Hypoxemia and reoxygenation with 21% or 100% oxygen in newborn pigs: changes in blood pressure, base deficit, and hypoxanthine and brain morphology

Pulmonary hemodynamics in newborn piglets during hypoxemia and reoxygenation: blocking of the endothelin-1 receptors

The effects of blocking endothelin (ET) receptors in pulmonary circulation during hypoxemia and reoxygenation were studied in five groups of piglets. Ten minutes before hypoxemia, the Hyp group (n = 10) was given saline and the 1-mg (n = 9) and 5-mg group (n = 9), respectively, were given 1 and 5 mg/kg i.v. SB 217242 (an ET receptor antagonist). Two groups served as normoxic controls. The piglets were ventilated with 8% O2 until base excess was <-20 mmol/L or mean arterial blood pressure was <20 mm Hg. Reoxygenation was performed with air. The increase of mean pulmonary artery pressure was significantly attenuated during hypoxemia and reoxygenation in the 1-mg group (p = 0.006). The pulmonary vascular resistance index increased significantly at the end of hypoxemia in the Hyp and 5-mg groups but was comparable to baseline in the 1-mg group. During the study period, the changes in pulmonary vascular resistance index were significantly attenuated in the 1-mg group compared with the 5-mg group. Stroke volume index was significantly attenuated compared with baseline in the 5-mg group during both hypoxemia and reoxygenation, whereas, in the Hyp and 1-mg group, stroke volume index was attenuated only at the end of hypoxemia. During hypoxemia, plasma ET-1 decreased from 1.9+/-0.2 to 1.3+/-0.3 ng/L (p = 0.008) in the Hyp group, remained unchanged in the 1-mg group, and increased from 1.6+/-0.2 to 6.6+/-1.6 ng/L (p = 0.008) in the 5-mg group. We conclude that blocking ET receptors attenuates pulmonary vasoconstriction during hypoxemia and reoxygenation in piglets.

Pulmonary hemodynamics and plasma endothelin-1 during hypoxemia and reoxygenation with room air or 100% oxygen in a piglet model

The immediate effect on the pulmonary circulation of reoxygenation with either room air or 100% O2 was studied in newborn piglets. Hypoxemia was induced by ventilation with 8% O2 until base excess was <-20 mmol/L or mean arterial blood pressure was <20 mm Hg. Reoxygenation was performed with either room air (n = 9) or 100% O2 (n = 9). Mean pulmonary artery pressure increased during hypoxemia (p = 0.012). After 5 min of reoxygenation, pulmonary artery pressure increased further from 24 +/- 2 mm Hg at the end of hypoxemia to 35 +/- 3 mm Hg (p = 0.0077 versus baseline) in the room air group and from 27 +/- 3 mm Hg at the end of hypoxemia to 30 +/- 2 mm Hg (p = 0.011 versus baseline) in the O2 group (NS between groups). Pulmonary vascular resistance index increased (p = 0.0005) during hypoxemia. During early reoxygenation pulmonary vascular resistance index decreased rapidly to values comparable to baseline within 5 min of reoxygenation in both groups (NS between groups). Plasma endothelin-1 (ET-1) decreased during hypoxemia from 1.5 +/- 0.1 ng/L at baseline to 1.2 +/- 0.1 ng/L at the end of hypoxemia (p = 0.003). After 30 min of reoxygenation plasma ET-1 increased to 1.8 +/- 0.3 and 1.5 +/- 0.2 ng/L in the room air and O2 groups, respectively (p = 0.0077 in each group versus end hypoxemia; NS between groups). We conclude that hypoxemic pulmonary hypertension and plasma ET-1 normalizes as quickly when reoxygenation is performed with room air as with 100% O2 in this hypoxia model with newborn piglets.

Resuscitation of asphyxiated newborn infants with room air or oxygen: an international controlled trial: the Resair 2 study

OBJECTIVE

Birth asphyxia represents a serious problem worldwide, resulting in approximately 1 million deaths and an equal number of serious sequelae annually. It is therefore important to develop new and better ways to treat asphyxia. Resuscitation after birth asphyxia traditionally has been carried out with 100% oxygen, and most guidelines and textbooks recommend this; however, the scientific background for this has never been established. On the contrary, theoretic considerations indicate that resuscitation with high oxygen concentrations could have detrimental effects. We have performed a series of animal studies as well as one pilot study indicating that resuscitation can be performed with room air just as efficiently as with 100% oxygen. To test this more thoroughly, we organized a multicenter study and hypothesized that room air is superior to 100% oxygen when asphyxiated newborn infants are resuscitated.

METHODOLOGY

In a prospective, international, controlled multicenter study including 11 centers from six countries, asphyxiated newborn infants with birth weight >999 g were allocated to resuscitation with either room air or 100% oxygen. The study was not blinded, and the patients were allocated to one of the two treatment groups according to date of birth. Those born on even dates were resuscitated with room air and those born on odd dates with 100% oxygen. Informed consent was not obtained until after the initial resuscitation, an arrangement in agreement with the new proposal of the US Food and Drug Administration's rules governing investigational drugs and medical devices to permit clinical research on emergency care without the consent of subjects. The protocol was approved by the ethical committees at each participating center. Entry criterion was apnea or gasping with heart rate <80 beats per minute at birth necessitating resuscitation. Exclusion criteria were birth weight <1000 g, lethal anomalies, hydrops, cyanotic congenital heart defects, and stillbirths. Primary outcome measures were death within 1 week and/or presence of hypoxic-ischemic encephalopathy, grade II or III, according to a modification of Sarnat and Sarnat. Secondary outcome measures were Apgar score at 5 minutes, heart rate at 90 seconds, time to first breath, time to first cry, duration of resuscitation, arterial blood gases and acid base status at 10 and 30 minutes of age, and abnormal neurologic examination at 4 weeks. The existing routines for resuscitation in each participating unit were followed, and the ventilation techniques described by the American Heart Association were used as guidelines aiming at a frequency of manual ventilation of 40 to 60 breaths per minute.

RESULTS

Forms for 703 enrolled infants from 11 centers were received by the steering committee. All 94 patients from one of the centers were excluded because of violation of the inclusion criteria in 86 of these. Therefore, the final number of infants enrolled in the study was 609 (from 10 centers), with 288 in the room air group and 321 in the oxygen group. Median (5 to 95 percentile) gestational ages were 38 (32.0 to 42.0) and 38 (31.1 to 41.5) weeks (NS), and birth weights were 2600 (1320 to 4078) g and 2560 (1303 to 3900) g (NS) in the room air and oxygen groups, respectively. There were 46% girls in the room air and 41% in the oxygen group (NS). Mortality in the first 7 days of life was 12.2% and 15.0% in the room air and oxygen groups, respectively; adjusted odds ratio (OR) = 0.82 with 95% confidence intervals (CI) = 0.50-1.35. Neonatal mortality was 13.9% and 19.0%; adjusted OR = 0. 72 with 95% CI = 0.45-1.15. Death within 7 days of life and/or moderate or severe hypoxic-ischemic encephalopathy (primary outcome measure) was seen in 21.2% in the room air group and in 23.7% in the oxygen group; OR = 0.94 with 95% CI = 0.63-1.40. (ABSTRACT TRUNCATED)

Hypoxemic resuscitation in newborn piglets: recovery of somatosensory evoked potentials, hypoxanthine, and acid-base balance

We tested the hypothesis that hypoxic newborn piglets can be successfully resuscitated with lower O2 concentrations than 21%. Severely hypoxic, 2-4-d-old, anesthetized piglets were randomly divided into five resuscitation groups: 21% O2 (n = 10), 18% O2 (n = 9), 15% O2 (n = 9), 12% O2 (n = 8), all normoventilated, and a hypoventilated 21% O2 group (PaCO2; 7.0-8.0 kPa, n = 9). Base excess (BE) reached -20 +/- 1 mmol/L at the end of hypoxia. After 3 h of resuscitation, BE had risen to -4 +/- 1 mmol/L in the 21% O2, 18% O2, and hypoventilated groups, but was -10 +/- 2 mmol/L in the 15% O2 group (p < 0.05 versus 21% O2 group) and -22 +/- 2 mmol/L in the 12% O2 group (p < 0.05 versus 21% O2 group). Four animals died during resuscitation, all allocated to the 12% O2 group (p < 0.05 versus 21% O2 group). Somatosensory evoked potentials (SEPs) recovered in 39 of 45 piglets, and remained present during resuscitation in all except the 12% O2 group. SEP recovered initially even in six of eight animals in the 12% O2 group, but disappeared again in all later during resuscitation. The SEP amplitude recovered to levels not significantly different from the 21% O2 group in all groups except the 12% O2 group. Plasma hypoxanthine concentrations and extracellular hypoxanthine concentrations in the striatum decreased during resuscitation to levels not significantly different from the 21% O2 group in all but the 12% O2 group (p < 0.05 versus 21% O2 group). In conclusion, severely hypoxic newborn piglets were resuscitated as efficiently with both hypoventilation and 18% O2 as with 21% O2.

Early cerebral metabolic and electrophysiological recovery during controlled hypoxemic resuscitation in piglets

We tested the hypothesis that controlled hypoxemic resuscitation improves early cerebral metabolic and electrophysiological recovery in hypoxic newborn piglets. Severely hypoxic anesthetized piglets were randomly divided into three resuscitation groups: hypoxemic, 21% O2, and 100% O2 groups (8 in each group). The hypoxemic group was mechanically ventilated with 12-18% O2 adjusted to achieve a cerebral venous O2 saturation of 17-23% (baseline; 45 +/- 1%). Base excess (BE) reached -22 +/- 1 mM at the end of hypoxia. During a 2-h resuscitation period, no significant differences in time to recovery of electroencephalography (EEG), quality of EEG at recovery, or extracellular hypoxanthine concentrations in the cerebral cortex and striatum were found among the groups. BE and plasma hypoxanthine, however, normalized significantly more slowly during controlled hypoxemic resuscitation than during resuscitation with 21 or 100% O2. We conclude that early brain recovery during controlled hypoxemic resuscitation was as efficient as, but not superior to, recovery during resuscitation with 21 or 100% O2. The systemic metabolic recovery from hypoxia, however, was delayed during controlled hypoxemic resuscitation.

Plasma hypoxanthine reacts more abruptly to changes in oxygenation than base deficit and uric acid in newborn piglets

Previously, high postmortem concentrations of hypoxanthine have been found in vitreous humor of children dying from sudden infant death syndrome (SIDS). We wanted to investigate further the accumulation of hypoxanthine in vitreous humor during hypoxia. Twenty-four piglets aged 9-15 days were exposed to continuous hypoxemia (180 min 11% O2, n = 6), long interval intermittent hypoxemia (60 min 11% O2, 20 min room air, n = 7) or short interval intermittent hypoxemia (10 min 9% O2, 10 min room air with (n = 6) or without (n = 5) superimposed ligation of both carotid arteries). The increase in vitreous humor Hyp was four-fold higher (p < 0.01) with ligation of the carotid arteries (14 +/- 2.4 to 38 +/- 8.9 mumol/l) than without ligation (15 +/- 2.8 to 21 +/- 5.9 mumol/l). During continuous hypoxemia, plasma Hyp (r = 0.85), Xa (r = 0.89) uric acid (UA) (r = 0.85), and base deficit (BD) (r = 0.78) increased almost linearly (p < 0.001). Plasma Hyp responded more abruptly to changes in oxygenation than base deficit (BD) and UA. Ligation of the carotid arteries had a strong impact on Hyp accumulation in vitreous humor, suggesting that vitreous humor Hyp is not merely a filtration product of plasma Hyp, but reflects local hypoxia/ischemia in the eye.

Effects of hypoxemia and reoxygenation with 21% or 100% oxygen in newborn piglets: extracellular hypoxanthine in cerebral cortex and femoral muscle

OBJECTIVE

To determine whether reoxygenation with an FIO2 of 0.21 (21% oxygen) is preferable to an FIO2 of 1.0 (100% oxygen) in normalizing brain and muscle hypoxia in the newborn.

DESIGN

Prospective, randomized, animal study.

SETTING

Hospital surgical research laboratory.

SUBJECTS

Twenty-six anesthetized, mechanically ventilated, domestic piglets, 2 to 5 days of age.

INTERVENTIONS

The piglets were randomized to control or hypoxemia groups. Hypoxemia was induced by ventilating the piglets with 8% oxygen in nitrogen, which was continued until mean arterial pressure decreased to <20 mm Hg. After hypoxemia, the piglets were further randomized to receive reoxygenation with an FIO2 of 0.21 (21% oxygen group, n = 9) or an FIO2 of 1.0 for 30 mins followed by an FIO2 of 0.21 (100% oxygen group, n = 9), and followed for 5 hrs. The piglets in the control group were mechanically ventilated with 21% oxygen (n = 8).

MEASUREMENTS AND MAIN RESULTS

We measured extracellular concentrations of hypoxanthine in the cerebral cortex and femoral muscle (in vivo microdialysis), plasma hypoxanthine concentrations, cerebral arterial-venous differences for hypoxanthine, acid base balances, arterial and venous (sagittal sinus) blood gases, and mean arterial pressures. The lowest pH values of 6.91 +/- 0.11 (21% oxygen group, mean +/- SD) and 6.90 +/- 0.07 (100% oxygen group) were reached at the end of hypoxemia and then normalized during the reoxygenation period. Plasma hypoxanthine increased during hypoxemia from 28.1 +/- 9.3 to 119.1 +/- 31.9 micromol/L in the 21% oxygen group (p < .001) and from 32.6 +/0- 14.5 to 135.0 +/- 31.4 micromol/L in the 100% oxygen group (p <.001). Plasma hypoxanthine concentrations then normalized over the next 2 hrs in both groups. In the cerebral cortex, extracellular concentrations of hypoxanthine increased during hypoxemia from 3.9 +/- 2.8 to 20.2 +/- 7.4 micromol/L in the 21% oxygen group (p < .001) and from 5.9 +/- 5.0 to 25.1 +/- 7.1 micromol/L in the 100% oxygen group (p < .001). In contrast to plasma hypoxanthine, extracellular hypoxanthine in the cerebral cortex increased significantly further during early reoxygenation, and, within the first 30 mins, reached maximum values of 24.9 +/- 6.3 micromol/L in the 21% oxygen group (p < .01) and 34.8 +/- 10.9 micromol/L in the 100% oxygen group (p < .001). This increase was significantly larger in the 100% oxygen group than in the 21% oxygen group (9.7 +/- 4.7 vs. 4.7 +/- 2.6 micromol/L, p < .05). There were no significant differences between the two reoxygenated groups in duration of hypoxemia, hypoxanthine concentrations in femoral muscle, plasma hypoxanthine concentrations, pH, or mean arterial pressure. The cerebral arterial-venous difference for hypoxanthine was positive both at baseline, at the end of hypoxemia, and after 30 mins and 300 mins of reoxygenation, and no differences were found between the two reoxygenated groups.

CONCLUSIONS

Significantly higher extracellular concentrations of hypoxanthine were found in the cerebral cortex during the initial period of reoxygenation with 100% oxygen compared with 21% oxygen. Hypoxanthine is a marker of hypoxia, and reflects the intracellular energy status. These results therefore suggest a possibly more severe impairment of energy metabolism in the cerebral cortex or an increased blood-brain barrier damage during reoxygenation with 100% oxygen compared with 21% oxygen in this newborn piglet hypoxia model.

Acute effects on systemic and pulmonary hemodynamics of intratracheal instillation of porcine surfactant or saline in surfactant-depleted newborn piglets

Surfactant instillation may affect systemic and pulmonary hemodynamics. The aim of this study was to investigate whether this effect is specific to surfactant or if it can be triggered by instillation of the same volume of saline. Piglets 3-5-d-old were subjected to repeated lung lavage using 20 mL/kg 0.9% saline until the partial pressure of arterial O2 was < 10 kPa and partial pressure of arterial CO2 was between 4.0 and 6.0 kPa with fraction of inspired oxygen (FiO2) 1.0 and peak inspiratory pressure 25 cm H2O. Porcine surfactant 200 mg/kg (80 mg/mL) or the same volume of 0.9% saline was instilled into the lungs through a feeding catheter entered through the endotracheal tube. Mean arterial blood pressure, pulmonary artery pressure, and cardiac output were measured continuously. There was a significant decrease in mean arterial blood pressure from 67 (+/- 13) mm Hg to 52 (+/- 18) mm Hg (p < 0.05) 210 s after instillation of surfactant. Systemic vascular resistance decreased from 0.42 (+/- 0.18) to 0.34 (+/- 0.18) mm Hg x mL-1 x min x kg (p < 0.05) from 0 min to 180 s after instillation of surfactant. In the group receiving saline instillations there were no significant changes in mean arterial blood pressure or systemic vascular resistance. A transient but significant increase in mean pulmonary artery pressure was seen 120 s after instillation in both groups with a return to presurfactant level 240 s after instillation. Pulmonary vascular resistance increased transiently and significantly only in the group receiving surfactant. We conclude that porcine surfactant causes a decrease in systemic vascular resistance, resulting in a decrease in mean arterial blood pressure in newborn lung-lavaged piglets not seen after instillation of the same volume of saline.

Animal models for the study of perinatal hypoxic-ischemic encephalopathy: a critical analysis

We critically evaluated various design features from 292 animal studies related to perinatal hypoxic-ischemic encephalopathy (HIE). Rodents were the most frequently used animals in HIE research (26%), followed by piglets (23%) and sheep (22%). Asphyxia with or without ischemia was the most predominant method of producing experimental brain damage, but there were significant variations in specific details, particularly regarding the method and duration of brain insult. In 71% (207/292) of studies the CNS outcomes were tested within 24 h of experimental insult and in 29% (85/292) they were tested 24 h or more after the insult. Acute CNS metabolic end-points were assessed in 82-100% of all studies. In 90% of studies the chronological age of the animal was equivalent to that of human term newborn infant. However, in only 23% (67/292) were clinical neurological, developmental or behavioral outcomes evaluated, and in only 26% (76/292) was neuropathology assessed. While no single animal model was found to be ideal for all HIE research, some models were distinctly superior to others, depending upon the specific research question. The fetal sheep, newborn lamb and piglet models are well suited for the study of acute and subacute metabolic and physiologic endpoints, whereas the rodent and primate models could be used for long-term neurological and behavioral outcome experiments as well. We also feel that standardizing the study design features, including an HI insult method that produces consistent and predictable brain damage is urgently needed. Studies in neuro-ethology should explore how well brains of various animals compare with that of the newborn human infant. There is also a need for developing animal models that mimic clinical entities in which long-term neuro-developmental and behavioral outcomes can be assessed.

A piglet survival model of posthypoxic encephalopathy

The aim of this study was to produce a neonatal piglet model which, avoiding vessel ligation, exposed the whole animal to hypoxia and produced dose-dependent clinical encephalopathy and neuropathologic damage similar to that seen after birth asphyxia. Twenty-three piglets were halothane-anesthetized. Hypoxia was induced in 19 piglets by reducing the fractional concentration of inspired oxygen (FiO2) to the maximum concentration at which the EEG amplitude was below 7 microV (low amplitude) for 17-55 min. There were transient increases in Fio2 to correct bradycardia and hypotension. Posthypoxia, the piglets were extubated when breathing was stable. Four were sham-treated controls. We aimed at 72-h survival; seven died prematurely due to posthypoxic complications. EEG and a videotaped itemized neurologic assessment were recorded regularly. We found that 95% of the animals showed neuropathologic damage. The duration of low amplitude EEG during the insult and the arterial pH at the end of the insult correlated with cortical/white matter damage; r = 0.75 and 0.81, respectively. Early postinsult EEG background amplitude (r = 0.86 at 3 h) and neurologic score (r = 0.79 at 8 h) correlated with neuropathology. Epileptic seizures in seven animals were always associated with severe neuropathologic damage. We conclude that EEG-controlled hypoxia and subsequent intensive care enabled the animals to survive with an encephalopathy which correlated with the cerebral hypoxic insult. The encephalopathy was clinically, electrophysiologically, and neuropathologically similar to that in the asphyxiated term infant. This model is suitable for examining mechanisms of damage and evaluation of potential protective therapies after birth asphyxia.

Neonatal hemodynamic responses to extreme ranges of controlled graded hypoxia

OBJECTIVES

To determine the hemodynamic responses to a wide range of specific, controlled, graded levels of hypoxic hypoxia over 120 mins in a neonatal porcine model and to identify the PaO2 threshold for altered hemodynamic homeostasis.

DESIGN

Prospective, experimental, animal study.

SETTING

University cardiovascular research laboratory.

SUBJECTS

Three-day-old domestic swine.

INTERVENTIONS

Anesthetized, intubated, and ventilated 3-day-old pigs (n = 88) were assigned to one of five predetermined graded PaO2 groups: Group I (normoxia, PaO2 = 80 torr [10.7 kPa]); group II (PaO2 = 60 torr [8.0 kPa]); group III (PaO2 = 40 torr [5.3 kPa]); group IV (PaO2 = 30 torr [4.0 kPa]); or group V (PaO2 = 20 torr [2.7 kPa]).

MEASUREMENTS AND MAIN RESULTS

Hemodynamic parameters including heart rate, systolic blood pressure, diastolic blood pressure, mean arterial pressure (MAP), and pulse pressure were evaluated. Acid-base status (arterial pH and lactate) was monitored in each experimental group over the 120-min study period. Hemodynamic and acid-base parameters were unaltered in animals in groups I and II. In group III animals, blood pressure was maintained (partly by increased heart rate), and acid-base balance was unaltered. In contrast, group IV animals had a gradual and progressive decrease in systolic blood pressure, diastolic blood pressure, and MAP, and slightly decreased pulse pressure, despite sustained tachycardia. Group IV animals also developed mild lactic acidosis. Group V animals exhibited a biphasic hemodynamic response, while the heart rate response was characterized by tachycardia at the induction of hypoxia, which was reduced in magnitude by 120 mins. The biphasic hemodynamic response in this group of animals included an initial increase in systolic and pulse pressures, followed by a gradual and progressive decrease in systolic and diastolic blood pressures, MAP, and pulse pressure. In addition, group V animals also developed profound progressive lactic acidosis.

CONCLUSIONS

In anesthetized neonatal pigs, tachycardia occurred in response to a PaO2 of 40 torr (5.3 kPa), and thus marked the threshold for altered hemodynamic homeostasis. Beyond this threshold, both the 30 torr (4.0 kPa) and 20 torr (2.7 kPa) groups had a PaO2- dependent "late" hypotension, while only the 20 torr (2.7 kPa) group had a significant biphasic hemodynamic response characterized by "early" hypertension. The "late" hypotension which occurred in these two profound hypoxia groups indicates an inability to adequately adjust hemodynamics during prolonged hypoxic hypoxia.

Impact of reoxygenation with oxygen and air on the extent of the brain damage after hypoxia-ischaemia in neonatal rats

Brain damage after hypoxia-ischaemia develops partly during the state of reoxygenation. The generation of free oxygen radicals is considered to be one possible mechanism. In order to evaluate the role of hyperoxygenation, a comparison was made between reoxygenation with pure oxygen and with air after hypoxia-ischaemia in a rat model of unilateral cerebral hemisphere damage. Brain damage was induced in 7-day-old rats. The animals were treated during reoxygenation with either 100% oxygen for 0.5 h or air. The extent of the brain damage was determined at 3 weeks of age by weighing the left and right hemispheres separately. No significant difference in weight deficit of the hemispheres was seen in the oxygen-treated group (15.5%, median) compared to the air-treated group (25.0%). Reoxygenation with pure oxygen after hypoxia-ischaemia in neonatal rats does not cause increased brain damage compared with reoxygenation with room air.

Neuronal damage after hypothermic circulatory arrest and retrograde cerebral perfusion in the pig

BACKGROUND

Antegrade and retrograde cerebral perfusion during hypothermic circulatory arrest (HCA) has been reported to provide better brain protection during operation than hypothermic circulatory arrest alone. However, the efficacy of these techniques remains to be fully determined, especially when used for prolonged periods. We used a pig model to evaluate the histopathologic consequences of HCA and the potential benefit of cerebral perfusion during HCA.

METHODS

Twenty-two pigs were divided into four groups and exposed to either anesthesia alone, 120 minutes of HCA (15 degrees C), 120 minutes of retrograde cerebral perfusion at 15 degrees C during HCA, or 120 minutes of antegrade cerebral perfusion at 15 degrees C during HCA, and then reperfused for 60 minutes under cardiopulmonary bypass at 37 degrees C. The brains were perfusion fixed at the end of the experiments and examined by light microscopy.

RESULTS

There were no morphologic changes in any areas of the brains in the anesthesia group, and very minor changes in some areas of the brains in the antegrade cerebral perfusion. group. Varying severity of neuronal damage was found in the brains of all the pigs in the HCA and retrograde cerebral perfusion groups. The severity of ischemic damage in the brain showed the following descending order: hippocampus (CA4), caudate nucleus, cerebral cortex, putamen, thalamus, Purkinje cells of the cerebellum, pons, and mesencephalic gray matter. In the hippocampus the order of damage was CA4, CA3, polymorphous layer of the dentate gyrus, prosubiculum, CA2, CA1, and granule cell layer of the dentate gyrus. The damage in the retrograde cerebral perfusion group was less severe relative to the HCA group in many areas (no significance except mesencephalic gray matter).

CONCLUSIONS

These results demonstrate that the pattern of neuronal damage in pigs subjected to HCA and retrograde cerebral perfusion differs from the traditional pattern in that the caudate nucleus and hippocampal CA4 region are the most vulnerable to ischemia-hypoxia. Our results also suggest that antegrade cerebral perfusion prevented ischemic damage to the brain and retrograde cerebral perfusion provided some protection but moderately severe damage occurred.

MAC for halothane and isoflurane during normothermia and hypothermia in the newborn piglet

BACKGROUND

Halothane and isoflurane are frequently used in studies of perinatal hypoxia and ischemia. Little information exists on the minimum alveolar concentration (MAC) necessary to prevent movement to a painful stimulus in newborn pigs and no information on the effects of hypothermia on MAC in pigs. Hypothermia is currently investigated as a posthypoxic neuroprotective intervention.

METHODS

The MAC of halothane and isoflurane necessary to prevent movement when a 25 cm hemostatic clamp was applied to the tail were determined in six 20-48-hour-old piglets, and when the same stimulus was applied to the hoof. MAC for halothane was first determined at 39 degrees C, then at 35 degrees C, whereafter halothane was discontinued and MAC for isoflurane determined first at 35 degrees C and then at 39 degrees C.

RESULTS

In all six piglets MAC was lower at 35 degrees C than at 39 degrees C for both anesthetics with both tail and hoof determination, lower for halothane than isoflurane for both stimuli at both temperatures, and lower for tail than hoof determination for both anesthetics at both temperatures. For halothane at 39 degrees C, mean (SD) MAC hoof was 0.82 (0.05)% vs tail 0.60 (0.12)%, and at 35 degrees C, hoof 0.65 (0.06)% vs tail 0.42 (0.10)%. For isoflurane at 39 degrees C, MAC hoof was 2.47 (0.28)% vs tail 1.83 (0.28)%, and at 35 degrees C, hoof was 1.83 (0.18)% vs tail 0.85 (0.25)%.

CONCLUSION

In the newborn piglet, MAC should be determined by hoof clamp, MAC of isoflurane is approximately three times that of halothane, and both are reduced during hypothermia.

Influence of post-hypoxia reoxygenation conditions on energy metabolism and superoxide production in cultured neurons from the rat forebrain

Brain reperfusion and/or reoxygenation may be of particular importance in the etiology of neuronal damage after hypoxic-ischemic insult in neonates, especially with reference to the generation of free radicals. To investigate this issue, the influence of either standard reoxygenation or transient hyperoxia was studied on the consequences of severe hypoxia in a model of cultured neurons isolated from the fetal rat brain. Culture dishes were exposed for 6 h to hypoxia (95% N2/5% CO2). They were then placed under normoxia (95% air/5% CO2) or hyperoxia (95% O2/5% CO2) for 3 h, and finally returned to normoxia. Control cultures were kept under normoxic conditions. Cell morphology, protein concentrations, lactate dehydrogenase leakage, energy metabolism, as reflected by specific transport and incorporation of 2-D-[3H]deoxyglucose, as well as superoxide radical formation were analyzed as a function of time. Po2 values in the cell incubating medium were decreased by 78% by hypoxia and increased by 221% by hyperoxia. No morphologic alteration could be noticed before 72 h posthypoxia, when cell degeneration became apparent, with a concomitant reduction in protein contents. Hypoxia-reoxygenation induced a transient cellular hypermetabolism, as shown by a 36% increase in 2-D-[3H]deoxyglucose uptake 24 h after hypoxia, and then a 23% decrease below control values at 72 h. It also led to a sharp increase in the formation of superoxide radicals (+108%). Transient hyperoxia during reoxygenation did not exacerbate these events, and thus would not enhance their deterimental effects on cell integrity.

Regional blood flow during severe hypoxemia and resuscitation with 21% or 100% O2 in newborn pigs

Our aim was to determine whether the use of room air or 100% oxygen has different effects on the peripheral circulation during resuscitation from severe hypoxemia. Twenty-four piglets, 2-to 5-days old, were anesthetized with pentobarbital and randomized to control (n = 5, surgery only) or hypoxemia. Hypoxemia (FiO2 = 0.08) was continued until base excess reached - 20 mml/L. Resuscitation was then performed with 21% (n = 10) or 100% O2 (n = 9) for 25 min followed by 21% O2 in both groups. Regional blood flow was measured with radioactive microspheres. Both hypoxic groups showed marked hyperemia during resuscitation in cardiac and skeletal muscle, a moderate hyperemia in intestine and pancreas while kidneys, liver, spleen and skin showed no hyperemic response. There were no significant differences between the two treatment groups in blood flow to any organ. Arterial oxygen content was significantly higher in the 100% O2 group than in the 21% O2 at 5 and 20 min after onset of resuscitation (11.6 +/- 0.7 and 11.2 +/- 0.6 vs 8.6 +/- 0.3 and 8.7 +/- 0.3 ml/100 ml, p < 0.01). Oxygen delivery was, however, significantly higher in the 100% O2 group than in the 21% O2 group only to the intestine and pancreas at 5 min of resuscitation. We conclude that resuscitation with 21% or 100% oxygen produces similar changes in peripheral blood flow in this porcine model of neonatal hypoxemia.

The effect of post-asphyxial reoxygenation with 21% vs. 100% oxygen on Na+,K(+)-ATPase activity in striatum of newborn piglets

To compare the effect of 21% vs. 100% oxygen during post-asphyxial reoxygenation on brain cell membrane function in the striatum, 20 anesthetized, ventilated newborn piglets were studied: group 1 (normoxia, n = 5), group 2 (asphyxia, no reoxygenation, n = 5), group 3 (asphyxia followed by reoxygenation with 21% O2, n = 5), and group 4 (asphyxia followed by reoxygenation with 100% O2, n = 5). Asphyxia was induced by a stepwise reduction in FiO2 at 20 min intervals from 21% to 14%, 11%, and 8%. Following a total 60 min of asphyxia, piglets in groups 3 and 4 were recovered for 2 h with either 21% or 100% O2. Na+,K(+)-ATPase activity (mumol Pi/mg protein/h) in striatal cell membranes was 31 +/- 1, 22 +/- 2, 32 +/- 2 and 26 +/- 1 in groups 1, 2, 3 and 4, respectively. Na+,K(+)-ATPase activities in groups 2 and 4 were significantly lower than in groups 1 and 3 (p < 0.01). Piglets recovered post-asphyxia for 2 h with 21% O2 had restoration of Na+,K(+)-ATPase activity to baseline levels, while those treated with 100% O2 during recovery had persistent Na+,K(+)-ATPase inhibition of 16%. This could result from increased free radical production during reoxygenation with 100% O2 which could contribute to post-asphyxial cellular injury in the striatum.

AMPA antagonist LY293558 does not affect the severity of hypoxic-ischemic injury in newborn pigs

BACKGROUND AND PURPOSE

LY293558 is a systemically active alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) excitatory amino acid antagonist. AMPA antagonists have shown promise in several adult hypoxic-ischemic brain injury models, and we wanted to see if this work could be extended to a newborn animal.

METHODS

Seventy-six (beta error < .10) 0- to 3-day-old piglets under 1.5% isoflurane anesthesia underwent placement of carotid snares and arterial and venous catheters. While paralyzed with succinylcholine under 0.5% isoflurane, 50% nitrous oxide, piglets were randomly assigned to receive either 5 mg/kg or 15 mg/kg of LY293558 or saline at time--10 minutes and again 10 hours later. At time 0, both carotid arteries were clamped, and blood was withdrawn to reduce the blood pressure to two thirds of normal. At time 15 minutes, inspired oxygen was reduced to 6%. At time 30 minutes, the carotid snares were released, the withdrawn blood was reinfused, and the oxygen was switched to 100%. On the third day after the hypoxic-ischemic injury, the animals were killed by perfusion of the brain with 10% formalin. Brain pathology was scored by a blinded observer.

RESULTS

There were no significant differences between the drug-treated and control groups.

CONCLUSIONS

The systemically active AMPA antagonist LY293558, when given at a dose of 5 mg/kg or 15 mg/kg before injury and 10 hours later, does not affect the severity of hypoxic-ischemic brain injury in newborn piglets. Neither AMPA receptor activity nor NMDA receptor activity are important in brain injury in this model.

Oxygen at birth and prolonged cerebral vasoconstriction in preterm infants

To determine if the use of oxygen in the delivery room influences subsequent global cerebral blood flow (CBF), 70 infants of gestational age of less than 33 completed weeks were randomly assigned to receive room air (group I) or 80% oxygen (group II) during the initial stabilisation at birth. In group I supplemental oxygen was administered on clinical indications, when required. After being admitted to the neonatal intensive care unit all infants were treated according to our normal practice. At a postnatal age of 2 hours CBF was measured by xenon clearance. Seventy four per cent of the infants in group I were successfully stabilised without the need for supplemental oxygen. CBF was significantly higher in group I than in group II (CBF median (interquartile range): 15.9 (13.6-21.9) v 12.2 (10.7-13.8) ml/100 g/minute). Differences in oxygen exposure seemed to be the only explanation for the differences in CBF. No differences in short term outcome were found between the groups.

Release of xanthine oxidase to the systemic circulation during resuscitation from severe hypoxemia in newborn pigs

Xanthine oxidase may contribute to oxygen free radical formation during reoxygenation after hypoxia, but in humans the enzyme is present in substantial amounts only in the liver and intestine. We developed a sensitive assay for xanthine oxidase using 14C-xanthine as substrate and investigated whether xanthine oxidase was released into the systemic circulation when 19 newborn pigs were resuscitated after severe hypoxemia. In five piglets plasma xanthine oxidase concentrations increased from undetectable levels to a median value of 8 (range 4-18) microU/ml after 30 min of reoxygenation. In these pigs serum aspartate aminotransferase increased from 45 to 148 U/l, while alanine aminotransferase was unchanged (28-31 U/l). The release of xanthine oxidase did not seem to correlate with the severity of the histological brain damage after 4 days. We conclude that only low levels of xanthine oxidase are released to the systemic circulation after severe hypoxemia in newborn pigs.

Effects of asphyxia on the fetal lamb brain

OBJECTIVE

Our purpose was to study the effect of fetal asphyxia on the release of hypoxanthine and xanthine in cerebrospinal fluid and on brain histologic characteristics.

STUDY DESIGN

In seven fetal lambs (3 to 5 days after surgery, gestational age 124.3 +/- 2.6 days) asphyxia was induced by restriction of uterine blood flow.

RESULTS

Fetal pH and base excess were reduced to 6.99 +/- 0.02 and -17.6 +/- 0.9 mmol/L, respectively. Cerebral blood flow increased during asphyxia and returned to normal in the recovery phase. Maximum concentrations of cerebrospinal fluid hypoxanthine and xanthine were reached in the normoxemic recovery phase. This high level of substrates during normoxemia facilitates oxygen free radical formation and may thus aggravate postasphyctic brain damage. Histologic evaluation of the brain 3 days after the insult showed a variable degree of edema. Coagulative neuronal changes, characteristic of irreversible cell death, were only occasionally detected. These changes were most obvious in the Purkinje cells of the cerebellum.

CONCLUSIONS

Fetal asphyxia induced by uterine blood flow restriction is associated with high levels of cerebrospinal fluid hypoxanthine and xanthine in the recovery phase. Microscopically detectable brain damage, although not extensive, is mainly located in the cerebellum.

Glucose affects the severity of hypoxic-ischemic brain injury in newborn pigs

BACKGROUND AND PURPOSE

The administration of glucose has been shown to worsen brain injury in adult animals but has no effect on the severity of injury in newborn rats. We wished to see whether the results in newborn rats could be extended to another newborn animal.

METHODS

In 44 0- to 3-day-old piglets, hypoxic-ischemic central nervous system damage was induced by ligation of both carotid arteries and reduction of their blood pressure to two-thirds normal for one-half hour. In the last 15 minutes of this half hour, oxygen concentration was reduced to 6%. The piglets were randomized to receive either 2 mL/kg 50% dextrose in water followed by 2 mL/kg per hour for 2.5 hours beginning before ischemia or enough insulin to reduce their resting blood sugar to approximately 2 mmol/L.

RESULTS

Neurological exam scores in the glucose-treated piglets at 1 day after injury were significantly worse than those in the insulin-treated group. Pathological examination scores were poorer in the glucose-treated group (13.6 +/- 1.9 [mean +/- SEM]) than in the insulin-treated group (24.7 +/- 1.4, P < .01).

CONCLUSIONS

Increasing serum glucose during hypoxic-ischemic injury to the newborn piglet's brain worsens brain injury.