Respiratory and neuroendocrine responses of piglets to hypoxia during postnatal development

Role of fast inhibitory synaptic transmission in neonatal respiratory rhythmogenesis and pattern formation

Several studies have investigated the general role of chloride-based neurotransmission (GABA_A and glycinergic signaling) in respiratory rhythmogenesis and pattern formation. In several brain regions, developmental alterations in these signaling pathways have been shown to be mediated by changes in cation-chloride cotransporter (CC) expression. For instance, CC expression changes during the course of neonatal development in medullary respiratory nuclei and other brain/spinal cord regions in a manner which decreases the cellular import, and increases the export, of chloride ions, shifting reversal potentials for chloride to progressively more negative values with maturation. In slice preparations of the same, this is related to an excitatory-to-inhibitory shift of GABA_A- and glycinergic signaling. In medullary slices, GABA_A-/glycinergic signaling in the early neonatal period is excitatory, becoming inhibitory over time. Additionally, blockade of the Na⁺/K⁺/2Cl^- cotransporter, which imports these ions via secondary active transport, converts excitatory response to inhibitory ones. These effects have not yet been demonstrated at the individual respiratory-related neuron level to occur in intact (in vivo or in situ) animal preparations, which in contrast to slices, possess normal network connectivity and natural sources of tonic drive. Developmental changes in respiratory rhythm generating and pattern forming pontomedullary respiratory circuitry may contribute to critical periods, during which there exist increased risk for perinatal respiratory disturbances of central, obstructive, or hypoxia/hypercapnia-induced origin, including the sudden infant death syndrome. Thus, better characterizing the neurochemical maturation of the central respiratory network will enhance our understanding of these conditions, which will facilitate development of targeted therapies for respiratory disturbances in neonates and infants.

Brainstem amino acid neurotransmitters and ventilatory response to hypoxia in piglets

The ventilatory response to hypoxia is influenced by the balance between inhibitory (GABA, glycine, and taurine) and excitatory (glutamate and aspartate) brainstem amino acid (AA) neurotransmitters. To assess the effects of AA in the nucleus tractus solitarius (NTS) on the ventilatory response to hypoxia at 1 and 2 wk of age, inhibitory and excitatory AA were sampled by microdialysis in unanesthetized and chronically instrumented piglets. Microdialysis samples from the NTS area were collected at 5-min intervals and minute ventilation (VE), arterial blood pressure (ABP), and arterial blood gases (ABG) were measured while the animals were in quiet sleep. A biphasic ventilatory response to hypoxia was observed in wk 1 and 2, but the decrease in VE at 10 and 15 min was more marked in wk 1. This was associated with an increase in inhibitory AA during hypoxia in wk 1. Excitatory AA levels were elevated during hypoxia in wk 1 and 2. Changes in ABP, pH, and ABG during hypoxia were not different between weeks. These data suggest that the larger depression in the ventilatory response to hypoxia observed in younger piglets is mediated by predominance of the inhibitory AA neurotransmitters, GABA, glycine, and taurine, in the NTS.

Protein kinase C activity in the nucleus tractus solitarii is critically involved in the acute hypoxic ventilatory response, but is not required for intermittent hypoxia-induced phrenic long-term facilitation in adult rats

Protein kinase C (PKC) is a broadly expressed and critically important signalling protein with a wide range of functional roles, including central components of respiratory control. For example, systemic and targeted administration of PKC inhibitors within the nucleus of the solitary tract (nTS) markedly attenuates peak hypoxic ventilatory responses (HVR). Protein kinase C activation in phrenic motor nucleus has also been implicated in some forms of acute respiratory plasticity, such as phrenic long-term facilitation (pLTF), a persistent enhancement of phrenic motor output following acute intermittent hypoxia. To further examine the role of PKC within the nTS, the selective PKC antagonist bisindolylmaleimide I (BIM I) was microinjected in the area corresponding to the nTS via bilateral osmotic pumps in normoxic adult male Sprague-Dawley rats; control animals received bisindolylmaleimide V (BIM V, inactive analogue). In one series of experiments, hypoxic challenges (fractional inspired ) were conducted in unrestrained animals (n = 8 per group). No differences in baseline ventilation emerged; however, peak HVR was attenuated following BIM I (P < 0.01), primarily owing to reductions in respiratory frequency increases (P < 0.01). In a second series of experiments, integrated phrenic nerve activity was recorded in anaesthetized, vagotomized, paralysed and ventilated rats exposed to three 5 min hypoxic episodes separated by 5 min hyperoxia . During baseline conditions, no differences emerged in phrenic nerve output; however, phrenic nerve output measured during the initial hypoxic exposure was significantly attenuated in BIM I-treated rats (P < 0.01). In contrast, both groups of animals displayed significant pLTF (BIM I versus BIM V; n.s.). Thus, we conclude that PKC activation within the nTS is critically involved in the central response to acute hypoxia, but does not appear to play a role in either eliciting or maintaining pLTF.

Comparative anatomical assessment of the piglet as a model for the developing human medullary serotonergic system

Because the piglet is frequently used as a model for developmental disorders of the medullary serotonergic (5-HT) system in the human infant, this review compares the topography and developmental profile of selected 5-HT markers between humans in the first year of life and piglets in the first 60 days of life. The distribution of tryptophan hydroxylase-immunoreactive 5-HT neurons in the human infant medulla is very similar, but not identical, to that in the piglet. One notable difference is the presence of compact clusters of 5-HT neurons at the ventral surface of the piglet medulla. While it lacks these distinctive clusters, the human infant medulla contains potentially homologous 5-HT neurons scattered along the ventral surface embedded in the arcuate nucleus. Each species shows evidence of age-related changes in the 5-HT system, but the changes are different in nature; in the human infant, statistically significant age-related changes are observed in the proportional distribution of medullary 5-HT cells, while in the piglet, statistically significant age-related changes are observed in the levels of 5-HT receptor binding in certain medullary nuclei. Analyses of 5-HT receptor binding profiles in selected nuclei in the two species suggest that the equivalent postnatal ages for 5-HT development in piglets and human infants are, respectively, 4 days and 1 month, 12 days and 4 months, 30 days and 6 months, and 60 days and 12 months. Collectively, when certain species differences are considered, these data support the use of the piglet as a model for the human infant medullary 5-HT system.

Calcium/calmodulin-dependent kinase II mediates critical components of the hypoxic ventilatory response within the nucleus of the solitary tract in adult rats

Calcium/calmodulin-dependent kinase II (CaMKII) is an ubiquitous second messenger that is highly expressed in neurons, where it has been implicated in some of the pathways regulating neuronal discharge as well as N-methyl-d-aspartate receptor-mediated synaptic plasticity. The full expression of the mammalian hypoxic ventilatory response (HVR) requires intact central relays within the nucleus of the solitary tract (NTS), and neural transmission of hypoxic afferent input is mediated by glutamatergic receptor activity, primarily through N-methyl-d-aspartate receptors. To examine the functional role of CaMKII in HVR, KN-93, a highly selective antagonist of CaMKII, was microinjected in the NTS via bilaterally placed osmotic pumps in freely behaving adult male Sprague-Dawley rats for 3 days. Vehicle-loaded osmotic pumps were surgically placed in control animals, and adequate placement of cannulas was ascertained for all animals. HVR was measured using whole body plethysmography during exposure to 10% O2-balance N2 for 20 min. Compared with control rats, KN-93 administration elicited marked attenuations of peak HVR (pHVR) but did not modify normoxic minute ventilation. Differences in pHVR were primarily attributable to diminished respiratory frequency recruitments during pHVR without significant differences in tidal volume. These findings indicate that CaMKII activation in the NTS mediates respiratory frequency components of the ventilatory response to acute hypoxia; however, CaMKII activity does not appear to underlie components of normoxic ventilation.

Adenosine A2A receptors mediate GABAergic inhibition of respiration in immature rats

Adenosine is a known inhibitor of respiratory output during early life. In this study we investigated the developmental changes in adenosine A2A-receptor activation on respiratory timing, as well as the relationship between adenosine and GABA. The specific adenosine A2A-receptor agonist CGS-21680 (CGS) or vehicle control was injected into the fourth ventricle of 14-day (n = 9), 21-day (n = 9), and adult (n = 5) urethane-anesthetized rats while diaphragm electromyogram was monitored as an index of respiratory neural output. CGS injection resulted in a decrease in frequency and/or apnea in all 14-day-old rats and in 66% of 21-day-old rats. There was no effect of CGS injection on respiratory timing in adult rats. Prior injection of the GABA(A)-receptor blocker bicuculline at 14 and 21 days eliminated the CGS-induced decrease in frequency and apnea. We conclude from these studies that the inhibitory effect of A2A-receptor activation on respiratory drive is age dependent and is mediated via GABAergic inputs to the inspiratory timing neural circuitry. These findings demonstrate an important mechanism by which xanthine therapy alleviates apnea of prematurity.

Adenosine A2A receptors interact with GABAergic pathways to modulate respiration in neonatal piglets

GABA and adenosine contribute to respiratory inhibition in early postnatal life. In this study the adenosine A2A receptor agonist CGS21680 was used to evaluate adenosine receptor specificity and the interrelation of adenosine and GABA in the inhibition of inspiratory drive. In neonatal piglets (n = 10), CGS21680 was injected into the fourth ventricle resulting in apnea and/or decreased burst area and frequency of phrenic discharge. Phrenic burst area decreased to 58.9 +/- 8.6% (S.E.M.) after CGS21680 injection (control = 91.8 +/- 1.0%). Expiratory time increased 261.0 +/- 59.9% after CGS21680 from control (87.7 +/- 2.7%). When bicuculline was injected locally within the rostral ventrolateral medulla (n = 5), or into the fourth ventricle (n = 5), the CGS21680 induced inhibition of phrenic was abolished. To define expression of A2A receptor at the message level (mRNA), we employed in situ hybridization with a digoxigenin-coupled oligonucleotide. Adenosine A2A receptor mRNA was expressed in regions of the medulla oblongata known to contain GABAergic neurons. We conclude that GABAergic inputs affecting respiratory timing and inspiratory drive are modulated by activation of A2A receptors. These findings offer new insight into the mechanism whereby xanthine therapy diminishes apnea of prematurity.

Maturation of respiratory reflex responses in the fetus and neonate

Respiratory control in the fetus and neonate is quite immature when compared to that of adults. This immaturity involves all facets of respiration including respiratory responses to hypoxia, hypercapnia, an exaggerated apnoeic response to laryngeal stimulation and immature responses to activation of pulmonary afferents. The net result of this immaturity of breathing responses is the vulnerability of neonates and especially preterm infants to apnoea and respiratory pauses. The mechanisms behind immature control of breathing are not fully understood, but seem to originate from a predominance of inhibitory input early in life on respiratory centres. The relative contribution of up-regulation of inhibitory pathways versus down-regulation of excitatory ones is not clear. Multiple neurotransmitters have been implicated in the regulation of breathing in mammals and some of them are discussed in this chapter.

Effect of stimulus cycle time on acute respiratory responses to intermittent hypercapnic hypoxia in unsedated piglets

To determine whether stimulus frequency affects physiological compensation to an intermittent respiratory stimulus, we studied piglets (n = 43) aged 14.8 +/- 2.4 days. A 24-min total hypercapnic hypoxia (HH) (10% O(2)-6% CO(2)-balance N(2) = HH) was delivered in 24-, 8-, 4-, or 2-min cycles alternating with air. Controls (n = 10) breathed air continuously. Minute ventilation and temperature were not different between the 2-min and 24-min groups, with neither different from controls during recovery. Piglets exposed to 8-min cycles had ventilatory stimulation, whereas those exposed to 4-min cycles had significant depression of ventilation. Despite this, piglets in these intermediate intermittent HH (IHH) groups (8- and 4-min cycles) showed more severe acidosis and attenuated temperature changes (P < 0.001 and P < 0.01 for pH and temperature vs. 24 min, respectively). Cycle time affected the ability of young piglets to tolerate IHH. More severe respiratory acidosis developed when IHH was delivered in intermediate (4 min or 8 min) cycles compared with the same total dose as a single episode or in short (2 min) cycles.

Developmental changes of (3)H-labelled mu-opioid receptors in brainstems of intra-uterine growth-restricted rats

The opioid mu-system is involved in brainstem-mediated respiratory control. Infants with intra-uterine growth restriction (IUGR) have more respiratory disorders in the early postnatal period. Using [(3)H]DAGO, a mu-selective ligand, and a computer-based image analysis of autoradiography, we compared the ontogeny and distribution of mu-opioid binding sites in the brainstem of IUGR and control rats in utero (E21), at birth (P0) and on postnatal days 1 (P1), P7, P10, P14 and P21. The ontogeny pattern was found to be similar in both groups. The density of the binding sites, which was low in E21, increased at P0, slightly declined at P1 and remained relatively constant thereafter. The distribution of DAGO-binding sites, also similar in both groups, was heterogeneous and was much denser in the dorsal areas of medulla and pons. In particular, binding sites were highly concentrated in nuclei involved in the cardio-respiratory function. However, DAGO-binding density was higher at all ages (except for P0 and P1) in IUGR than in control rats. Taken together, these results give at least a partial explanation for the effects of IUGR which lowers the Apgar score at birth and raises the incidence of respiratory disorders in infants.

Respiratory responses to single and episodic hypoxia during development: mechanisms of adaptation

The respiratory responses of the developmental subject to single and repeated episodes of hypoxia are distinct. During a single exposure, the fetus responds with an arrest of breathing activity, and the neonate, with excitation followed by depression (the biphasic response). Mechanisms under active consideration include chemosensory resetting, hypometabolism, prevalence of inhibitory neurotransmitter/modulator influence, and supramedullary regulation of control functions. When exposed to recurrent episodic hypoxia, neonates respond with relative hypoventilation, i.e. tolerance to a subsequent hypoxic stimulus. Whereas the investigation of processes responsible for this tolerance is at its infancy, studies using chronic hypoxia appear to be a useful guide. So far, altered interstitial neuromodulator levels and central markers of programmed neuronal death are harbingers of future research in this field. The clarification of the mechanisms involved in response to recurrent episodic hypoxia during development will be of fundamental value and may be useful for the eventual treatment and/or prevention of harmful central respiratory-related processes.

Age-dependent metabolic effects of repeated hypoxemia in piglets

The aim of this study was to determine whether repeated exposure to hypoxemia would modify the response to hypoxemia during maturation. We exposed piglets to three 1-h cycles of hypoxemia (PaO2 = 30 to 35 mmHg; 1 mmHg = 133.3 Pa) at 1 week (n = 9), 2-3 weeks (n = 10), and 4-5 weeks of age (n = 10). O2 consumption (VO2) and CO2 production (VCO2) were measured, and alveolar ventilation (VA) was derived from VCO2 and PaCO2. Levels of lactic acid (lactate) and serum catecholamines were also measured. With hypoxemia, time had a significant effect on VO2 and body temperature in an age-dependent fashion: that is, whereas the 1 week group and the 4-5 week group showed both variables decreasing over time, the 2-3 week group showed no drop in VO2 and a small increase in body temperature over time. Lactate levels increased with hypoxemia in all animals during the first exposure. However, with repeated exposures to hypoxemia, only the 2-3 week group continued to increase its lactate levels. Furthermore, the changes in lactate levels paralleled the changes in epinephrine levels with hypoxemia. We found, too, that although VA increased significantly with hypoxemia in all animals, this change was not modified by age or repeated exposures. No significant effects of age or repeated exposures were found in the cardiovascular response to hypoxemia. We concluded that, from a metabolic viewpoint, after repeated exposures to hypoxemia the 2-3 week animals responded differently.Key words: metabolic rate, lactic acid, maturation, catecholamines.

Adenosine modulates inspiratory neurons and the respiratory pattern in the brainstem of neonatal rats

The role of adenosine in the modulation of respiration-related neurons was examined using an in vitro brainstem-spinal cord preparation from neonatal rats (0-4 d old). Respiratory activity was recorded from the C4 or C5 ventral roots by suction electrodes and from inspiratory related neurons (I neurons) in the rostral ventrolateral medulla by microelectrodes. The following substances were added to the preparation superfusate, and their effect was evaluated: the adenosine A1 receptor agonist N6-(2-phenylisopropyl)adenosine, R(-)isomer (R-PIA), the adenosine uptake blocker dipyridamole, the adenosine receptor antagonist theophylline, and the specific A1 receptor antagonist 8-cyclopentyl-1,3-dipropylxanthine (DPCPX). R-PIA and dipyridamole decreased the activity of I neurons and the C4 respiratory burst rate. Furthermore, these compounds induced a significantly more irregular respiratory rate in three-quarters of preparations from the youngest animals (<48 h old) compared with that of controls. Theophylline or DPCPX reversed the effects of both R-PIA and dipyridamole on respiratory rate, regularity of respiratory rate, inspiratory time, amplitude, and intra-burst frequency of I neurons. Thus, adenosine depresses both the I neurons in the rostral ventrolateral medulla and the respiratory motor output. This depression of I neurons and respiratory rate can be abolished by theophylline primarily through a blockade of medullary adenosine A1 receptors. An age-dependent correlation of the effects of R-PIA and dipyridamole, with a more pronounced decrease in respiratory activity in preparations from younger animals, indicates that adenosinergic modulation of medullary respiration-related neurons changes during the first days of postnatal life.

Postnatal development of the pattern of respiratory and cardiovascular response to systemic hypoxia in the piglet: the roles of adenosine

1. In 3-day-old and 3-week-old spontaneously breathing piglets anaesthetized with Saffan, we have studied ventilatory and cardiovascular responses evoked by 5 min periods of hypoxia (breathing 10 and 6% O2). 2. In 3-day-old piglets both 10 and 6% O2 evoked an increase followed by a secondary fall in ventilation, a gradual tachycardia and a renal vasoconstriction, with an increase in femoral blood flow that was attributable to femoral vasodilatation. Arterial blood pressure rose initially but fell towards control values by the 5th minute of hypoxia. 3. The stable adenosine analogue 2-chloroadenosine (2-CA; 30 mg kg(-1) i.v.) evoked bradycardia and renal vasoconstriction, but had no effect on femoral vasculature. These responses were blocked by the adenosine receptor antagonist 8-phenyltheophylline (8-PT; 8 mg kg(-1) i.v.). 8-PT also abolished the secondary fall in ventilation evoked by 10 and 6% O2 and the renal vasoconstriction evoked by 10% O2, but had no effect on the tachycardia, or on the femoral vascular response. 4. By contrast, in 3-week-old piglets both 10 and 6% O2 evoked a sustained increase in ventilation, tachycardia and a rise in arterial pressure with renal vasoconstriction, but no change in renal blood flow and substantial femoral vasodilatation with an increase in femoral blood flow. 2-CA evoked bradycardia and renal vasoconstriction, as in 3-day-old piglets, but also evoked pronounced femoral vasodilatation. 8-PT blocked these responses and the hypoxia-induced femoral vasodilatation, but had no significant effect on other components of the hypoxia-induced response. 5. We propose that there is postnatal development of the ventilatory and cardiovascular responses evoked by systemic hypoxia and of the role of locally released adenosine in these responses: at 3 days, adenosine released within the central nervous system and within the kidney is a major contributor to the secondary fall in ventilation and renal vasoconstriction respectively, whereas at 3 weeks, adenosine makes little contribution to the ventilatory response, or renal vasoconstriction, but is largely responsible for hypoxia-induced vaso-dilatation in skeletal muscle.

Respiratory electromyographic estimates of ventilatory functions in piglets

The best electromyographic (EMG) predictors of respiratory drive (P100), tidal volume (VT) and ventilation (VE) were determined from diaphragmatic (DI) and posterior cricoarytenoid (PCA) EMG measures in 8-48-day-old, anesthetized piglets. Progressive hypercapnia was employed to obtain a wide range of muscle activity. A custom-designed, microcomputer-based system was employed to measure the duration, peak amplitude, rate of rise (initial slope) as well as the summed total and initial (first 100 ms) EMG activity from the DI and the PCA. For each respiratory function, the following combinations of EMG measures were identified as significant predictors using regression analyses: (1) for P100, DI amplitude, PCA initial area and PCA rate of rise; (2) for VT, DI amplitude, PCA duration and DI duration; (3) for VE, DI amplitude, DI initial area, PCA initial area, PCA rate of rise, PCA duration, DI area and DI rate of rise. Thus, whereas the traditionally employed measure of DI amplitude is an important correlate of P100, VT or VE, a complete estimate of these respiratory functions requires the inclusion of initial EMG measures and duration.

Hypoxia, sleep and respiration in relation to opioids in developing swine

To test the role of mu and delta opioid systems in neonates during hypoxia, a total of sixteen, 4-11 (n = 7) and 26-33-day-old piglets (n = 9) were instrumented aseptically for assessment of sleep/wake states (S/W), electromyographic activities of the diaphragm and posterior cricoarytenoid muscles (EMGdi, EMG-pca, respectively), heart rate, and arterial pressures, pH and gas tensions. During daily sessions for 5 consecutive days, the piglets inhaled 10% O2/90% N2 for 10 min twice per session, first before any drug, then after either naltrexone (2 mg.kg-1 i.v.), a predominantly mu opioid antagonist, or naltrindole (4 mg.kg-1 i.v.), a specific delta opioid antagonist. During hypoxia, young, in contrast to older piglets, spent more time asleep, and increased sleep during the second half of the hypoxic exposure before, but not after each antagonist. They also exhibited, overall, higher breathing frequency, and lower slope, amplitude, area and initial area of EMGdi and EMGpca activity than older piglets. Naltrindole stimulated EMGpca activity in both age groups, and naltrexone increased the breathing frequency and slope of EMGdi in the older group. We conclude that hypoxia enhances the activation of central mu and delta opioid systems which influence S/W and respiration.

Effects of pentobarbital on proopiomelanocortin opioid products of neonatal piglets during normoxia and hypoxia

Abstract Endogenous opioids have been shown to suppress physiological functions in the neonate. It has been suggested that anesthesia with barbiturates might enhance this suppression by influencing opioid systems directly. To explore this possibility, naive piglets, 2.2+/-0.8 (X+/-SD) days old, underwent one of five protocols: 1) normoxia (control); 2) 10% 0(2)/90% N(2) (hypoxia); 3) saline injection ip during normoxia (sham anesthesia); 4) pentobarbital sodium, 25 mg/kg ip, during normoxia (barbiturate anesthesia); and 5) pentobarbital sodium, 25 mg/kg ip, during hypoxia (combined hypoxia and barbiturate anesthesia). Following the inhalation of either gas mixture for at least 30 min, and precisely 30 min after an injection, blood, cerebrospinal fluid and a dorsal medullary slice containing the nucleus tractus solitarii were collected and processed for measurement by radioimmunoassay of opioid proopiomelanocortin products. These comprised beta-lipotropin (the precursor), beta-endorphin-like immunoreactivity (containing the active peptide beta-endorphin) and N-acetyl beta-endorphin (a deactivated peptide). The most striking result was seen in the cerebrospinal fluid: As compared to barbiturate anesthesia, peptide levels with all other treatments, including combined hypoxia and barbiturate anesthesia, were consistently higher. In the plasma, peptide levels after either combined hypoxia and barbiturate anesthesia or hypoxia alone were generally higher than those of their respective controls (sham anesthesia, control). Plasma levels of beta-endorphin-like immunoreactivity and estimated beta-endorphin with combined hypoxia and barbiturate anesthesia were also higher than those with barbiturate anesthesia. The latter pattern was reversed in the nucleus tractus solitarii, in which beta-endorphin-like immunoreactivity and estimated beta-endorphin levels were lower with combined hypoxia and barbiturate anesthesia than with barbiturate anesthesia alone, although no significant differences were achieved. These results suggest that pentobarbital may decrease the central neuronal release of active endorphins, and thus decrease the quantity of these ligands available for interaction with opioid receptors. Hypoxia, on the other hand, appears to increase such release even in the presence of pentobarbital. Thus, during a hypoxic insult, the suppressive influence of opioids on physiological functions would be enhanced regardless of the presence of barbiturate anesthesia.

Modulation by mu opioid antagonism of sleep and respiration in neonatal swine

Young (3-13 days) and older (26-34 days) piglets were instrumented aseptically for chronic recording of sleep/wake states (biparietal electrocorticogram, horizontal and vertical electrooculogram, submental muscle electromyogram (EMG)), heart rate, arterial pressure, pH and gas tensions, posterior cricoarytenoid and diaphragmatic EMG (EMGpca, EMGdi). After recovery from surgery, piglets underwent 1 h daily recordings for 5 consecutive days. Experimental sessions comprised control periods followed by study periods with CTOP (10-40 micrograms/kg i.v.), a somatostatin analogue with mu opioid antagonistic activity. In the young group, CTOP decreased percent time spent in active sleep (AS), increased heart rate during wakefulness, increased breathing frequency during transitional and quiet sleep (TS, QS) and decreased the duration of EMGdi activity during TS, QS and AS. In the older group, CTOP decreased the duration of EMGdi activity during QS. Changes in cardiorespiratory functions with age simulated those reported previously (Scott et al. (1990) Respir. Physiol. 80: 83-102). We conclude that, in early neonatal life, the mu opioid system influences both sleep pattern and respiratory timing, and that this influence diminishes with postnatal age.

Respiratory responses of piglets to hypercapnia during postnatal development: effects of opioids

Resting respiratory and cardiovascular functions and the response to CO2 rebreathing were compared between 2.5 +/- 0.7 (mean +/- SE) and 34.1 +/- 1.9 day old piglets, before and after the opioid antagonist naltrexone (1 mg/kg IV). At rest, tidal volume, both absolute and per m2, inspiratory and expiratory time, absolute minute ventilation, and mean arterial pressure increased with age, and breathing frequency, minute ventilation per m2, and heart rate decreased, all of these with as well as without naltrexone. During hypercapnia, the pattern, but not the quantitative aspects of breathing changed with age. At rest, naltrexone produced hyperventilation in the young, but not in the older group. During hypercapnia, naltrexone had a sparse effect in both ages. We conclude that, in the anesthetized piglet, ventilatory functions at rest undergo change with postnatal age, but breathing responses to hypercapnia exhibit maturation in pattern only and not in magnitude. Whereas resting ventilation of young piglets is modulated by endogenous opioids, hypercapnia may activate opioids to a limited extent and in a manner unrelated to age.

Effect of adenosine on isolated and superfused cat carotid body activity

Adenosine is known to increase carotid chemoreceptor discharge in vivo. Since adenosine has powerful vascular effects it is possible that this chemoexcitation is indirectly caused by changes in carotid body blood flow. To evaluate this possibility the effect of adenosine (0.02-2.0 mumol) was assessed on the chemoreceptor activity of the cat carotid bodies in vitro. All three doses of adenosine produced an increase in chemoreceptor discharge which reached its maximum within 10-20 s and subsequently returned to preinjection controls within 1 min. The chemoreceptor excitation caused by adenosine was dose-dependent. These results suggest that adenosine induces chemoexcitation without changes in blood pressure and blood flow.

Effect of adenosine on chemosensory activity of the cat aortic body

Adenosine, which is released during hypoxia, increases carotid chemoreceptor discharge. It is not known if adenosine also may stimulate the aortic chemoreceptors. The purpose of this study was to investigate if adenosine also can stimulate aortic chemoreceptors. The effect of adenosine (0.01, 0.1 and 1.0 mumol/kg) on aortic chemoreceptor discharge was studied in seven anesthetized, paralyzed and artificially ventilated adult cats. Intra-aortic injections of adenosine produced an increase in chemoreceptor discharge, which reached its peak between 10 and 20 s. The chemoreceptor augmentation increased with higher doses of adenosine. Adenosine also caused a fall in blood pressure. The increase of chemoreceptor discharge was not related to fall in arterial blood pressure. Since adenosine is released during hypoxia, it is suggested that part of the cardiovascular changes induced by hypoxia is due to stimulation of aortic chemoreceptors by adenosine.

Ontogeny of sleep/wake and cardiorespiratory behavior in unanesthetized piglets

Young and older piglets (2-15, 25-35 days old) underwent chronic recording of electrocorticogram, vertical and horizontal electrooculograms, electromyograms of submental muscles, diaphragm (EMGdi) and posterior cricoarytenoid (EMGpca), and heart rate, arterial pressure, pH and gas tensions. With age, (1) the distribution of percent time spent in various sleep-wake states differed; (2) heart rate decreased in all S/W, arterial pressure increased in wakefulness (W), transitional sleep (TS) and quiet sleep (QS); (3) respiratory frequency decreased, EMGdi and EMGpca duration and EMGpca amplitude increased in all S/W, EMGdi amplitude decreased in TS and QS and rate of rise of EMGdi and EMGpca decreased in W, TS and QS. Active sleep was characterized by smaller normalized EMGpca amplitudes in the young, short EMGpca to EMGdi intervals in both ages and predominance of prolonged diminished muscle activity (DMA) of either muscle. Discoordination between EMGpca and EMGdi activation and the occurrence of DMA were influenced by youth and male gender. These results provide insight into subtle expressions of gender and sleep influences on developmental respiratory control.

Opioids and the developing organism: a comprehensive bibliography, 1984-1988

A comprehensive bibliography of the literature concerned with opioids and the developing organism for 1984-1988 is presented. Utilized with companion papers (Neurosci. Biobehav. Rev. 6:439-479; 1982; 8:387-403; 1984), these articles cover the clinical and laboratory references beginning in 1875. For the years 1984, 1985, 1986, 1987, and 1988, a total of 877 citations were recorded. A series of indexes accompanies the citations in order to make the literature more accessible. These indexes are divided into clinical and laboratory topics, and subdivided into such topics as the type of opioid explored and the general area of biological interest (e.g., physiology).

Possible modulation of the medullary respiratory rhythm generator by the noradrenergic A5 area: an in vitro study in the newborn rat

Respiratory activity was recorded on hypoglossal nerve or ventral cervical roots during in vitro experiments performed in the superfused brainstem-cervical cord preparation of newborn rats. Section and coagulation experiments revealed that the medullary respiratory generator was tonically inhibited by a structure located in the caudal ventrolateral pons. Electrical and pharmacological stimulations located this structure more precisely between the superior olivary nuclei and the sensory nucleus of the Vth nerve, i.e. in an area containing the A5 noradrenergic nucleus. Norepinephrine and alpha 2-antagonists (yohimbine, idazoxan) added to the bathing medium modified the respiratory frequency. Norepinephrine decreased respiratory frequency whereas norepinephrine antagonists increased respiratory rate. The electrical stimulation of the caudal ventrolateral pons which inhibited the respiratory rhythm under normal bathing medium became ineffective after alpha 2-antagonist. The results herein suggest that a noradrenergic inhibitory drive, originating from the A5 area or surrounding structures modulates the activity of the medullary respiratory generator. This hypothesis is discussed in relation to A5 involvement in cardiovascular regulation.