Volume of activation of the Hering-Breuer inflation reflex in the newborn infant.

Although the Hering-Breuer inflation reflex (HBIR) is active within tidal breathing range in the neonatal period, there is no information regarding whether a critical volume has to be exceeded before any effect can be observed. To explore this, effects of multiple airway occlusions on inspiratory and expiratory timing were measured throughout tidal breathing range using a face mask and shutter system. In 20 of the 22 healthy infants studied, there was significant shortening of inspiration because the volume at which occlusion occurred rose from functional residual capacity (FRC) to end-inspiratory volume [14.9% reduction in inspiratory time (per ml/kg increase in lung volume at occlusion)]. All infants showed a significant increase in expiratory time [17.1% increase (per ml/kg increase in lung volume at occlusion)]. Polynomial regression analyses revealed a progressive increase in strength of HBIR from FRC to approximately 4 ml/kg above FRC. Eighteen infants showed no further shortening of inspiratory time and 10 infants no further lengthening of expiratory time with increasing occlusion volumes, indicating maximal stimulation of the reflex had been achieved. There was a significant relationship between strength of HBIR and respiratory rate, suggesting that HBIR modifies the breathing pattern in the neonatal period.     

Light-dark differences in the effects of ambient temperature on gaseous metabolism in newborn rats.

Body temperature (T(b)) of rat pups (7-9 days old) raised under a 12:12-h light-dark (L-D) regimen (L: 0700-1900, D: 1900-0700) was consistently higher in D than in L by approximately 1.1 degrees C. We tested the hypothesis that the L-D differences in T(b) were accompanied by differences in the set point of thermoregulation. Measurements were performed on rat pups at 7-9 days after birth. O(2) consumption (VO(2)) and CO(2) production (VCO(2)) were measured with an open-flow method during air breathing, as ambient temperature (T(a)) was decreased from 40 to 15 degrees C at the constant rate of 0.5 degrees C/min. At T(a) >/=33 degrees C, VO(2) was not significantly different between L and D, whereas VCO(2) was higher in L, suggesting a greater ventilation. Over the 33 to 15 degrees C range the VO(2) values in D exceeded those in L by approximately 30%. Specifically, the difference was contributed by differences in thermogenesis at T(a) = 30 to 20 degrees C. As T(a) was decreased, the critical temperature at which VO(2) began to rise was lower in L. We conclude that the higher T(b) of rat pups in D is accompanied by a higher set point for thermoregulation and a greater thermogenesis. These results are consistent with the idea that, in newborns, endogenous changes in the set point of thermoregulation contribute to the circadian oscillations of T(b).     

The reflex ventilatory responses of conscious, newborn rats to alternations of inspiratory oxygen concentration.

We examined the effect of a dynamic, hypoxic stimulus upon the reflex respiratory responses of 15, conscious rat pups on post-natal days 5-7 in order to ascertain the influence of a non-adapting peripheral chemoreceptor discharge upon respiratory control during hypoxia in the newborn. Respiration was measured as integrated airflow into and out of a body plethysmograph. The respiratory response to 6 minutes of a 16-breath cycle (approximately 5 s) in FiO2 between 0.21 and 0.10 (alternating hypoxia) was compared with the response to 6 min of a constant FiO2 of 0.12 (non-alternating hypoxia). Ventilation increased significantly from a control level of 0.12 +/- 0.02 ml/s (mean +/- SEM) to 0.18 +/- 0.02 and 0.17 +/- 0.02 ml/s in non-alternating and alternating hypoxia runs respectively during the first minute (phase 1) of each run, after which ventilation in both run types fell progressively and significantly back towards control levels to reach, by the sixth minute (phase 2), 0.13 +/- 0.01 and 0.12 +/- 0.02 ml/s respectively. No significant difference was found between the levels of ventilation in non-alternating hypoxia and alternating hypoxia during either phase 1 (P greater than 0.10) or phase 2 (P greater than 0.60). No significant alternation was found in any respiratory variable at the frequency of the 16-breath hypoxic cycle during either phase 1 or phase 2 of non-alternating hypoxia. However, a significant alternation, at this frequency, of 37 +/- 6% (P less than 0.05 compared to control) was found in ventilation during phase 1 of alternating hypoxia which was further increased to 62 +/- 8% (P less than 0.05 compared to phase 1) during phase 2. In phase 1 the alternation was due primarily to significant alternation in inspiratory time whilst in phase 2 significant alternation also occurred in tidal volume, expiratory time and mean inspiratory flow. Our results show that the magnitude of hypoxic ventilatory depression (HVD) in the newborn is not affected by an alternating hypoxic stimulus and that, during phase 2, ventilation can still be stimulated by peripheral chemoreceptors. We suggest that peripheral chemoreceptor adaptation is unlikely to be a major cause of HVD in the newborn rat and that the magnitude of HVD is, in part, the result of a competitive interaction between peripheral chemoreceptor stimulation and a centrally-mediated inhibitory action of hypoxia.     

The Hering-Breuer reflex in anesthetized infants: end-inspiratory vs. end-expiratory occlusion technique

Bothend-inspiratory (EIO) and end-expiratory (EEO) occlusions have beenused to measure the strength of the Hering-Breuer inflation reflex(HBIR) in infants. The purpose of this study was to compare bothtechniques in anesthetized infants. In each infant, HBIR activity wascalculated as the relative prolongation of expiratory and inspiratorytime during EIO and EEO, respectively. Respiratory drive was assessedfrom the change in airway pressure during inspiratory effort againstthe occlusion, both at a fixed time interval of 100 ms(P_0.1) and a fixed proportion(10%) of the occluded inspiratory time(P_10%). Twenty-two infants [age 14.3 ± 6.4 (SD) mo] were studied. No HBIR activitywas present during EIO [11.8 ± 15.9 (SD) %]. Bycontrast, there was significant, albeit weak, reflex activity duringEEO [HBIR: 27.2 ± 17.4%]. A strong HBIR (up to 310%)was elicited in six of seven infants in whom EIO was repeated afterlung inflation. P_0.1 was similar during both types of occlusions, whereas mean ± SDP_10% was lower during EEO thanduring EIO: 0.198 ± 0.09 vs. 0.367 ± 0.15 kPa, respectively(P < 0.01). These data suggest adifference in the central integration of stretch receptor activity ininfants during anesthesia compared with during sleep.

     

Postnatal development of the Hering-Breuer reflex in the rat

The intensity of the Breuer-Hering inflation reflex was studied in newborn (1 day old), in young (8 days old) and in adult rats (90 days old) under urethane general anaesthesia (1.3 g/kg i.p.). The inflation pressure was adjusted with the aid of a water-valve. The reflex was present in all 3 age groups. An inflation pressure of 0.2 kPa applied in the course of expiration produced a long lasting apnoea in newborn rats which lasted 48 normal respiratory cycles. An inflation pressure of 0.5 kPa in young rats induced an apnoea lasting for only 3 normal respiratory cycles, whereas a pressure of 1 kPa in adult rats led to an apnoea which lasted for 20 normal respiratory cycles. The compliance of the respiratory system in relation to lung weight is approximately 5 times higher in adult rats compared with that of newborn rats. It is approximately double in comparison with young rats. The pressures of inflation mentioned in the 3 age categories can be considered as equieffective from the point of stimulation pulmonary stretch receptors. It can be concluded from these findings that the reflex of Breuer-Hering in newborn rats is more potent in comparison with adult rats, but it is lower in young rats at the age of 8 days. It is suggested that the differences observed are due to functional and anatomical maturation.     

31P-NMR studies of cerebral metabolic changes during graded hypoxia in newborn lambs

We measured cerebral phosphocreatine (PCr), inorganic phosphate (Pi), ATP, and intracellular pH (pHi) with in vivo phosphorus nuclear magnetic resonance (NMR) during 10- to 15-min periods of reversible hypoxic hypoxia in 20 newborn lambs (1-11 days). There was a significant correlation between arterial O2 partial pressure (PaO2) and the PCr/Pi ratio or pHi; however, between PaO2 130-33 mmHg, metabolite changes were not significant. PCr/Pi and pHi decreased significantly when PaO2 was lowered below 33 and 28 mmHg, respectively. After recovery, metabolite ratios and pHi returned to base-line values within 5 min. During the early phases of hypoxia and recovery, there were large fluctuations in metabolites and pHi, indicating that mitochondrial reactions were not in a steady state. After several minutes of hypoxia or recovery, PCr/Pi and pHi stabilized, suggesting steady state kinetics for mitochondrial respiration. NMR is extremely sensitive to changes in mitochondrial oxygenation, and stable PCr/Pi and pHi indicate that O2 tension in cerebral mitochondria of the newborn lamb is constant between PaO2 of 30 and 140 mmHg.     

Systemic hypoxia increases leukocyte emigration and vascular permeability in conscious rats.

We recently observed that acute systemic hypoxia produces rapid increases in leukocyte adherence in the mesenteric microcirculation of the anesthetized rat Wood JG, Johnson JS, Mattioli LF, and Gonzalez NC. J Appl Physiol 87: 1734-1740, 1999; Wood JG, Mattioli LF, and Gonzalez NC. J Appl Physiol 87: 873-881, 1999. Hypoxia-induced leukocyte adherence is associated with an increase in reactive oxygen species (ROS) generation and is attenuated by antioxidants or interventions that increase tissue levels of nitric oxide (NO). These results suggest that the acute effects of hypoxia on leukocyte-endothelial interactions are caused by a change in the ROS-NO balance. The present experiments were designed to extend our observations of the initial microcirculatory response to hypoxia; specifically, we wanted to determine whether the response to systemic hypoxia involves increased microvascular permeability and leukocyte emigration and whether ROS generation and decreased NO levels contribute to these responses. At this time, there is conflicting evidence, from in vitro studies, regarding the effect of hypoxia on these indexes of vascular function. Our studies were carried out in the physiological setting of the conscious animal, in which a prolonged hypoxic exposure is possible without the adverse effects that may develop under anesthesia. The central observation of these studies is that conscious animals exposed for 4 h to environmental hypoxia show increased microvascular permeability and emigration of leukocytes into the extravascular space of the mesenteric circulation. Furthermore, these events are dependent on increased ROS generation and, possibly, a subsequent decrease in tissue NO levels during systemic hypoxia. Our results show that systemic hypoxia profoundly affects vascular endothelial function through changes in the ROS-NO balance in the conscious animal.     

不同环境温度对有机磷杀虫剂毒死蜱引起大鼠体温变化的影响

目的: 观察不同环境温度对有机磷杀虫剂毒死蜱(CHP)引起大鼠体温变化的影响.方法: 用数字体温仪测量大鼠的结肠和尾部皮肤温度,观察25℃、16℃和32℃环境温度对口饲CHP引起结肠温度和尾部皮肤温度变化的影响.结果: 给置于25℃和16℃环境中的大鼠口饲CHP (20 mg·kg-1) 后,均可引起结肠温度明显的降低,尾部皮肤温度明显升高;但32℃环境中大鼠口饲CHP后却引起了明显的升温作用,而尾部皮肤温度无明显影响.结论: CHP对大鼠体温的影响与环境温度有关.     

Body temperature regulation during acclimation to cold and hypoxia in rats

Extreme environmental conditions present challenges for thermoregulation in homoeothermic organisms such as mammals. Such challenges are exacerbated when two stressors are experienced simultaneously and each stimulus evokes opposing physiological responses. This is the case of cold, which induces an increase in thermogenesis, and hypoxia, which suppresses metabolism conserving oxygen and preventing hypoxaemia. As an initial approach to understanding the thermoregulatory responses to cold and hypoxia in a small mammal, we explored the effects of acclimation to these two stressors on the body temperature (T_b) and the daily and ultradian T_b variations of Sprague-Dawley rats. As T_b is influenced by sleep-wake cycles, these T_b variations reflect underlying adjustments in set-point and thermosensitivity. The T_b of rats decreased precipitously during initial hypoxic exposure which was more pronounced in cold (T_b=33.4±0.13) than in room temperature (T_b=35.74±0.17) conditions. This decline was followed by an increase in T_b stabilising at a new level ~0.5 °C and ~1.4 °C below normoxic values at room and cold temperatures, respectively. Daily T_b variations were blunted during hypoxia with a greater effect in the cold. Ultradian T_b variations exhibited daily rhythmicity that disappeared under hypoxia, independent of ambient temperature. The adjustments in T_b during hypoxia and/or cold are in agreement with the hypothesis that an initial decrease in the T_b set-point is followed by its partial re-establishment with chronic hypoxia. This rebound of the T_b set-point might reflect cellular adjustments that would allow animals to better deal with low oxygen conditions, diminishing the drive for a lower T_b set-point. Cold and hypoxia are characteristic of high altitude environments. Understanding how mammals cope with changes in oxygen and temperature will shed light into their ability to colonize new environments along altitudinal clines and increase our understanding of how T_b is regulated under stimuli that impose contrasting physiological constraints.     

NO-dependent effects during adaptation of rats to intermittent hypoxia

In experiments on Wistar rats processes nitric oxide production on concentration of anions (NO2-, NO3-), carbamide and polyamines contents were investigated in processes of rats adaptation to acute hypoxia (7% O2 in N2, 30 min) and intermittent hypoxia training (10% O2 in N2, 15 min, 5 cycles daily) during 14 days. NO production by oxygen-dependent and oxygen-independent metabolites paths has been investigated. It is concluded that the disturbances in nitric oxide system induced by acute hypoxia by L-arginine injections may result in acute hypoxia.