Acute effects on systemic circulation after intratracheal instillation of Curosurf or Survanta in surfactant-depleted newborn piglets

Systemic vasodilatation in surfactant-depleted newborn piglets is induced by 200 mg/kg of modified porcine lung surfactant (Curosurf). The aim of this investigation was to study whether this effect is dependent on dose and could further be induced by instillation of a bovine surfactant preparation (Survanta). Twenty-two 3-5-d old piglets were subjected to repeated saline lung lavage and then randomized to one of three groups. Instillation of either Curosurf l00 mg/kg (n=8), Survanta l00 mg/kg (n=7) or Curosurf 200 mg/kg (n=7) was performed through the endotracheal tube. Systemic vascular resistance decreased 7 (+/-4)%, 15 (+/-12)% and 18 (+/-6)% in the three groups, respectively (p < 0.05 in all three groups). A significant difference between the high and low dose Curosurf groups was found (p < 0.05), whereas no significant difference was seen between the Curosurf 100 mg group and the Survanta group. The decrease in vascular resistance was compensated by an increase in cardiac output, resulting in a stable mean arterial blood pressure. In conclusion, both Curosurf and Survanta induce a significant decrease in systemic vascular resistance in surfactant-depleted newborn piglets. A more pronounced effect was observed after 200 mg/kg than after 100mg/kg of Curosurf.

Practical aspects of resuscitating asphyxiated newborn infants

Of all newborn infants, 5% require some degree of basic life support at birth. Newborn resuscitation therefore is one of the most frequent procedures carried out in medicine. It is therefore important that the routines in use are evidence based. Newborn resuscitation can be divided into ten steps: (1) initial stabilisation; (2) evaluation; (3) ventilation; (4) oxygen supplementation; (5) external heart massage; (6) medication; (7) response assessment; (8) withdrawal; (9) post resuscitation care; and (10) documentation. The procedures used in these steps are rarely based on scientific investigation and there is a need for more research in this field. Training programmes, identification of risk cases and preparation for resuscitation should be part of the routine in all delivery units. It is underlined that the need for oxygen, external heart massage or medication is rare. Most depressed newborn infants manage well with suctioning, gentle tactile stimulation or a few ventilations with a bag and mask.

The importance of the measurement of ATP depletion and subsequent cell damage with an estimate of size and nature of the market for a practicable method: a review designed for technology transfer

ATP is the energy currency of cells. ATP depletion is a central process in pathogenesis, in particular ischaemia, hypoxia and hypoglycaemia. ATP depletion in cells can be indirectly measured from the increased concentrations of extracellular hypoxanthine, a central intermediate in the metabolism of ATP. Cell damage secondary to ATP depletion can also be measured from extracellular hypoxanthine. The relevant biochemistry and physiology is briefly reviewed. Since market size is needed for investment decisions that would allow technology transfer, the numbers of hypoxanthine analyses that are clinically justified from the extensive published evidence are calculated per million population from UK, Norwegian and other evidence. The concentration of oxygen in blood is measured to estimate whether mitochondrial oxidative phosphorylation is adequate. Measurements of bicarbonate are used to estimate anaerobic glycolysis. Since the indirect estimation of ATP depletion is a major objective of blood gas and acid-base analyses, the number of such analyses per million population provides a good estimate of potential market size for a more direct method of estimating ATP depletion. A method is required for the rapid, dispersed emergency analyses needed clinically. Routes for method development are indicated. Competition, risks, acceptability, consumer motivation and timetables are indicated for the development phase. There are medicolegal pressures, especially in the USA, for the proposed advances to be widely used.

Bronchopulmonary dysplasia and oxidative stress: are we closer to an understanding of the pathogenesis of BPD?

In recent years a body of data has accumulated, linking the development of bronchopulmonary dysplasia (BPD) to increased oxidative stress in the first few days after birth, since high concentrations of metabolites reflecting increased peroxidation products such as pentane, ethane, protein carbonyl, o-tyrosine, allantoin and F2-isoprostanes, as well as low levels of glutathione and sulfhydryl/total protein ratio, also reflecting increased oxidative load, have been found in the premature infants at risk of or developing BPD. Oxidative stress seems to increase lung antioxidants in some experimental models of BPD and hyperoxia affects foetal lung growth. There are similarities between inflammation and hypoxia/reoxygenation, since both activate a number of inflammatory mediators such as cytokines and adhesion molecules, some of which are found in high concentrations in tracheal aspirate fluid of infants developing BPD. Surfactant production and function are also altered by both hyperoxia and reactive oxygen species per se, making the lungs more vulnerable to injury. This new knowledge may result in new and more efficient therapeutic approaches, hopefully leading to the eradication of BPD in the near future.

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.

Near-infrared monitoring of cerebral tissue oxygen saturation and blood volume in newborn piglets

Near-infrared spectrophotometry (NIRS) potentially provides a tool for noninvasive tissue oxygenation and blood volume monitoring. Cerebral monitoring could be useful in the prevention of hypoxic ischemic brain injury in newborns. This study sought to validate such NIRS measurements in normoventilated, hypocapnic, and hypoxemic states in the brain of newborn piglets vs. arterial (SaO2) and sagittal sinus blood hemoglobin saturation (SssO2) and blood volume measurements with 99mTc-labeled erythrocytes. NIRS measurements of cerebral blood volume (CBV) were performed with both oxyhemoglobin and indocyanine green as tracers, and changes in CBV were monitored by following the change in the concentration of total hemoglobin (i.e., oxyhemoglobin + deoxyhemoglobin). NIRS CBV measurements did not correlate well with the radioactive measurements. NIRS measurements of oxygenation, however, correlated well with a weighted mean value of SaO2 and SssO2 (r = 0.90; P < 0.0001). Multiple linear regression of the oxygenation index (i.e., oxyhemoglobin - deoxyhemoglobin) on SaO2 and SssO2 suggested that NIRS sees hemoglobin in tissue in a venous-to-arterial ratio of 2:1. Therefore, in this study, NIRS reliably monitored changes in cerebral tissue oxygenation but not in CBV.

Nitric oxide contributes to surfactant-induced vasodilation in surfactant-depleted newborn piglets

To investigate whether nitric oxide (NO) is involved in surfactant-induced systemic and pulmonary vasodilatation in newborn piglets with surfactant deficiency, 2-6-d-old piglets were subjected to repeated saline lung lavages. They were then randomly assigned to one of two groups (seven in each group): the N(omega)-nitro-L-arginine methyl ester (L-NAME) group received 3 mg/kg L-NAME i.v. 45 min before endotracheal instillation of 200 mg/kg porcine surfactant; the saline group received saline i.v. at the same time point, and instillation of 200 mg/kg surfactant. Mean arterial blood pressure, systemic vascular resistance, pulmonary arterial pressure, and pulmonary vascular resistance increased significantly after injection of L-NAME (all p < 0.01), whereas the cardiac index decreased significantly (p < 0.05). Saline injection did not change any variable. Significant decreases in mean arterial blood pressure (from a mean +/- SD of 66 +/- 10 to 53 +/- 9 mm Hg, p < 0.01), pulmonary arterial pressure (from 29 +/- 6 to 23 +/- 6 mm Hg, p < 0.01), and systemic vascular resistance (from 0.40 +/- 0.13 to 0.33 +/- 0.12 mm Hg/mL/min/kg, p < 0.05) were observed only in the saline group after surfactant instillation, whereas the decrease in pulmonary vascular resistance was not significant after surfactant instillation (p = 0.06). In contrast to the saline group, these variables were not modified in the L-NAME group after surfactant instillation. We conclude that the vasodilatory effect of porcine surfactant instillation in newborn piglets with surfactant deficiency is associated with activation of NO synthase.

Ascorbic acid enhances hydroxyl radical formation in iron-fortified infant cereals and infant formulas

Infant cereals and formulas are usually fortified with iron to prevent iron deficiency. To enhance iron bioavailability, supplemental ascorbic acid is recommended. Ascorbic acid is considered to be an antioxidant in vivo, but has pro-oxidant effects when exposed to non-protein-bound iron. We measured formation of free radicals in cereals and infant formulas after addition of ascorbic acid. The production of hydroxyl radicals was assessed by hydroxylation of salicylic acid to 2.5-dihydroxybenzoic acid (2,5-DHBA). Production of 2.5-DHBA increased with increasing ascorbic acid doses added. Addition of 0.8 mM ascorbic acid to breast milk produced less radicals (0.03 +/- 0.05 microM) than addition of ascorbic acid to low-iron formula (0.13 +/- 0.08 microM. P = 0.019), medium-iron formula (0.34 +/- 0.12 microM, P < 0.0001) or high-iron formula (0.44 +/- 0.08 microM. P < 0.0001). Even when iron content in breast milk was adjusted to a level comparable with that of formulas, production of 2,5-DHBA was lower. Breast milk seems to contain substances that reduce hydroxyl radical formation.

CONCLUSION

Supplemental ascorbic acid causes hydroxyl radical formation in iron-fortified infant nutrients in vitro.

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.

Hemodynamics and tissue blood flow after porcine surfactant replacement in surfactant-depleted newborn piglets

In 22 newborn piglets we studied the effect of hypovolemia or hypoxemia on hemodynamics and regional blood flow after instillation of porcine surfactant. Surfactant deficiency was obtained by repeated lung lavage, and blood flow measurements were carried out using radioactive microspheres. Three groups of piglets were studied, controls (n = 8), hypovolemia (n = 7), and hypoxemia (n = 7). Three to five minutes after instillation of surfactant, mean arterial blood pressure decreased significantly in all three groups with a mean decrease (+/- SD) of 31(+/- 12), 33(+/- 9), and 29(+/- 9) mm Hg, respectively (p < 0.01 in all three groups). Systemic vascular resistance decreased significantly in all three groups immediately after surfactant instillation (p < 0.01) and returned to presurfactant level after 60 min. Blood flow did not change after surfactant instillation in any of the three groups, in neither skin, muscle, pancreas, brain, nor retina. In liver, kidney, intestine, and choroidea there was a decrease in blood flow immediately after instillation with return to presur-factant levels within 60 min. Hypoxemia or hypovolemia before surfactant instillation did not increase the hemodynamic instability. The decrease in mean arterial blood pressure was caused by a vasodilation and not by a reduced cardiac output.

Role of xanthine oxidase and its inhibitor in hypoxia: reoxygenation injury

OBJECTIVE

This article reviews the biochemistry and function of xanthine dehydrogenase (XDH) and xanthine oxidase (XO) as well as their role in hypoxia-reoxygenation injury. Possible benefits of XO blockade are discussed.

METHODOLOGY

The available literature was reviewed.

RESULTS

It is evident that relatively high activities of XO are restricted to a few organs in man. Because positive effects of XO blockade with allopurinol have been reported even in organs containing relatively low activities of XO, two other possible favorable actions of allopurinol are mentioned. First it may act as an oxygen radical scavenger, and second, it may augment the adenine nucleotides and, hence, adenosine triphosphate concentration in the cell.

CONCLUSIONS

XDH and XO may play an important role in a series of pathophysiologic conditions. Their role in hypoxia-reoxygenation injury has been critically reviewed. However, care should be exercised in starting randomized trials to prevent hypoxia-reoxygenation injury with allopurinol, especially in newborn infants.

SPECULATION

XDH and XO are released from the liver during hypoxic conditions, for instance, and consequently, they may reach a number of organs via the circulation.

Beta-endorphin immunoreactivity levels in CSF after laryngeal chemoreflex activation correlate with apnoea duration in piglets

The activation of the laryngeal chemoreflex may be a pathogenic mechanism in apnoea, apparent life threatening events, and SIDS. Infants with apnoea and increased levels of beta-endorphin immunoreactivity in CSF have been successfully treated with naloxone. Beta-endorphin may induce respiratory depression, and naloxone is a beta-endorphin antagonist. We therefore wanted to measure beta-endorphin levels in CSF before and after the chemoreflex induced apnoea. This study includes 13 piglets, 5-10 days of age, treated with and without naloxone. Respiration, blood pressure, and heart rate were monitored. CSF was sampled before and after the laryngeal chemoreflex induced apnoea. We found a shorter duration of apnoea in the piglets which had received naloxone than in those which did not (p = 0.02). The beta-endorphin immunoreactivity levels in CSF increased after apnoea, and the increased levels correlated positively with the duration of the apnoea in the piglets which had not received naloxone (r = 0.94, p = 0.02), but not in those pretreated with naloxone (r = 0.1, p = 0.8). The median amount of beta-endorphin immunoreactivity in CSF after apnoea in the naloxone-treated piglets was not significantly different from that in the non-treated piglets: 615 +/- 589 (n = 7) fmol/ml CSF and 984 +/- 851 (n = 6) fmol/ml CSF, respectively. The beta-endorphin immunoreactivity levels measured before the apnoea were less than 4.3 fmol/ml CSF.

CONCLUSION

The laryngeal chemoreflex induced apnoea may possible be partly mediated by beta-endorphin.

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.

Mechanisms of tissue injury by oxygen radicals: implications for neonatal disease

A role of the oxygen radical generating system hypoxanthine-xanthine oxidase in hypoxia-reoxygenation injury was proposed 15 years ago. In recent years, however, new understanding of hypoxia-reoxygenation injury has been achieved and the significance of other oxygen radical generating systems has been acknowledged too. The hypothesis that an oxygen radical disease exists in preterm infants has recently been strengthened; an important observation is that preterm infants have lower activities of erythrocyte Cu/Zn superoxide dismutase compared to term babies. New actions of oxygen radicals have also been emphasized, and recently it has been demonstrated that the degree of protein oxidation of the lung of newborn infants is associated with chronic lung injury. The new insight into the interaction of oxygen radicals with other systems as excitatory amino acids and the NO system also increases the possibility to understand and hence prevent oxygen radical injury in the preterm infant as well as in adults exposed to an increased load of oxygen radicals.

Beta-endorphin may be a mediator of apnea induced by the laryngeal chemoreflex in piglets

To determine whether beta-endorphin is involved in the laryngeal chemoreflex, we initially injected 0.01-1 mg of beta-endorphin into the cisterna magna (i.c.m.) and registered the respiratory and cardiovascular patterns in 5-10-d-old piglets. From 0.1 to 1 mg of beta-endorphin i.c.m. induced a decrease in the minute volume, heart rate, and blood pressure within 15 min. Within the next 30 min respiratory pauses accompanied by blood pressure increases and reductions in heart rate developed, similar to the respiratory and cardiovascular pattern of the induced laryngeal chemoreflex. Based on these initial data, we decided to induce a laryngeal chemoreflex in piglets pretreated with 0.1 mg of beta-endorphin i.c.m (n = 6), 0.2 mg of beta-endorphin i.c.m. (n = 6), 0.1 mg of beta-endorphin i.c.m. and 100 micrograms/kg naloxone i.v. (n = 6), 100 micrograms/kg naloxone i.v. (n = 6), or water i.c.m. (n = 6). Because elevated levels of hypoxanthine in the vitreous humor may indicate hypoxia before death, we therefore measured the postmortem hypoxanthine levels in the vitreous humor. The laryngeal chemoreflex-induced apnea was shortened in the piglet group pretreated with water i.c.m and naloxone i.v. (p < 0.01) and in the piglet group pretreated with 0.1 mg of beta-endorphin i.c.m and naloxone i.v. (p < 0.05), but not significantly prolonged in the piglet groups pretreated with 0.1 or 0.2 mg of beta-endorphin i.c.m. when compared with the piglets pretreated with water i.c.m.(ABSTRACT TRUNCATED AT 250 WORDS)

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.

[Screening of newborn infants in Norway for severe metabolic disease]

The objective of neonatal screening for phenylketonuria and congenital hypothyroidism is early diagnosis and initiation of treatment to prevent brain damage and mental retardation. We present the results of the Norwegian national neonatal screening programme for phenylketonuria and congenital hypothyroidism. Screening for phenylketonuria based on serum phenylalanine determinations started in 1967 and covered the whole country in 1978. National screening for congenital hypothyroidism started in 1979. One hundred children with phenylketonuria and 280 children with a strong indication of congenital hypothyroidism have been detected up to 1 October 1994. Screening-related challenges and principles of treatment are discussed.

[Neonatal screening for metabolic diseases--a task without priority in the Norwegian health policy?]

The Norwegian national screening programme for early diagnosis of phenylketonuria and congenital hypothyroidism was established in 1978-79. The organization and implementation of the programme is based on a marginal cost policy profile and has kept almost the same structure throughout the period of national neonatal screening. We focus on practical measures aimed at increasing the quality of the programme, and suggest a health political reconsideration of public preference and financial support for neonatal screening in Norway.

SIDS cases have increased levels of interleukin-6 in cerebrospinal fluid

Cerebrospinal fluid (CSF) from 20 infants who died of sudden infant death syndrome (SIDS), 7 cases of infectious death and 5 cases of violent death were examined with respect to concentrations of interleukin-6 (IL-6). The measurements were performed by ELISA. IL-6 levels in SIDS were significantly lower than in infectious death (p < 0.02), but significantly higher than in violent death (p < 0.02). Since IL-6 plays an important role in immune responses and may induce fever, the findings may suggest that immune activation plays a role in SIDS. The presence of cytokines in the central nervous system (CNS) may cause respiratory depression, especially in vulnerable infants.

Changes in the concentration and distribution of immunoglobulin-producing cells in SIDS palatine tonsils

Seventeen sudden infant death syndrome (SIDS) cases and 9 controls, were examined immunohistochemically with regard to the presence of IgA-, IgM-, IgD, and IgG, as well as for the subtypes IgG1-, IgG2-, IgG3-, and IgG4-immunocytes. Differences in compartmentalization were also investigated. Differences were demonstrated between SIDS and controls in total number of IgG cells per 0.1 mm2 tissue area (median: 18.3, range: 12.3-30.2 versus median: 6.3, range: 2.0-14.6) (p < 0.01), and for IgA immunocytes (median: 3.9, range: 2.4-5.0 versus median: 1.5, range: 1.1-3.7) (p < 0.05), while no differences were demonstrated for IgM cells (median: 1.8, range: 1.2-3.3 versus median: 1.8, range: 0.7-5.6) or IgD cells (median: 1.9, range: 0.8-2.9 versus median: 1.6, range: 0.7-2.4). Differences were demonstrated between SIDS and control IgG plasma cells in all the four palatine tonsillar compartments; germinal centre (p < 0.01), mantle zone (p < 0.05), interfollicular area (p < 0.01) and reticular epithelium (p < 0.01). Furthermore, the number of IgA cells was higher in SIDS vs. controls in both the germinal centre (median: 1.4, range: 0.6-2.1 versus median: 0.6, range: 0.3-1.3) (p < 0.05) and in the interfollicular area (median: 2.2, range: 1.1-3.1 versus median: 0.5, range: 0.4-2.0) (p < 0.01).(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of oxygen radicals on cysteinyl leukotriene metabolism and pulmonary circulation in young pigs

The effects of oxygen radicals, generated by the hypoxanthine-xanthine oxidase (XO) system, on pulmonary circulation and release of cysteinyl-containing leukotrienes (LTs) were studied in pigs after XO infusion into the right atrium. A 2.3-fold increase in pulmonary vascular resistance (PVR) (p < 0.05 vs. baseline) and a 2.1-fold increase in LT release (p < 0.05 vs. baseline) was observed. Pretreatment with indomethacin and allopurinol attenauted the vascular response (p < 0.01 and p < 0.05 vs. XO), and the LT release was inhibited by allopurinol and catalase (p < 0.01 and p < 0.02 vs. XO). We conclude that oxygen radicals stimulate lipoxygenase metabolism. This coincides with the observed increase in PVR, however, no causal relationship can be derived from the data presented.

D-penicillamine inhibits the action of reactive oxygen species in the pig pulmonary circulation

Oxygen radicals produced by the hypoxanthine-xanthine oxidase (Hyp-XO) system potently constrict the pulmonary circulation of pigs. D-penicillamine (DPA) is thought to be a free radical scavenger. In the present work we have studied if DPA may influence the vasoactive action of Hyp-XO in pig lungs. Further, we have measured how this drug influences the output of cyclooxygenase and lipoxygenase products from the left atrium in pigs infused with XO into the pulmonary circulation. Twelve young pigs were divided into two groups. Group 1, the XO group, was infused 1 U/kg XO into right atrium. Group 2, the DPA group, was pretreated with DPA, 100 mg/kg intravenously before XO infusion as in group 1. Pulmonary artery pressure, left atrial pressure, pulmonary artery blood flow and systemic blood flow and pressure were recorded continuously. Plasma tromboxane B2 and prostaglandin (6-keto-PGF1 alpha) were determined with a radioimmunoassay method. Cysteinyl containing leukotrienes LTC4, LTD4, and LTE4, were measured together by RIA analyses of plasma samples, using a monoclonal antibody. There was a significant parallel decrease in paO2 and saO2 during the 130 minutes duration of the experiments in both groups without differences between the groups. Pulmonary vascular pressure and resistance increased sharply with a peak found after 25 minutes in the XO group. DPA attenuated the hemodynamic response. DPA inhibited the XO induced pulmonary blood pressure changes with 80% and inhibited the increase in pulmonary vascular resistance 68%. Plasma TXB2 increased two folds in the XO group reaching a maximum after 40 minutes, this effect was completely inhibited by DPA (92% inhibition). DPA also inhibited the XO induced increase in 6-keto-PGF1 alpha, however, not as efficient as with TXB2 (40% inhibition). Plasma cysteinyl leukotrienes increased after XO infusion reaching a peak at 20 minutes. DPA completely abolished this effect (100% inhibition). The study demonstrates that DPA attenuates or even abolishes the hemodynamic effects of XO on the pulmonary circulation in pigs. It seems that DPA inhibits the production of both lipoxygenase and cyclooxygenase products per se, and it is tempting to speculate that the observed DPA effect is caused by its action as an oxygen radical scavenger. It is further speculated that the vasoconstricting effect of XO is due to the fact that oxygen radicals may inactivate nitric oxide (NO), and that DPA stabilizes NO so it more efficiently possess its vasorelaxant activity. We conclude that DPA is an extremely potent inhibitor of XO induced pulmonary vascular effects. The mechanism of action is not fully understood, although its action as an oxygen radical scavenger may explain part of it.