Behavioural state influences the cardiovascular response to haemorrhage in lambs

We investigated the effect of behavioural state on the cardiovascular response to an acute venous haemorrhage in 7 lambs aged 13 to 19 days. Each lamb had previously been anaesthetized and instrumented for measurements of electrocorticogram, electro-oculogram, nuchal and diaphragm electromyograms, pulmonary blood flow (electromagnetic flow transducer), aortic and right atrial blood pressures. The lambs were allowed to recover from surgery at least three days before they were studied. Measurements were made during a 1-minute control period and during a 1-minute experimental period that followed a 10 ml/kg body weight haemorrhage during quiet wakefulness, quiet sleep and active sleep; the haemorrhage took approximately 30s. Haemorrhage produced similar decreases in right atrial pressure and pulmonary blood flow during the three behavioural states. However, mean aortic pressure decreased more following haemorrhage during active sleep than during quiet sleep or quiet wakefulness. These results provide evidence that reflex control of the peripheral circulation is altered during active sleep compared to quiet sleep and quiet wakefulness in lambs.     

Fever in young lambs: temperature, metabolic and cardiorespiratory responses to a small dose of bacterial pyrogen

Experiments were done on ten lambs ranging in age from 15 to 25 days to define the temperature, metabolic and cardiorespiratory responses to intravenous administration of a small dose of bacterial pyrogen (SAE). Administration of SAE but not normal saline produced a short-lived fever of about 0.7 degrees C. The increase in body-core temperature was preceded by a surge in total body oxygen consumption and the onset of shivering which was influenced by behavioral state (ie, shivering was inhibited during active sleep). The increase in total body oxygen consumption was initially met by an increase in total body oxygen extraction and then by an increase in systemic oxygen delivery. Systemic arterial blood pressure did not change significantly during the febrile response; however, pulmonic arterial blood pressure increased significantly. Thus, our experiments provide new data on oxygen supply and demand during the development of fever and that shivering thermogenesis is inhibited in active sleep following the administration of bacterial pyrogen in young lambs. The influence of active sleep on the overall febrile response, and whether or not there is a shift from shivering thermogenesis to non-shivering thermogenesis remains to be determined.     

Fever in young lambs: hypoxemia alters the febrile response to a small dose of bacterial pyrogen.

Experiments were done on eight young lambs to investigate the effects of hypoxemia on the body temperature, metabolic and cardiovascular responses to intravenous administration of a small dose of bacterial pyrogen (0.3 micrograms lipopolysaccharide extracted from Salmonella Abortus Equi; SAE). Each lamb was anaesthetized with halothane and prepared for sleep staging and measurements of cardiac output, arterial and mixed-venous haemoglobin oxygen saturations, body-core and ear-skin temperatures. Three experiments were done on each lamb, the first being done no sooner than three days after surgery. The first experiment consisted of establishing the thermal neutral environment during normoxemia (ie, environmental temperature at which total body oxygen consumption was minimal while body temperature was maintained) for each lamb. The second and third experiments were done at the lamb's thermoneutral environment as determined on day 1. One experiment was done during normoxemia (ie, control condition, SaO2 approximately 90%) and one experiment was done during hypoxemia (ie, experimental condition, SaO2 approximately 50%). Measurements were made during a control period and during one-minute experimental periods at 10 minute intervals for 120 minutes following administration of 0.3 micrograms of bacterial pyrogen in sterile saline. Administration of SAE produced a short-lived fever of about 0.8 degrees C in the normoxemic lambs, whereas no change in body-core temperature was observed in the hypoxemic lambs. During normoxemia, the increase in body-core temperature was preceded by peripheral vasoconstriction, the onset of shivering, and a surge in total body oxygen consumption. The increase in total body oxygen consumption was met primarily by an increase in total body oxygen extraction during the development of fever. Cardiac index, heart rate, and systemic oxygen transport increased during the peak body-core temperature response. Systemic arterial blood pressure did not change significantly during the febrile response; however, pulmonic arterial blood pressure increased. During hypoxemia, peripheral vasoconstriction and shivering occurred following administration of SAE, but there was no change in total body oxygen consumption or body-core temperature. Thus, our data provide evidence that hypoxemia alters the febrile response of young lambs to bacterial pyrogen. The precise mechanism remains to be determined.     

Arousal and cardiopulmonary responses to hyperoxic hypercapnia in lambs

Experiments were done to investigate the arousal and cardiopulmonary responses to hyperoxic hypercapnia in 8 lambs. Each lamb was anaesthetized and instrumented for recordings of electrocorticogram, electro-oculogram, nuchal and diaphragm electromyograms and measurements of arterial blood pressure and haemoglobin oxygen saturation. No sooner than 3 days after surgery, measurements were made in quiet sleep and active sleep during control periods when the animal was breathing 21% oxygen and during experimental periods of hyperoxic hypercapnia when the animal was breathing 10% carbon dioxide and 30% oxygen. Hyperoxic hypercapnia was terminated during each epoch by returning the inspired gas mixture to 21% oxygen once the animal aroused from sleep. Arousal occurred from both sleep states during hyperoxic hypercapnia but was delayed in active sleep compared to quiet sleep (active sleep 58 +/- 17 s; quiet sleep 21 +/- 10 s; mean +/- 1SD). There were no significant changes in heart rate or blood pressure during hyperoxic hypercapnia before arousal. However, respiratory rate and diaphragm electrical activity did increase during hyperoxic hypercapnia before arousal. Thus, our data provide evidence that hypercapnia can initiate arousal from sleep in young lambs. The mechanisms responsible for this response are yet to be determined.     

Influence of carotid-denervation on the arousal and cardiopulmonary responses to alveolar hypercapnia in lambs

Experiments were done on five lambs to determine if carotid-denervation influences the arousal and cardiopulmonary responses to alveolar hypercapnia during sleep. Each lamb was anaesthetized and instrumented for recordings of electrocorticogram, electro-oculogram, nuchal and diaphragm electromyograms and measurements of systemic arterial blood pressure and arterial haemoglobin oxygen saturation. The carotid chemoreceptors and baroreceptors were denervated, a tracheostomy was done and a fenestrated tracheostomy tube placed in the trachea so that the inspired gas mixture could be changed quickly. No sooner than three days after surgery, measurements were made in quiet sleep and active sleep during control periods when the animal was breathing room air and during experimental periods of alveolar hypercapnia when the lamb was breathing 10% carbon dioxide in air. Alveolar hypercapnia was terminated during an experimental period by changing the gas mixture back to room air once the animal aroused from sleep. If an animal did not arouse within 2 min, the gas mixture was changed back to room air. Arousal occurred during only 6 of 12 epochs in quiet sleep and during only 2 of 10 epochs in active sleep. These data provide evidence that the carotid chemoreceptors and/or carotid baroreceptors play a major role in causing arousal from sleep during alveolar hypercapnia in lambs.     

The control of thermoregulation in the developing lamb during slow wave sleep

This study investigates the mechanisms involved in adjusting metabolic rate in response to acute changes in ambient temperature close to thermoneutrality during postnatal development. Twelve lambs were prepared for sequential studies at 4, 14, 30, 45 and 55 days of age. During each study they were maintained at ambient temperatures of 5, 10, 15, 20, 25 and 30 degrees C for at least 1 h and until a slow wave sleep epoch was established. Eight lambs completed all studies. In these there was a significant fall in oxygen consumption with age which was independent of ambient temperature. This effect was closely related to a decrease in plasma triiodothyronine concentration that was greatest between 4- and 14-days old lambs and was not associated with a change in the plasma concentration of thyrotrophin or thyroxine. In 4-days old lambs oxygen consumption was increased at ambient temperatures of 5 and 10 degrees C by non-shivering thermogenesis, whilst in 14- and 30-days old lambs this effect was achieved by shivering. On the basis of significant changes in oxygen consumption and/or the occurrence of shivering (lower critical temperature) and panting (upper critical temperature) we have shown that there is a fall in both upper and lower critical temperature with age and a widening of the thermoneutral zone. This was associated with a decrease in the plasma cortisol concentration and heart rate as measured at thermoneutrality, whilst rectal temperature increased from 4 to 30 days of age. The other 4 lambs, 3 of which died between 7 and 17 days of age, had low plasma triiodothyronine concentrations when studied at 4 and/or 14 days of age and their oxygen consumption at thermoneutrality was significantly lower than the normal group at 14 days. Shivering thermogenesis occurred at an earlier age and control of body temperature was less effective. It is concluded that triiodothyronine has an important role in the control of metabolic rate in the developing lamb even to meet modest changes in ambient temperature, and possibly directly in survival.     

Thermoregulation and the control of breathing during non-REM sleep in the developing lamb.

This study investigates how metabolic rate, as required for thermoregulation, interacts with breathing control during development of the lamb. Fifteen lambs were studied sequentially at 4, 14, 30, 45 and 55 days of age. During each study they were maintained at ambient temperatures of 5, 10, 15, 20, 25 and 30 degrees C for at least 1 h before measurements were made during N-REM sleep. Basal oxygen consumption fell from 16.1 +/- 0.72 (+/- SEM) to 10.1 +/- 0.47 ml/min per kg between 4 and 55 days of age, while breathing frequencies fell from 52.3 +/- 4.4 to 32.4 +/- 1.6 breaths/min over this period. Ventilation increased as oxygen consumption increased on cooling below thermoneutrality. In 4 days-old lambs this was achieved by an increase in breath amplitude, whilst in older lambs breathing frequency also rose. As breathing frequency fell there was a greater incidence of expiratory laryngeal braking at thermoneutrality associated with lengthened expiratory time. The ambient temperature at which these effects occurred, together with panting thresholds, progressively changed with age as the upper and lower critical temperatures fell and the thermoneutral range widened during development. It is concluded that metabolic rate provides a powerful stimulus to breathing in infant lambs. As the metabolic stimulus decreases with age, basal breathing frequency falls and expiratory laryngeal braking becomes important not only to protect lung volume, but also, through airway mechanosensory reflexes, in regulating breath time. This interaction is also particularly apparent as the metabolic and respiratory requirements alter to meet changes in ambient conditions.     

Effects of increase in body temperature on the breathing pattern in premature infants

This study was designed to determine the effects of a mild increase in body temperature within the physiological range (0.8 degrees C) in healthy premature infants. Seven unsedated premature infants (38.4 wk +/- 1.5 postconceptional age) were monitored polygraphically during "morning naps" in an incubator under two different environmental temperatures: (1) normothermia with the incubator temperature set at 25 degrees C and the rectal temperature equal to 36.9 degrees C +/- 0.1; (2) hyperthermia with the incubator temperature set at 35 degrees C and the rectal temperature equal to 37.7 degrees C +/- 0.15. Respiratory frequency and heart rate, respiratory events, i.e., central and obstructive apnea, and periodic breathing with and without apneic oscillations were tabulated. Results for respiratory events were expressed as (1) indices of the total number of respiratory events, and of specific respiratory events per hour of total, quiet and active sleep times; (2) duration of total and specific respiratory events expressed as a percentage of total sleep, quiet and active sleep times. Respiratory frequency and heart rate were significantly increased by hyperthermia (P less than 0.05). Hyperthermia did not significantly modify the indices or the duration of central and obstructive apnea. But the indices and the duration of periodic breathing with and without apneic oscillations were significantly increased by hyperthermia during active sleep (P less than 0.05) but not during quiet sleep. The present study shows that a mild increase in body temperature within the physiological range in premature infants enhances the instability of the breathing pattern during active sleep.     

Influence of repeated exposure to rapidly developing hypoxaemia on the arousal and cardiopulmonary response to rapidly developing hypoxaemia in lambs

Experiments were done on four lambs to determine if repeated exposure to rapidly developing hypoxaemia influences the cardiopulmonary and arousal response from sleep. Each lamb was anaesthetized and instrumented for sleep staging and measurements of arterial haemoglobin oxygen saturation. No sooner than three days after surgery, measurements were made in quiet sleep and active sleep during control periods when the animal was breathing 21% oxygen and during experimental periods of rapidly developing hypoxaemia when the animal was breathing 5% oxygen for approximately 100 epochs of sleep. Arousal occurred from both sleep states during rapidly developing hypoxaemia but was delayed in active sleep compared to quiet sleep. The time to arousal and the decrease in arterial haemoglobin oxygen saturation were significantly increased with repeated exposure to rapidly developing hypoxaemia during both quiet sleep and active sleep. Thus, our data provide evidence that repeated exposure to rapidly developing hypoxaemia produces an arousal response decrement in lambs. Since it is possible that alterations in the arousal response to respiratory stimuli play a role in sudden infant death, studies to investigate the mechanism of the arousal response decrement following repeated exposure to rapidly developing hypoxaemia are warranted.     

The interaction of the upper airway and thermo-metabolism on respiratory rhythm during non-REM sleep in the developing lamb.

This study investigates the role of metabolic rate and of vagal airway mechanisms in sustaining rhythmic breathing in the developing lamb. Fifteen lambs were prepared, at 2 days of age under fluothane anaesthesia, for sequential studies at 4, 14, 30, 45, and 55 days of age. At each age they were maintained at an ambient temperature of 5, 10, 15, 20, 25 and 30 degrees C for at least one hour before measurements were made during N-REM sleep. In 6 lambs at 4 days and in all lambs at older ages the upper airway was by-passed (by opening a tracheal window) for 10-15 minutes at each ambient temperature. Oxygen consumption was unaffected by upper airway by-pass and there were no consistent changes in mean breathing frequency or amplitude, with the exception of shifts to panting at warm ambient temperatures. Breathing pattern was unaffected by upper airway by-pass in lambs at 4 days of age, but at older ages loss of regularity of breathing frequently occurred (up to 47% of 30 days-old lambs at 25 degrees C). This was related to the fall in oxygen consumption with age and to basal values at thermoneutrality, and coincided with lower respiratory rates and increased use of expiratory laryngeal braking. Periodic breathing (and apnea) of a fixed cycle length (9.3 +/- 0.36 s) was a common feature (62%) of the observed breathing dysrhythmia. In young lambs high metabolic rate sustained high frequency rhythmic breathing which was unaffected by upper airway by-pass.(ABSTRACT TRUNCATED AT 250 WORDS)     

Active glottal closure during central apneas limits oxygen desaturation in premature lambs.

Our laboratory previously reported that active glottal closure was present in 90% of spontaneous central apneas in premature lambs while maintaining a high-apneic lung volume (Renolleau S, Letourneau P, Niyonsenga T, and Praud JP. Am J Respir Crit Care Med 159: 1396-1404, 1999.) The present study aimed at testing whether this mechanism limits postapnea oxygen desaturation. Four premature lambs were instrumented for recording states of alertness, thyroarytenoid muscle and diaphragm electromyographic (EMG) activity, nasal airflow, lung volume changes, and pulse oximetry. One thousand four hundred fifty-two spontaneous central apneas (isolated or during periodic breathing) were analyzed in nonsedated lambs. Apneas, with high lung volume maintained by active glottal closure, were compared with apneas, with a tracheostomy opened at apnea onset. Oxygen desaturation slopes were lower when high-apneic lung volume was actively maintained during both wakefulness and quiet sleep. Furthermore, oxygen desaturation slopes were lower after isolated apneas with continuous thyroarytenoid EMG during wakefulness, compared with apneas with noncontinuous thyroarytenoid EMG (= glottis opened shortly after apnea onset). These results highlight the importance of maintaining high-alveolar oxygen stores during central apneas by active glottal closure to limit desaturation in newborns.     

The effect of short-term sleep fragmentation produced by intense auditory stimuli on the arousal response to upper airway obstruction in lambs

Upper airway obstruction is recognized to cause apnoea in newborns as well as in adults. However, very little is known about factors that influence the arousal response from sleep during upper airway obstruction in newborns. Experiments were therefore done to investigate the effect of short-term sleep fragmentation on the arousal response to upper airway obstruction in six lambs aged 8 to 14 days. Each lamb was anaesthetized and instrumented for recordings of electrocorticogram, electro-oculogram, nuchal and diaphragm electromyograms and measurements of systemic arterial blood pressure and oxygen saturation (fiberoptic catheter oximeter). A tracheostomy was done and a fenestrated tracheostomy tube placed in the trachea. Experiments were not done before the third postoperative day. During a study, a 5F balloon tipped catheter was inserted into the tube so that airflow could be obstructed by inflating the balloon. Measurements were made during 30 s control periods and during experimental periods of upper airway obstruction in at least three epochs of quiet sleep and active sleep in each animal. These measurements were made following a period of uninterrupted sleep and repeated following a 36-42 h period of sleep fragmentation. Sleep fragmentation was produced by 30 s of noise separated by 2 min of quiet. Sleep fragmentation produced small but statistically significant increases in the time to arousal and decreases in the haemoglobin oxygen saturation at arousal during upper airway obstruction in quiet sleep but not active sleep. However, these changes, although consistent, were small and are of questionable biological significance. Therefore, I believe it is unlikely that short-term sleep fragmentation per se significantly impairs the arousal response to respiratory stimuli in newborns.     

Ambient temperature-dependent thermoregulatory role of REM sleep

Changes in ambient temperature produce complex effects on sleep–wakefulness. In order to find out the mechanisms involved in temperature-sensitive changes in sleep in rats, their thermal preference, body temperature and sleep were studied before and after the destruction of both peripheral and central warm receptors, by systemic administration of 375 mg/kg capsaicin. Though the pre-treated rats preferred to stay mostly at the ambient temperature of 27 °C, post-treated rats strayed freely into chambers having ambient temperature of 30 °C and 33 °C. Sleep and body temperature of these rats were studied for six hours each, when they were kept at an ambient temperature of 18–36 °C. Total sleep time, especially REM sleep, was maximum at 30 °C in pre-treated rats, but this REM sleep peak at 30 °C disappeared after capsaicin administration. Body temperature increased sharply in post-treated rats, at ambient temperatures above 30 °C. Apart from the ability to defend body temperature at high ambient temperature, avoidance of warm ambient temperature and increase in REM sleep are the behavioral measures which are lost in post-treated rats. Results of this study suggest that the ambient temperature-related increase in REM sleep at 30 °C could be part of the thermoregulatory measures.     

Effects of Ambient Temperature on Sleep and Cardiovascular Regulation in Mice: The Role of Hypocretin/Orexin Neurons

The central neural pathways underlying the physiological coordination between thermoregulation and the controls of the wake-sleep behavior and cardiovascular function remain insufficiently understood. Growing evidence supports the involvement of hypocretin (orexin) peptides in behavioral, cardiovascular, and thermoregulatory functions. We investigated whether the effects of ambient temperature on wake-sleep behavior and cardiovascular control depend on the hypothalamic neurons that release hypocretin peptides. Orexin-ataxin3 transgenic mice with genetic ablation of hypocretin neurons (n = 11) and wild-type controls (n = 12) were instrumented with electrodes for sleep scoring and a telemetric blood pressure transducer. Simultaneous sleep and blood pressure recordings were performed on freely-behaving mice at ambient temperatures ranging between mild cold (20°C) and the thermoneutral zone (30°C). In both mouse groups, the time spent awake and blood pressure were higher at 20°C than at 30°C. The cold-related increase in blood pressure was significantly smaller in rapid-eye-movement sleep (REMS) than either in non-rapid-eye-movement sleep (NREMS) or wakefulness. Blood pressure was higher in wakefulness than either in NREMS or REMS at both ambient temperatures. This effect was significantly blunted in orexin-ataxin3 mice irrespective of ambient temperature and particularly during REMS. These data demonstrate that hypocretin neurons are not a necessary part of the central pathways that coordinate thermoregulation with wake-sleep behavior and cardiovascular control. Data also support the hypothesis that hypocretin neurons modulate changes in blood pressure between wakefulness and the sleep states. These concepts may have clinical implications in patients with narcolepsy with cataplexy, who lack hypocretin neurons.     

Radiant heat affects thermoregulation and energy expenditure during rewarming from torpor

The high expenditure of energy required for endogenous rewarming is one of the widely perceived disadvantages of torpor. However, recent evidence demonstrates that passive rewarming either by the increase of ambient temperature or by basking in the sun appears to be common in heterothermic birds and mammals. As it is presently unknown how radiant heat affects energy expenditure during rewarming from torpor and little is known about how it affects normothermic thermoregulation, we quantified the effects of radiant heat on body temperature and metabolic rate of the small (body mass 25 g) marsupial Sminthopsis macroura in the laboratory. Normothermic resting individuals exposed to radiant heat were able to maintain metabolic rates near basal levels (at 0.91 ml O(2) g(-1) h(-1)) and a constant body temperature down to an ambient temperature of 12 degrees C. In contrast, metabolic rates of individuals without access to radiant heat were 4.5-times higher at an ambient temperature of 12 degrees C and body temperature fell with ambient temperature. During radiant heat-assisted passive rewarming from torpor, animals did not employ shivering but appeared to maximise uptake of radiant heat. Their metabolic rate increased only 3.2-times with a 15- degrees C rise of body temperature (Q(10)=2.2), as predicted by Q(10) effects. In contrast, during active rewarming shivering was intensive and metabolic rates showed an 11.6-times increase. Although body temperature showed a similar absolute change between the beginning and the end of the rewarming process, the overall energetic cost during active rewarming was 6.3-times greater than that during passive, radiant heat-assisted rewarming. Our study demonstrates that energetic models assuming active rewarming from torpor at low ambient temperatures can substantially over-estimate energetic costs. The low energy expenditure during passive arousal provides an alternative explanation as to why daily torpor is common in sunny regions and suggests that the prevalence of torpor in low latitudes may have been under-estimated in the past.     

Nitric oxide inhibition abolishes sleep-wake differences in cerebral circulation

Nitric oxide (NO), being produced by active neurones and also being a cerebral vasodilator, may couple brain activity and blood flow in sleep, particularly during active sleep (AS), which is characterized by widespread neural activation and markedly elevated cerebral blood flow (CBF) compared with quiet wakefulness (QW) and quiet sleep (QS). This study examined CBF and cerebral vascular resistance (CVR) in lambs (n = 6) during spontaneous sleep-wake cycles before and after infusion of N(omega)-nitro-L-arginine (L-NNA), an inhibitor of NO synthase. L-NNA infusion produced increases in CVR and decreases in CBF during all sleep-wake stages, with the greatest changes occurring in AS (DeltaCVR, 88 +/- 19%; DeltaCBF -24 +/- 8%). The characteristic CVR and CBF differences among AS, QS, and QW disappeared within 1-3 h of L-NNA infusion, but had reappeared by 24 h despite persisting cerebral vasoconstriction. These experiments show that NO promotes cerebral vasodilatation during sleep as well as wakefulness, particularly during AS. Additionally, NO is the major, although not sole, determinant of the CBF differences that exist between sleep-wake states.     

Arousal response to upper airway obstruction in young lambs: comparison of nasal and tracheal occlusion

Experiments were done on seven lambs to determine if site of occlusion--nasal versus tracheal--influences the cardiopulmonary and arousal responses from sleep to upper airway obstruction. Each lamb was anesthetized and instrumented for sleep staging and measurements of heart rate and arterial hemoglobin oxygen saturation. A tracheostomy was also done and a fenestrated tracheostomy tube placed in the trachea. Prior to an experiment, A 5F balloon-tipped catheter was inserted through the decannulation cannula into the tracheostomy tube so that tracheal occlusions could be accomplished by inflating the balloon. In addition, a 5F balloon-tipped catheter was inserted into the inlet of a pre-formed silicone mask sealed to the animals snout with silicone rubber foam so that nasal occlusions could be accomplished by inflating the balloon. During an experiment, measurements were made in quiet sleep and in active sleep during control periods of tidal breathing and during experimental periods of nasal or tracheal occlusion. Upper airway obstruction was terminated by deflating the balloon once the animal aroused from sleep. Arousal occurred sooner following nasal occlusion than during tracheal occlusion in quiet sleep; 64 percent of arousals occurred within five seconds of nasal occlusion whereas only 14 percent of arousals occurred within five seconds of tracheal occlusion in quiet sleep. In addition, SaO2 and heart rate decreased more before arousal following tracheal occlusion than following nasal occlusion. However, there was not a significant effect of site of obstruction on time to arousal or the change in SaO2 before arousal in active sleep.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pituitary adenylate cyclase-activating polypeptide maintains neonatal breathing but not metabolism during mild reductions in ambient temperature

Mild reductions in ambient temperature dramatically increase the mortality of neonatal mice deficient in pituitary adenylate cyclase-activating polypeptide (PACAP), with the majority of animals succumbing in the second postnatal week. During anesthesia-induced hypothermia, PACAP(-/-) mice at this age are also vulnerable to prolonged apneas and sudden death. From these observations, we hypothesized that before the onset of genotype-specific mortality and in the absence of anesthetic, the breathing of PACAP-deficient mice is more susceptible to mild reductions in ambient temperature than wild-type littermates. To test this hypothesis, we recorded breathing in one group of postnatal day 4 PACAP+/+, (+/-), and (-/-) neonates (using unrestrained, flow-through plethysmography) and metabolic rate in a separate group (using indirect calorimetry), both of which were exposed acutely to ambient temperatures slightly below (29 degrees C), slightly above (36 degrees C), or at thermoneutrality (32 degrees C). At 32 degrees C, the breathing frequency of PACAP(-/-) neonates was significantly less than PACAP+/+ littermates. Reducing the ambient temperature to 29 degrees C caused a significant suppression of tidal volume and ventilation in both PACAP+/- and (-/-) animals, while the tidal volume and ventilation of PACAP+/+ animals remained unchanged. Genotype had no effect on the ventilatory responses to ambient warming. At all three ambient temperatures, genotype had no influence on oxygen consumption or body temperature. These results suggest that during mild reductions in ambient temperature, PACAP is vital for the preservation of neonatal tidal volume and ventilation, but not for metabolic rate or body temperature.     

The Effect of Old Age on the Free-Running Period of Circadian Rhythms in Rat

The free-running period is regarded to be an exclusive feature of the endogenous circadian clock. Changes during aging in the free-running period may therefore reflect age-related changes in the internal organization of this clock. However, the literature on alterations in the free-running period in aging is not unequivocal. In the present study, with various confounding factors kept to a minimum, it was found that the free-running periods for active wakefulness, body temperature, and drinking behavior were significantly shorter (by 12-17 min) in old than in young rats. In addition, it was found that the day-to-day stability of the different sleep states was reduced in old rats, whereas that of the drinking rhythm was enhanced. Transient cycles were not observed, nor were there any age-related differences in daily totals of the various sleep-wake states. The amplitudes of the circadian rhythms of active wakefulness, quiet sleep, and temperature were reduced, whereas those of paradoxical sleep and quiet wakefulness remained unchanged.     

Laryngeal response to nasal ventilation in nonsedated newborn lambs.

Although endoscopic studies in adult humans have suggested that laryngeal closure can limit alveolar ventilation during nasal intermittent positive pressure ventilation (nIPPV), there are no available data regarding glottal muscle activity during nIPPV. In addition, laryngeal behavior during nIPPV has not been investigated in neonates. The aim of the present study was to assess laryngeal muscle response to nIPPV in nonsedated newborn lambs. Nine newborn lambs were instrumented for recording states of alertness, electrical activity [electromyograph (EMG)] of glottal constrictor (thyroarytenoid, TA) and dilator (cricothyroid, CT) muscles, EMG of the diaphragm (Dia), and mask and tracheal pressures. nIPPV in pressure support (PS) and volume control (VC) modes was delivered to the lambs via a nasal mask. Results show that increasing nIPPV during wakefulness and quiet sleep led to a progressive disappearance of Dia and CT EMG and to the appearance and subsequent increase in TA EMG during inspiration, together with an increase in trans-upper airway pressure (TUAP). On rare occasions, transmission of nIPPV through the glottis was prevented by complete, active glottal closure, a phenomenon more frequent during active sleep epochs, when irregular bursts of TA EMG were observed. In conclusion, results of the present study suggest that active glottal closure develops with nIPPV in nonsedated lambs, especially in the VC mode. Our observations further suggest that such closure can limit lung ventilation when raising nIPPV in neonates.