Influence of adenosine A(1)-receptor blockade and vagotomy on the gasping and heart rate response to hypoxia in rats during early postnatal maturation.

Failure to autoresuscitate from apnea has been suggested to play a role in sudden infant death. Little is known, however, about factors that influence the gasping and heart rate response to severe hypoxia that are fundamental to successful autoresuscitation in the newborn. The present experiments were carried out on 184 rat pups to investigate the influence of the parasympathetic nervous system, as well as adenosine, in mediating the profound bradycardia that occurs with the onset of hypoxic-induced primary apnea and in modulating hypoxic gasping. On days 1 to 2, days 5 to 6, and days 10 to 11 postpartum and following bilateral cervical vagotomy (VAG) or administration of a selective adenosine A(1) receptor antagonist (8-cyclopentyl-1,3-dipropylxanthine; DPCPX), each pup was exposed to a single period of severe hypoxia produced by breathing an anoxic gas mixture (97% N(2)-3% CO(2)). Exposure to severe hypoxia resulted in an age-dependent decrease in heart rate (P < 0.001), accentuated with increasing postnatal age, that was attenuated in all age groups by DPCPX but not by VAG. Furthermore, DPCPX but not VAG decreased the time to last gasp but increased the total number of gasps in the 1- to 2-day-old and 5- to 6-day-old pups but not in the 10- to 11-day-old pups during exposure to severe hypoxia. Thus our data provide evidence that adenosine acting via adenosine A(1) receptors plays a role in modulating hypoxic gasping and in mediating the profound bradycardia that occurs coincident with hypoxic-induced primary apnea in rats during early postnatal life.     

Threshold levels of maternal nicotine impairing protective responses of newborn rats to intermittent hypoxia.

Experiments were carried out to determine the threshold level of maternal nicotine that impairs protective responses of rat pups to hypoxia. From days 6 or 7 of gestation, pregnant rats received either vehicle or nicotine (1.50, 3.00, or 6.00 mg of nicotine tartrate. kg body wt(-1).day(-1)) or vehicle continuously via a subcutaneous osmotic minipump. On postnatal days 5 or 6, pups were exposed to a single period of hypoxia produced by breathing an anoxic gas mixture (97% N(2) or 3% CO(2)) and their time to last gasp was determined, or they were exposed to intermittent hypoxia and their ability to autoresuscitate from hypoxic-induced primary apnea was determined. Perinatal exposure to nicotine did not alter the time to last gasp or the total number of gasps when the pups were exposed to a single period of hypoxia. The number of successful autoresuscitations on repeated exposure to hypoxia was, however, decreased in pups whose dams had received either 3.00 or 6.00 mg of nicotine tartrate/kg body wt; these dosage regimens produced maternal serum nicotine concentrations of 19 +/- 6 and 35 +/- 8 ng/ml, respectively. Thus our experiments define the threshold level of maternal nicotine that significantly impairs protective responses of 5- to 6-day-old rat pups to intermittent hypoxia such as may occur in human infants during episodes of prolonged sleep apnea or positional asphyxia.     

Inhibitory effects of hyperthermia on mechanisms involved in autoresuscitation from hypoxic apnea in mice: a model for thermal stress causing SIDS.

The physiological mechanisms that might be involved in an association between heat stress and sudden infant death syndrome (SIDS) are obscure. We tested the hypothesis that a combination of acute hypoxia and elevated body temperature (T(B)) might prevent autoresuscitation from hypoxic apnea (AR). We exposed 21-day-old mice (total = 216) to hyperthermia (40.5-43.5 degrees C), hypoxia, or a combination of the two. Neither hyperthermia alone (40.5-42.5 degrees C) nor hypoxia alone was found to be lethal, but the combination produced failure to AR during the first hypoxic exposure with increasing frequency as T(B) increased. The ability to withstand multiple hypoxic exposures was also reduced as T(B) increased. In contrast, heat stress causing moderate T(B) increase (40.5 degrees C) had no effect on survival. Increased T(B) (43.5 degrees C) reduced gasping duration and number of gasps. It increased heart rate during anoxia but did not alter gasping rate. Furthermore, the oxygen-independent increase in heart rate observed before gasping failure was usually delayed until after the last gasp in hyperthermic animals. Mild dehydration occurred during T(B) elevation, but this did not appear to be a primary factor in AR failure. We conclude that a thermal stress, which by itself is nonlethal, frequently prevents AR from hypoxic apnea. This may be due, at least in part, to decreased gasp number and duration as well as to hyperthermia-related asynchrony of reflexes regulating heart and gasping frequencies during attempted AR.     

Gasping and autoresuscitation in the developing rat: effect of antecedent intermittent hypoxia.

Gasping is a critically important mechanism for autoresuscitation and survival during extreme tissue hypoxia. Evidence of antecedent hypoxia in sudden infant death syndrome suggests that intermittently occurring hypoxic episodes may modify gasping and autoresuscitation. To examine this issue, an intermittent hypoxia (IH) profile consisting of alternating room air and 10% O(2)-balance N(2) every 90 s was applied to pregnant Sprague-Dawley rats (IHRA; n = 50) and to pups after a normal pregnancy (RAIH; n = 50) as well as to control pups (RARA; n = 50). At postnatal day 5, pups were exposed to 95% N(2)-5% CO(2), and gasping and the ability to autoresuscitate were assessed. Compared with RARA, IHRA- and RAIH-exposed pups had a reduced number of gasps, decreased overall gasp duration, and were less likely to autoresuscitate on introduction of room air to the breathing mixture during the last phase of gasping (P < 0.001 vs. RARA). We conclude that both prenatal and early postnatal IH adversely affect gasping and related survival mechanisms.     

Postnatal age influences the ability of rats to autoresuscitate from hypoxic-induced apnea

Failure to autoresuscitate from apnea by gasping has been suggested to have a role in sudden infant death. Little is known, however, about the factors that influence the ability of gasping to sustain life during acute hypoxia in the newborn. The present experiments were carried out on 105 rat pups to investigate the influence of postnatal age on the time to last gasp during a single hypoxic exposure and on the ability to autoresuscitate from primary apnea during repeated hypoxic exposures. On days 1-2, 5-6, 10-11, 15-16, and 19-20 postpartum, each pup was placed into a temperature-controlled chamber regulated to 37 +/- 1 degrees C and was exposed either to a single period of hypoxia produced by breathing an anoxic gas mixture (97% N(2)-3% CO(2)), and the time to last gasp was determined, or repeated exposure to hypoxia was performed, and the ability to autoresuscitate from primary apnea was determined. Increases in postnatal age decreased the time to last gasp following a single hypoxic exposure and decreased the number of successful autoresuscitations following repeated hypoxic exposures. Thus our data provide evidence that postnatal age influences protective responses that may prevent death during hypoxia as may occur during episodes of prolonged sleep apnea.     

Influence of core temperature on autoresuscitation during repeated exposure to hypoxia in normal rat pups.

Failure to autoresuscitate by hypoxic gasping during prolonged sleep apnea has been suggested to play a role in sudden infant death. Furthermore, thermal stress brought about by a contribution of infection, overwrapping, or excessive environmental heating has been shown to be associated with an increased risk of sudden infant death, particularly in prone sleeping infants. The present experiments were carried out on newborn rat pups to investigate the influence of "forced" changes in core temperature on their time to last gasp during a single hypoxic exposure and on their ability to autoresuscitate during repeated exposure to hypoxia. On day 5 or 6 postpartum the pups were placed in a temperature-controlled chamber regulated to 33, 35, 37, 39, or 41 degrees C and exposed to a single period of hypoxia (97% N(2)-3% CO(2)) and their time to last gasp was determined, or they were exposed repeatedly to hypoxia and their ability to autoresuscitate from primary apnea was determined. Increases in core temperature brought about by changes in ambient temperature from 33 to 41 degrees C decreased the time to last gasp after a single hypoxic exposure and decreased the number of successful autoresuscitations after repeated hypoxic exposures. Thus our data support the hypothesis that forced changes in core temperature brought about by changes in ambient temperature influence protective responses in newborns that may prevent death during hypoxia, as may occur during single or repeated episodes of prolonged sleep apnea.     

Mechanisms underlying induced autoresuscitation failure in BALB/c and SWR mice.

Mechanisms underlying failure of autoresuscitation from hypoxic apnea were investigated. Failure was induced by repeated exposure to hypoxia. The influence of maturation was studied in adults, weanlings, and 10- and 5-day-old mice. Mice successful at autoresuscitation (BALB/c) as well as those prone to autoresuscitation failure (SWR weanlings) were studied. Hypoxic apnea was induced with 97% N2-3% CO2, and 21% O2 was given at its onset; electrocardiogram and ventilation were recorded. Hypoxic exposure was repeated if autoresuscitation (recovery of eupnea) occurred. Autoresuscitation failure (death) was induced in all mice. Young BALB/c mice tolerated more trials than older mice. SWR weanlings frequently failed to autoresuscitate on the initial exposure and tolerated fewer repeat trials overall than age-matched BALB/c mice. Induced autoresuscitation failure in all mice appeared to be unrelated to gasping regulation, because both gasp number and amplitude were similar during the failed trial and the previous successful trial. In most mice, failure was associated with absent recovery of heart rate during gasping. In BALB/c mice in particular, this persistent bradycardia was usually due to heart block, which occurred in 95% of failed trials. In addition, heart block occurred with increasing frequency on later successful trials, but conversion to sinus rhythm always preceded successful autoresuscitation. Heart block was also frequent in SWR mice and had similar consequences. BALB/c mice exposed to continuous anoxia survived longer than SWR mice, indicating increased endurance of components of the autoresuscitation mechanism not directly related to the ventilatory function of gasping (e.g., cardiovascular components).(ABSTRACT TRUNCATED AT 250 WORDS)     

Perinatal nicotine exposure impairs ability of newborn rats to autoresuscitate from apnea during hypoxia

Failure toautoresuscitate by hypoxic gasping during prolonged sleep apnea hasbeen suggested to play a role in sudden infant death. Furthermore,maternal smoking has been repeatedly shown to be a risk factor forsudden infant death. The present experiments were carried out onnewborn rat pups to investigate the influence of perinatal exposure tonicotine (the primary pharmacological and addictive agent in tobacco)on their time to last gasp during a single hypoxic exposure and ontheir ability to autoresuscitate during repeated exposure to hypoxia.Pregnant rats received either nicotine (6 mg · kg¹ · 24 h¹) or vehiclecontinuously from day 6 of gestationto days 5 or 6 postpartum via an osmotic minipump.On days 5 or6 postpartum, pups were exposed eitherto a single period of hypoxia (97%N₂-3% CO₂) and their time to last gaspwas determined, or they were exposed repeatedly to hypoxia and theirability to autoresuscitate from primary apnea was determined. Perinatalexposure to nicotine did not alter the time to last gasp, but it didimpair the ability of pups to autoresuscitate from primary apnea. Aftervehicle, the pups were able to autoresuscitate from 18 ± 1 (SD)periods of hypoxia, whereas, after nicotine, the pups were able toautoresuscitate from only 12 ± 2 periods(P < 0.001) of hypoxia. Thus ourdata provide evidence that perinatal exposure to nicotine impairs the ability of newborn rats to autoresuscitate from primary apnea duringrepeated exposure to hypoxia, such as may occur during episodes ofprolonged sleep apnea.

     

Ionotropic excitatory amino acid receptors in pre-Botzinger complex play a modulatory role in hypoxia-induced gasping in vivo.

Activation of ionotropic excitatory amino acid (EAA) receptors in pre-B?tzinger complex (pre-B?tC) not only influences the eupneic pattern of phrenic motor output but also modifies hypoxia-induced gasping in vivo by increasing gasp frequency. Although ionotropic EAA receptor activation in this region appears to be required for the generation of eupneic breathing, it remains to be determined whether similar activation is necessary for the production and/or expression of hypoxia-induced gasping. Therefore, we examined the effects of severe brain hypoxia before and after blockade of ionotropic EAA receptors in the pre-B?tC in eight chloralose-anesthetized, deafferented, mechanically ventilated cats. In each experiment, before blockade of ionotropic EAA receptors in the pre-B?tC, severe brain hypoxia (6% O2 in a balance of N2 for 3-6 min) produced gasping. Although bilateral microinjection of the broad-spectrum ionotropic EAA receptor antagonist kynurenic acid (20-100 mM; 40 nl) into the pre-B?tC eliminated basal phrenic nerve discharge, severe brain hypoxia still produced gasping. Under these conditions, however, the onset latency to gasping was increased (P < 0.05), the number of gasps was reduced for the same duration of hypoxic gas exposure (P < 0.05), the duration of gasps was prolonged (P < 0.05), and the duration between gasps was increased (P < 0.05). These findings demonstrate that hypoxia-induced gasping in vivo does not require activation of ionotropic EAA receptors in the pre-B?tC, but ionotropic EAA receptor activation in this region may modify the expression of the hypoxia-induced response. The present findings also provide additional support for the pre-B?tC as the primary locus of respiratory rhythm generation.     

The process of cardiorespiratory autoresuscitation in intact newborn rats

To examine the process of spontaneous autoresuscitation and the recovery of the hypoxic ventilatory response (HVR) after prolonged anoxia, we monitored respiratory frequency (f, by body plethysmography) and heart rate (HR, by ECG) in intact newborn rats (n = 12, day 2-4) before, during, and after 100% N2 exposure. The rat before anoxia showed signs of HVR: f changes at acute hypoxia (10% O2) and hyperoxia (100% O2). During anoxia, the spontaneous respiratory movement "gasping" appeared for 21 min (mean). At O2 restoration (with 100% O2), gasping stopped and no respiratory flow was detected for 1 min. One rat failed to autoresuscitate and had heart arrhythmia during the transient apnea, but 11 rats recovered respiration after the HR acceleration. Despite the successful autoresuscitation, the rats did not show HVR at 10 min into the recovery period and the recovery of HVR required more than 30 min. The results indicate that O2 inhalation is useful to trigger autoresuscitation even when the rat has already been in a state of profound hypoxic depression, but the rat becomes transiently insensitive to HVR after autoresuscitation. We estimate that reform of the respiratory control system in newborn rats is not yet firmly established to track HVR early in the recovery phase after prolonged anoxia.     

Autoresuscitation: a survival mechanism in piglets.

Piglets were studied to determine 1) the cardiovascular and neurophysiological effects of prolonged laryngeal-induced respiratory inhibition (n = 7) and 2) whether these effects were modulated by autonomic blockade (n = 6). Respiration, electrocardiogram, electroencephalogram (EEG), and blood pressure were recorded, and blood gases were measured. During continuous laryngeal stimulation in the presence of light anesthesia, apnea was interrupted every 1-2.5 min by clusters of two to six breaths. Compared with control, these breaths had a significantly greater tidal volume (430 +/- 30% of control), shorter inspiratory time (87 +/- 5%), and longer expiratory time (124 +/- 15%) and, thus, were of a gasping nature. With each cluster of gasps, arterial PO2 increased from 15 +/- 2 to 56 +/- 5 Torr, heart rate from 84 +/- 7 to 161 +/- 5 beats/min, and mean blood pressure from 48 +/- 4 to 106 +/- 6 mmHg. The EEG became flat by 1 min after the onset of apnea and remained isoelectric throughout the stimulus period. Cyclical gasps were not affected by sympathetic or parasympathetic blockade. These data show that, despite EEG silence, piglets can autoresuscitate by initiating gasps that are not dependent on autonomic integrity. These gasps markedly improve cardiovascular status and may sustain animals for a prolonged period of time.     

Unique spectral peak in phrenic nerve activity characterizes gasps in decerebrate cats

The respiratory pattern of gasping has been characterized on the phrenic nerve as rapidonset, rapid-rise, large-amplitude bursts of neural activity. Furthermore, medullary sites critical for the neurogenesis of gasping have been identified and are not the sites of identified respiratory neurons, such as the dorsal and ventral respiratory groups. I classified envelopes of phrenic nerve activity as eupneic breaths, or gasps based on the time-domain features of duration, shape, and amplitude. Gasps were elicited by hypoxia and low blood pressure in 9 of 12 decerebrate cats. Inspiratory times were 1.15 +/- 0.43 (SD) for eupneic breaths and 0.55 +/- 0.18s for gasps. The high-frequency peaks in the power spectra of phrenic nerve activity were at 80 +/- 13 Hz for eupneic breaths and at 120 +/- 21 Hz for gasps. Three of the 12 cats developed a breathing pattern that began as a normal breath and terminated in a gasp. Power spectra of the normal portion had eupneic spectral peaks (75 +/- 24 Hz); power spectra of the gasp portion had the high peaks at 110 +/- 23 Hz, a value 1.5 times higher than that for the normal peaks. Although this analysis of peripheral nerve activity cannot distinguish between two central pattern generators at two distinct anatomical sites or one pattern generator operating in two distinct modes, the fact that gasps were much shorter in duration and had markedly higher spectral peaks than control breaths supports the idea that the central pattern generator for gasping is not the central pattern generator for eupnea.     

Role of adenosine in hypoxic ventilatory depression

The role of adenosine in the ventilatory depression induced by hypoxia was studied in 82 spontaneously breathing urethan-anesthetized 4-day-old rabbit pups. Respiration was monitored with a pneumotachograph. The animals were exposed to hypoxia (6% O2 in N2) for 30 min or until the occurrence of terminal apnea. In all animals hypoxia produced an initial increase in ventilation followed by a decrease. In the control group 52% of the animals became apneic after 7 min of hypoxic exposure. By contrast, pretreatment with dipyridamole (10 or 20 mg/kg), an adenosine uptake blocker, significantly shortened the time needed to reach apnea. Thus at 7 min of hypoxia 93% of the animals that received dipyridamole became apneic. On the other hand, administration of adenosine antagonists 8-p-sulfophenyltheophylline (5 or 8 mg/kg) and aminophylline (10 or 25 mg/kg) significantly prolonged the time required to produce apnea. Only 20% of the animals that received these antagonists became apneic at 7 min of hypoxia. These results suggest that adenosine is potentially involved in the ventilatory depression produced by hypoxia in neonatal rabbit pups.     

Mechanism of failure of recovery from hypoxic apnea by gasping in 17- to 23-day-old mice.

The mechanism of failure of autoresuscitation from hypoxic apnea in 17- to 23-day-old (weanling) Swiss Webster related/J mice was investigated by recording electrocardiogram (ECG) and ventilation in adult, weanling, and 11-day-old mice. Hypoxic apnea was induced with 97% N2-3% CO2. O2 (21% or 50% O2) or 97% N2-3% CO2 was given at the onset of apnea. The ECG showed no arrhythmias predictive of failure of autoresuscitation. The first indication of failure was a progressive fall in gasp volume ("run down"). This pattern also occurred in animals given continuous 97% N2-3% CO2 and was significantly different from that in mice that survived. Gasping duration in 97% N2 was longer in weanlings than adults but shorter than in 11 day olds. Respiratory and heart rate recovery were more rapid in adults than in weanlings. Although recovery in high O2 was more rapid, the survival rate was not increased. The lack of effect of high O2 on survival and the virtually identical pattern of gasping in mice dying in 97% N2 and air leads us to conclude that in mice that fail to autoresuscitate little or no O2 reaches the medullary respiratory centers. We speculate that this may be due to increased vulnerability of cardiac muscle to anoxia in 17- to 23-day-old mice, resulting in early and severe heart failure.     

Hypoxia-mediated prolonged elevation of sympathetic nerve activity after periods of intermittent hypoxic apnea.

Obstructive sleep apnea (OSA) is associated with transient elevation of muscle sympathetic nerve activity (MSNA) during apneic events, which often produces elevated daytime MSNA in OSA patients. Hypoxia is postulated to be the primary stimulus for elevated daytime MSNA in OSA patients. Therefore, we studied the effects of 20 min of intermittent voluntary hypoxic apneas on MSNA during 180 min of recovery. Also, we compared MSNA during recovery after either 20 min of intermittent voluntary hypoxic apneas, hypercapnic hypoxia, or isocapnic hypoxia. Consistent with our hypothesis, both total MSNA and MSNA burst frequency were elevated after 20 min of intermittent hypoxic apnea compared with baseline (P < 0.05). Both total MSNA and MSNA burst frequency remained elevated throughout the 180-min recovery period and were statistically different from time control subjects throughout this period (P < 0.05). Finally, MSNA during recovery from intermittent hypoxic apnea, hypercapnic hypoxia, and isocapnic hypoxia were not different (P = 0.50). Therefore, these data support the hypothesis that short-term exposure to intermittent hypoxic apnea results in sustained elevation of MSNA and that hypoxia is the primary mediator of this response.     

Short-term intermittent hypoxia enhances sympathetic responses to continuous hypoxia in humans.

Short-term intermittent hypoxia leads to sustained sympathetic activation and a small increase in blood pressure in healthy humans. Because obstructive sleep apnea, a condition associated with intermittent hypoxia, is accompanied by elevated sympathetic activity and enhanced sympathetic chemoreflex responses to acute hypoxia, we sought to determine whether intermittent hypoxia also enhances chemoreflex activity in healthy humans. To this end, we measured the responses of muscle sympathetic nerve activity (MSNA, peroneal microneurography) to arterial chemoreflex stimulation and deactivation before and following exposure to a paradigm of repetitive hypoxic apnea (20 s/min for 30 min; O(2) saturation nadir 81.4 +/- 0.9%). Compared with baseline, repetitive hypoxic apnea increased MSNA from 113 +/- 11 to 159 +/- 21 units/min (P = 0.001) and mean blood pressure from 92.1 +/- 2.9 to 95.5 +/- 2.9 mmHg (P = 0.01; n = 19). Furthermore, compared with before, following intermittent hypoxia the MSNA (units/min) responses to acute hypoxia [fraction of inspired O(2) (Fi(O(2))) 0.1, for 5 min] were enhanced (pre- vs. post-intermittent hypoxia: +16 +/- 4 vs. +49 +/- 10%; P = 0.02; n = 11), whereas the responses to hyperoxia (Fi(O(2)) 0.5, for 5 min) were not changed significantly (P = NS; n = 8). Thus 30 min of intermittent hypoxia is capable of increasing sympathetic activity and sensitizing the sympathetic reflex responses to hypoxia in normal humans. Enhanced sympathetic chemoreflex activity induced by intermittent hypoxia may contribute to altered neurocirculatory control and adverse cardiovascular consequences in sleep apnea.     

Determinants of poststimulus potentiation in humans during NREM sleep.

To test whether active hyperventilation activates the "afterdischarge" mechanism during non-rapid-eye-movement (NREM) sleep, we investigated the effect of abrupt termination of active hypoxia-induced hyperventilation in normal subjects during NREM sleep. Hypoxia was induced for 15 s, 30 s, 1 min, and 5 min. The last two durations were studied under both isocapnic and hypocapnic conditions. Hypoxia was abruptly terminated with 100% inspiratory O2 fraction. Several room air-to-hyperoxia transitions were performed to establish a control period for hyperoxia after hypoxia transitions. Transient hyperoxia alone was associated with decreased expired ventilation (VE) to 90 +/- 7% of room air. Hyperoxic termination of 1 min of isocapnic hypoxia [end-tidal PO2 (PETO2) 63 +/- 3 Torr] was associated with VE persistently above the hyperoxic control for four to six breaths. In contrast, termination of 30 s or 1 min of hypocapnic hypoxia [PETO2 49 +/- 3 and 48 +/- 2 Torr, respectively; end-tidal PCO2 (PETCO2) decreased by 2.5 or 3.8 Torr, respectively] resulted in hypoventilation for 45 s and prolongation of expiratory duration (TE) for 18 s. Termination of 5 min of isocapnic hypoxia (PETO2 63 +/- 3 Torr) was associated with central apnea (longest TE 200% of room air); VE remained below the hyperoxic control for 49 s. Termination of 5 min of hypocapnic hypoxia (PETO2 64 +/- 4 Torr, PETCO2 decreased by 2.6 Torr) was also associated with central apnea (longest TE 500% of room air). VE remained below the hyperoxic control for 88 s. We conclude that 1) poststimulus hyperpnea occurs in NREM sleep as long as hypoxia is brief and arterial PCO2 is maintained, suggesting the activation of the afterdischarge mechanism; 2) transient hypocapnia overrides the potentiating effects of afterdischarge, resulting in hypoventilation; and 3) sustained hypoxia abolishes the potentiating effects of after-discharge, resulting in central apnea. These data suggest that the inhibitory effects of sustained hypoxia and hypocapnia may interact to cause periodic breathing.     

Ventilatory, hemodynamic, sympathetic nervous system, and vascular reactivity changes after recurrent nocturnal sustained hypoxia in humans

Recurrent and intermittent nocturnal hypoxia is characteristic of several diseases including chronic obstructive pulmonary disease, congestive heart failure, obesity-hypoventilation syndrome, and obstructive sleep apnea. The contribution of hypoxia to cardiovascular morbidity and mortality in these disease states is unclear, however. To investigate the impact of recurrent nocturnal hypoxia on hemodynamics, sympathetic activity, and vascular tone we evaluated 10 normal volunteers before and after 14 nights of nocturnal sustained hypoxia (mean oxygen saturation 84.2%, 9 h/night). Over the exposure, subjects exhibited ventilatory acclimatization to hypoxia as evidenced by an increase in resting ventilation (arterial Pco(2) 41.8 +/- 1.5 vs. 37.5 +/- 1.3 mmHg, mean +/- SD; P < 0.05) and in the isocapnic hypoxic ventilatory response (slope 0.49 +/- 0.1 vs. 1.32 +/- 0.2 l/min per 1% fall in saturation; P < 0.05). Subjects exhibited a significant increase in mean arterial pressure (86.7 +/- 6.1 vs. 90.5 +/- 7.6 mmHg; P < 0.001), muscle sympathetic nerve activity (20.8 +/- 2.8 vs. 28.2 +/- 3.3 bursts/min; P < 0.01), and forearm vascular resistance (39.6 +/- 3.5 vs. 47.5 +/- 4.8 mmHg.ml(-1).100 g tissue.min; P < 0.05). Forearm blood flow during acute isocapnic hypoxia was increased after exposure but during selective brachial intra-arterial vascular infusion of the alpha-blocker phentolamine it was unchanged after exposure. Finally, there was a decrease in reactive hyperemia to 15 min of forearm ischemia after the hypoxic exposure. Recurrent nocturnal hypoxia thus increases sympathetic activity and alters peripheral vascular tone. These changes may contribute to the increased cardiovascular and cerebrovascular risk associated with clinical diseases that are associated with chronic recurrent hypoxia.     

Exposure to hypoxia produces long-lasting sympathetic activation in humans.

The relative contributions of hypoxia and hypercapnia in causing persistent sympathoexcitation after exposure to the combined stimuli were assessed in nine healthy human subjects during wakefulness. Subjects were exposed to 20 min of isocapnic hypoxia (arterial O(2) saturation, 77-87%) and 20 min of normoxic hypercapnia (end-tidal P(CO)(2), +5.3-8.6 Torr above eupnea) in random order on 2 separate days. The intensities of the chemical stimuli were manipulated in such a way that the two exposures increased sympathetic burst frequency by the same amount (hypoxia: 167 +/- 29% of baseline; hypercapnia: 171 +/- 23% of baseline). Minute ventilation increased to the same extent during the first 5 min of the exposures (hypoxia: +4.4 +/- 1.5 l/min; hypercapnia: +5.8 +/- 1.7 l/min) but declined with continued exposure to hypoxia and increased progressively during exposure to hypercapnia. Sympathetic activity returned to baseline soon after cessation of the hypercapnic stimulus. In contrast, sympathetic activity remained above baseline after withdrawal of the hypoxic stimulus, even though blood gases had normalized and ventilation returned to baseline levels. Consequently, during the recovery period, sympathetic burst frequency was higher in the hypoxia vs. the hypercapnia trial (166 +/- 21 vs. 104 +/- 15% of baseline in the last 5 min of a 20-min recovery period). We conclude that both hypoxia and hypercapnia cause substantial increases in sympathetic outflow to skeletal muscle. Hypercapnia-evoked sympathetic activation is short-lived, whereas hypoxia-induced sympathetic activation outlasts the chemical stimulus.     

Periods of intermittent hypoxic apnea can alter chemoreflex control of sympathetic nerve activity in humans

Obstructive sleep apnea is associated with sustained elevation of muscle sympathetic nerve activity (MSNA) and altered chemoreflex control of MSNA, both of which likely play an important role in the development of hypertension in these patients. Additionally, short-term exposure to intermittent hypoxic apneas can produce a sustained elevation of MSNA. Therefore, we tested the hypothesis that 20 min of intermittent hypoxic apneas can alter chemoreflex control of MSNA. Twenty-one subjects were randomly assigned to one of three groups (hypoxic apnea, hypercapnic hypoxia, and isocapnic hypoxia). Subjects were exposed to 30 s of the perturbation every minute for 20 min. Chemoreflex control of MSNA was assessed during baseline, 1 min posttreatment, and every 15 min throughout 180 min of recovery by the MSNA response to a single hypoxic apnea. Recovery hypoxic apneas were matched to a baseline hypoxic apnea with a similar nadir oxygen saturation. A significant main effect for chemoreflex control of MSNA was observed after 20 min of intermittent hypoxic apneas (P <0.001). The MSNA response to a single hypoxic apnea was attenuated 1 min postexposure compared with baseline (P <0.001), became augmented within 30 min of recovery, and remained augmented through 165 min of recovery (P <0.05). Comparison of treatment groups revealed no differences in the chemoreflex control of MSNA during recovery (P=0.69). These data support the hypothesis that 20 min of intermittent hypoxic apneas can alter chemoreflex control of MSNA. Furthermore, this response appears to be mediated by hypoxia.