were carried out with no added load and with inspiratory resistive loads of 5 and 16 cmH2O. l-1 X s. Measurements were made of ventilation and of diaphragmatic electromyographic activity. Base-line hypercapnic ventilatory responses were significantly lower than normal in the quadriplegic patients, but the effects of resistive loading on the ventilatory responses were comparable in the two groups. The change in peak moving-average diaphragmatic electrical activity (DI peak) for a given change in CO2 partial pressure (PCO2) and DI peak at PCO2 55 Torr increased significantly with resistive loading both in the normal subjects and the quadriplegic patients. In the normal subjects, but not in the quadriplegic patients, inspiratory duration increased progressively with increasing resistance. The increase in DI peak during ventilatory loading in the normal subjects was a consequence of inspiratory prolongation. In contrast, in the quadriplegic patients during breathing against the larger resistive load, there was a significant increase in the average rate of rise (DI peak divided by the time from onset to peak) of diaphragmatic activity. The change in DI rate of rise for a given change in PCO2 increased to 137 +/- 13% (SE), and the DI rate of rise at PCO2 55 Torr increased to 128 +/- 8% (SE) of control values. These results indicate that compensatory increases in diaphragmatic activation during ventilatory loading occur in quadriplegic patients in whom afferent feedback from rib cage receptors is disrupted.     

Exercise responses in pregnant sheep: blood gases, temperatures, and fetal cardiovascular system

In an effort to examine the effects of maternal exercise on the fetus we measured maternal and fetal temperatures and blood gases and calculated uterine O2 consumption in response to three different treadmill exercise regimens in 12 chronically catheterized near-term sheep. We also measured fetal catecholamine concentrations, heart rate, blood pressure, cardiac output, blood flow distribution, blood volume, and placental diffusing capacity. Maternal and fetal temperatures increased a mean maximum of 1.5 +/- 0.5 (SE) and 1.3 +/- 0.1 degrees C, respectively. We corrected maternal and fetal blood gas values for the temperatures in vivo. Maternal arterial partial pressure of O2 (PO2), near exhaustion during prolonged (40 min) exercise at 70% maximal O2 consumption, increased 13% to a maximum of 116.7 +/- 4.0 Torr, whereas partial pressure of CO2 (PCO2) decreased by 28% to 27.6 +/- 2.2 Torr. Fetal arterial PO2 decreased 11% to a minimum of 23.2 +/- 1.6 Torr, O2 content by 26% to 4.3 +/- 0.6 ml X dl -1, PCO2 by 8% to 49.6 +/- 3.2 Torr, but pH did not change significantly. Recovery was virtually complete within 20 min. During exercise total uterine O2 consumption was maintained despite the reduction in uterine blood flow because of hemoconcentration and increased O2 extraction. The decrease of 3 Torr in fetal arterial PO2 and 1.5 ml X dl -1 in O2 content did not result in major cardiovascular changes or catecholamine release. These findings suggest that maternal exercise does not represent a major stressful or hypoxic event to the fetus.     

Upper airway muscle responsiveness to rising PCO(2) during NREM sleep.

Although pharyngeal muscles respond robustly to increasing PCO(2) during wakefulness, the effect of hypercapnia on upper airway muscle activation during sleep has not been carefully assessed. This may be important, because it has been hypothesized that CO(2)-driven muscle activation may importantly stabilize the upper airway during stages 3 and 4 sleep. To test this hypothesis, we measured ventilation, airway resistance, genioglossus (GG) and tensor palatini (TP) electromyogram (EMG), plus end-tidal PCO(2) (PET(CO(2))) in 18 subjects during wakefulness, stage 2, and slow-wave sleep (SWS). Responses of ventilation and muscle EMG to administered CO(2) (PET(CO(2)) = 6 Torr above the eupneic level) were also assessed during SWS (n = 9) or stage 2 sleep (n = 7). PET(CO(2)) increased spontaneously by 0.8 +/- 0.1 Torr from stage 2 to SWS (from 43.3 +/- 0.6 to 44.1 +/- 0.5 Torr, P < 0.05), with no significant change in GG or TP EMG. Despite a significant increase in minute ventilation with induced hypercapnia (from 8.3 +/- 0.1 to 11.9 +/- 0.3 l/min in stage 2 and 8.6 +/- 0.4 to 12.7 +/- 0.4 l/min in SWS, P < 0.05 for both), there was no significant change in the GG or TP EMG. These data indicate that supraphysiological levels of PET(CO(2)) (50.4 +/- 1.6 Torr in stage 2, and 50.4 +/- 0.9 Torr in SWS) are not a major independent stimulus to pharyngeal dilator muscle activation during either SWS or stage 2 sleep. Thus hypercapnia-induced pharyngeal dilator muscle activation alone is unlikely to explain the paucity of sleep-disordered breathing events during SWS.     

Chronic intermittent hypoxia increases the CO2 reserve in sleeping dogs.

We hypothesized that chronic intermittent hypoxia (CIH) would induce a predisposition to apnea in response to induced hypocapnia. To test this, we used pressure support ventilation to quantify the difference in end-tidal partial pressure of CO(2) (Pet(CO(2))) between eupnea and the apneic threshold ("CO(2) reserve") as an index of the propensity for apnea and unstable breathing during sleep, both before and following up to 3-wk exposure to chronic intermittent hypoxia in dogs. CIH consisted of 25 s of Pet(O(2)) = 35-40 Torr followed by 35 s of normoxia, and this pattern was repeated 60 times/h, 7-8 h/day for 3 wk. The CO(2) reserve was determined during non-rapid eye movement sleep in normoxia 14-16 h after the most recent hypoxic exposure. Contrary to our hypothesis, the slope of the ventilatory response to CO(2) below eupnea progressively decreased during CIH (control, 1.36 +/- 0.18; week 2, 0.94 +/- 0.12; week 3, 0.73 +/- 0.05 l.min(-1).Torr(-1), P < 0.05). This resulted in a significant increase in the CO(2) reserve relative to control (P < 0.05) following both 2 and 3 wk of CIH (control, 2.6 +/- 0.6; week 2, 3.7 +/- 0.8; week 3, 4.5 +/- 0.9 Torr). CIH also 1) caused no change in eupneic, air breathing Pa(CO(2)); 2) increased the slope of the ventilatory response to hypercapnia after 2 wk but not after 3 wk compared with control; and 3) had no effect on the ventilatory response to hypoxia. We conclude that 3-wk CIH reduced the sensitivity of the ventilatory response to transient hypocapnia and thereby increased the CO(2) reserve, i.e., the propensity for apnea was reduced.     

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)     

Increased carotid body hypoxic sensitivity during acclimatization to hypobaric hypoxia

Mechanisms of ventilatory acclimatization to chronic hypoxia remain unclear. To determine whether the sensitivity of peripheral chemoreceptors to hypoxia increases during acclimatization, we measured ventilatory and carotid sinus nerve responses to isocapnic hypoxia in seven cats exposed to simulated altitude of 15,000 ft (barometric pressure = 440 Torr) for 48 h. A control group (n = 7) was selected for hypoxic ventilatory responses matched to the preacclimatized measurements of the experimental group. Exposure to 48 h of hypobaric hypoxia produced acclimatization manifested as decrease in end-tidal PCO2 (PETCO2) in normoxia (34.5 +/- 0.9 Torr before, 28.9 +/- 1.2 after the exposure) as well as in hypoxia (28.1 +/- 1.9 Torr before, 21.8 +/- 1.9 after). Acclimatization produced an increase in hypoxic ventilatory response, measured as the shape parameter A (24.9 +/- 2.6 before, 35.2 +/- 5.6 after; P less than 0.05), whereas values in controls remained unchanged (25.7 +/- 3.2 and 23.1 +/- 2.7; NS). Hypoxic exposure was associated with an increase in the carotid body response to hypoxia, similarly measured as the shape parameter A (24.2 +/- 4.7 in control, 44.5 +/- 8.2 in acclimatized cats). We also found an increased dependency of ventilation on carotid body function (PETCO2 increased after unilateral section of carotid sinus nerve in acclimatized but not in control animals). These results suggest that acclimatization is associated with increased hypoxic ventilatory response accompanied by enhanced peripheral chemoreceptor responsiveness, which may contribute to the attendant rise in ventilation.