Modulation of the responses of fetal sheep to adrenergic stimulation by adrenal demedullation and chemical sympathectomy

The responses to sympathetic stimulation of fetal sheep adrenal-demedullated or sympathectomised by infusion of guanethidine sulphate have been studied. Sympathetic responses in such denervated or sympathectomised fetuses was studied by intravenous infusion of adrenaline or noradrenaline at about 0.4 micrograms/min per kg. This infusion increased plasma concentration 100-200 fold and there was no significant difference between the control fetuses and those in the vasrious treatment groups. Catecholamine infusions at these rates normally have little effect upon fetal blood gas and pH values, but in adrenal-demedullated fetuses adrenaline infusion drepressed fetal arterial PO2 by 4-6 mmHg (P less than 0.05). The heart rate and blood pressure responses to catecholamine infusion in sympathectomised fetuses was, as expected, much increased. Similar observations were made on adrenal-demedullated fetuses, an unexpected finding, and this is taken to illustrate loss of the adrenal medulla is associated with enhanced responsiveness to adrenergic stimulation in peripheral tissues. The majority of the endocrine and metabolic responses, as reflected in fetal plasma concentrations of ACTH, cortisol, insulin, glucose, lactate and fatty acids, to catecholamine infusion were similarly much enhanced by adrenal-demedullation and chemical sympathectomy. Of particular note was a substantial increase in the responsiveness of the fetal adrenal, as reflected in plasma cortisol, to stimulation by ACTH, a change that usually induces labour, but not so in the present sheep. The results on increased sensitivity in adrenal-demedullated fetuses are discussed in relation to likely tissue mechanisms mediating the changes.     

Enkephalin peptides in fetal sheep, changes with gestation, origin and production by the placenta.

Enkephalin-containing peptides have been followed in the circulation of fetal sheep between 118-143 days gestation. Using a combination of radioimmunoassay and hplc met5-enkephalin was found in the concentration range 60-500 pg/ml and proenkephalins containing met5-enkephalin had a concentration of 150-4000 pg/ml. The concentration of both increased towards term. The sources of the enkephalin peptides was investigated by measurement of differences across the umbilical circulation and by studying the effects of fetal adrenal demedullation and chemical sympathectomy. The placenta showed a continuous net output of enkephalin peptides which increased close to term. This placental output was increased sharply by reduction of uterine blood flow either using compression of the uterine artery or through infusion of adrenaline at 35 micrograms/min into the maternal circulation. Maternal hypoxia caused by breathing 9% O2 plus 3% CO2 also increased fetal plasma enkephalin levels, although not output from the placenta. Adrenal demedullation, particularly if accompanied by chemical sympathectomy depressed fetal plasma enkephalin concentrations and sharply suppressed the fetal peptide responses to maternal hypoxia. It is concluded that the placenta and the fetal adrenal are important sources of met5-enkephalin-containing peptides in the fetal circulation. The placental production appears to be closely tied to changes in uterine perfusion and adrenal output changes in response to fetal oxygenation.     

Effect of sympathectomy and demedullation on increased myenteric and dorsal vagal complex Fos-like immunoreactivity by cholecystokinin-8

Chemical sympathectomy with daily, intraperitoneal (IP) injections of guanethidine sulfate to adult rats, attenuated myenteric, but not dorsal vagal complex (DVC) Fos-like immunoreactivity (Fos-LI) by cholecystokinin-8 (CCK). This technique destroys only 60-70% of the sympathetic neurons, and spares the hormonal source of catecholamines, the adrenal medulla. The goal of the current study is to evaluate the effect of complete sympathectomy or destroying 100% of the sympathetic neurons by injecting guanethidine to 1-day-old pups (40 mg/kg daily for 5 weeks), and surgically removing the adrenal medulla. In the DVC, demedullation and sympathectomy-demedullation increased Fos-LI by CCK in the area postrema and nucleus of the solitary tract, but sympathectomy-demedullation increased it only in the area postrema. In the myenteric plexus, sympathectomy increased this response in the duodenum, and demedullation increased it in the duodenum and jejunum. On the other hand, sympathectomy-demedullation attenuated myenteric Fos-LI in the jejunum. These results indicate that catecholamines may play an inhibitory role on the activation of the DVC neurons by CCK. In the myenteric neurons, however, catecholamines may have both inhibitory and excitatory roles depending on the level of the intestine e.g., duodenum vs. jejunum. This may also indicate that CCK activates the enteric neurons by different mechanisms or through different pathways.     

Control of fetal insulin secretion

In this study, we investigated the way in which fetal insulin secretion is influenced by interrelated changes in blood glucose and sympathoadrenal activity. Experiments were conducted in late gestation sheep fetuses prepared with chronic peripheral and adrenal catheters. The fetus mounted a brisk insulin response to hyperglycemia but with only a minimal change in the glucose-to-insulin ratio, indicating a tight coupling between insulin secretion and plasma glucose. In well-oxygenated fetuses, alpha(2)-adrenergic blockade by idazoxan effected no change in fetal insulin concentration, indicating the absence of a resting sympathetic inhibitory tone for insulin secretion. With hypoxia, fetal norepinephrine (NE) and epinephrine secretion and plasma NE increased markedly; fetal insulin secretion decreased strikingly with the degree of change related to extant plasma glucose concentration. Idazoxan blocked this effect showing the hypoxic inhibition of insulin secretion to be mediated by a specific alpha(2)-adrenergic mechanism. alpha(2)-Blockade in the presence of sympathetic activation secondary to hypoxic stress also revealed the presence of a potent beta-adrenergic stimulatory effect for insulin secretion. However, based on an analysis of data at the completion of the study, this beta-stimulatory mechanism was seen to be absent in all six fetuses that had been subjected to a prior experimentally induced hypoxic stress but in only one of nine fetuses not subjected to this perturbation. We speculate that severe hypoxic stress in the fetus may, at least in the short term, have a residual effect in suppressing the beta-adrenergic stimulatory mechanism for insulin secretion.     

Hormonal factors in the control of heart rate in normoxaemic and hypoxaemic fetal, neonatal and adult sheep

The relationship of plasma levels of adrenaline, noradrenaline, arginine vasopressin (AVP) and plasma renin activity (PRA) to heart rate were studied in normoxaemic and hypoxaemic fetal, neonatal and adult sheep. The mean heart rate response of fetuses at the end of a 30 minute period of 10% oxygen delivery to the maternal ewe was tachycardia. However bradycardia, usually of a transient nature, was observed in 9 of the 12 fetuses (P less than 0.05). Multiple regression analysis was used to determine the contribution of blood gas, blood pressure and plasma hormone levels to the variance in heart rate in the perinatal sheep. 22% of the variance in fetal heart rate was provided by PRA and age from conception (P less than 0.001). Tachycardia was the invariable heart rate response of the neonates and adults to hypoxaemia. 61% of the variance in neonatal heart rate was contributed by PaO2, PaCO2, AVP, PRA and systolic blood pressure (SBP, P less than 0.001). PaO2 and plasma levels of adrenaline were significantly related to adult heart rate (P less than 0.001). Those fetuses which developed bradycardia had lower PaO2 but higher AVP and PRA during hypoxaemia than those which did not develop bradycardia. The major determinant of the area of the fetal bradycardia response was found, by multiple regression analysis, to be plasma adrenaline concentration (P less than 0.05). Thus different hormonal factors may play a role in the regulation of heart rate in normoxaemic and hypoxaemic fetal, neonatal and adult sheep.     

Effect of thyroidectomy on cardiovascular responses to hypoxia and tyramine infusion in fetal sheep

Fetal sheep were thyroidectomized at 80 days' gestation and reoperated at 118-122 days for insertion of vascular catheters. The effects of hypoxaemia and intravenous tyramine infusion on plasma catecholamine concentrations, blood pressure and heart rate were then determined in experiments at 125-135 days' gestation. Age matched intact fetuses were also studied. Thyroidectomy was associated with increased concentrations of noradrenaline, adrenaline and dopamine in some thoracic and abdominal organs, increased noradrenaline concentrations in the cerebellum, and decreased adrenaline concentrations in the hypothalamus, cervical spinal cord, and superior cervical and inferior mesenteric ganglia. Arterial pressure was significantly lower in the thyroidectomized fetuses (34.0 +/- 0.15 mmHg) than in intact fetuses (44.7 +/- 0.2 mmHg; p less than 0.001). In contrast, plasma noradrenaline concentrations were significantly higher in the thyroidectomized fetuses (2.04 +/- 0.25 ng/ml) compared to the intact fetuses (0.99 +/- 0.08 ng/ml; P less than 0.001). In the intact fetuses there was a significant increase in plasma noradrenaline concentration and blood pressure during hypoxaemia, and bradycardia at the onset of hypoxaemia. In contrast, in the thyroidectomized fetuses hypoxaemia did not cause significant change in plasma catecholamine concentrations, blood pressure or heart rate. Infusion of tyramine produced a 1.9-fold increase of plasma noradrenaline in thyroidectomized fetuses compared to a 9.2-fold increase in the intact fetuses (P less than 0.05). Tyramine infusion caused a similar proportional increase of blood pressure in both thyroidectomized and intact fetuses. Heart rate decreased during the tyramine-induced hypertension in the intact fetus, but increased in the thyroidectomized fetuses.(ABSTRACT TRUNCATED AT 250 WORDS)     

Suprarenal aortic flow reduction versus angiotensin I infusion in fetal sheep

In the unanaesthetized fetal sheep, long-term suprarenal aortic blood flow reduction will cause upper body arterial blood pressure to increase. To see if the response to this procedure was entirely due to the concomitant increase in plasma renin activity, we gave an angiotensin I infusion of several days to 7 fetal sheep and compared their responses to those of 4 fetal sheep undergoing partial occlusion of the aorta above the renal arteries. Both protocols caused upper body arterial blood pressure to increase to comparable levels. Angiotensin I infusion had no effect upon venous blood pressure while suprarenal aortic blood flow reduction caused a significant increase in venous blood pressure as early as 1 day after blood flow reduction. Haematocrits were unchanged in the fetuses with flow restriction but increased in the infused fetuses. We conclude that long-term angiotensin I infusion in the fetus does not mimic the entire complex of responses to suprarenal aortic blood flow reduction.     

Haemodynamic and catecholamine responses to hypothermia in the fetal sheep in utero

Chronically catheterised fetal sheep (117-134 days) were cooled in utero via a tubing coil placed around the fetal trunk through which cold water was circulated for one hour. The fetal core temperature was reduced by 5.51 +/- 0.61 degrees C. This hypothermia was associated with tachycardia (P less than 0.001) and hypertension (P less than 0.001) (n = 12). The tachycardia was abolished by treatment with propranolol (n = 4) and the hypertension by treatment with phentolamine (n = 5). Blood flow in the left umbilical artery was measured by an electromagnetic flow probe in 4 fetuses and rose (P less than 0.001) with fetal cooling. The increase in blood flow was abolished by treatment with either phentolamine or propranolol. These observations are consistent with a redistribution of fetal blood flow from peripheral tissues to placental and thermogenic tissues during cooling. Fetal plasma adrenaline and noradrenaline concentrations rose (P less than 0.01) during fetal cooling (n = 5). These studies demonstrate that catecholamine and cardiovascular responses to environmental hypothermia have differentiated prior to birth in the sheep fetus.     

Ether stress increases adrenomedullin gene expression and levels in the rat adrenal.

To study the contribution of adrenomedullin in the adrenal medulla in the stress response, we measured plasma and adrenal levels of adrenomedullin in sham-operated (intact) rats and in rats without adrenal medulla, with or without exposure to ether vapor for 15 min. Adrenomedullin levels decreased drastically after demedullation. Effect stress resulted in increased adrenomedullin levels in both adrenal and plasma in sham-operated rats, but not in demedullated rats. The responses of plasma adrenocorticotropin to stress were similar, but the elevations in plasma corticosterone levels were significantly less in demedullated rats. In the sham-operated rat, preproadrenomedullin mRNA levels were increased after stress, and this effect was not blocked by pretreatment with hexamethonium. We conclude that stress increases adrenomedullin synthesis and secretion from the adrenal medulla through a hexamethonium-insensitive mechanism, and that adrenomedullin release from the adrenal medulla may play a role in cortical steroidogenesis.     

Redistribution of fetal circulation during repeated asphyxia in sheep: effects on skin blood flow, transcutaneous PO2, and plasma catecholamines

To improve the understanding of fetal responses to labour, we have ascertained whether reduced fetal skin blood flow after asphyxia reflects redistribution of the circulation, and if so, whether this can be detected by transcutaneous PO2 monitoring. We also studied the relation between plasma concentrations of catecholamines and organ blood flow. Eight experiments were conducted on 8 acutely-prepared fetal sheep in utero between 125 and 135 days of gestation. In each fetus 11 episodes of asphyxia were induced within 33 min by intermittent arrest of uterine blood flow for 90 s. The distribution of blood flow was measured before and after asphyxia (at 35.5 min) by the isotope-labelled microsphere method. Blood samples were drawn at 0, 33 (i.e. after 90 s recovery), and 40 min to determine blood gases, acid-base balance, and catecholamine concentrations. Fetal transcutaneous PO2, heart rate, arterial blood pressure, and arterial O2 saturation were recorded continuously. Repeated fetal asphyxia increased plasma catecholamine concentrations and caused a circulatory redistribution to the brain (181% change), adrenals (116% change), and lungs (105% change) at the expense of many peripheral organs, particularly of the skin (-61% change). The pattern of these changes was different from that observed by others in persistent hypoxia or asphyxia. The decrease in skin blood flow, which depressed transcutaneous PO2 and increased the arterial-transcutaneous PO2 difference, correlated with the decrease in blood flow to other peripheral organs and with an increase in blood flow to the brain stem. We conclude that reduced blood flow to the fetal skin after repeated episodes of asphyxia indicates circulatory redistribution, which can be detected by transcutaneous PO2 measurements. We suggest that monitoring of variables that depend on skin blood flow may improve fetal surveillance during complicated labour.     

Adrenal glands are essential for activation of glucogenesis during undernutrition in fetal sheep near term

In adults, the adrenal glands are essential for the metabolic response to stress, but little is known about their role in fetal metabolism. This study examined the effects of adrenalectomizing fetal sheep on glucose and oxygen metabolism in utero in fed conditions and after maternal fasting for 48 h near term. Fetal adrenalectomy (AX) had little effect on the rates of glucose and oxygen metabolism by the fetus or uteroplacental tissues in fed conditions. Endogenous glucose production was negligible in both AX and intact, sham-operated fetuses in fed conditions. Maternal fasting reduced fetal glucose levels and umbilical glucose uptake in both groups of fetuses to a similar extent but activated glucose production only in the intact fetuses. The lack of fasting-induced glucogenesis in AX fetuses was accompanied by falls in fetal glucose utilization and oxygen consumption not seen in intact controls. The circulating concentrations of cortisol and total catecholamines, and the hepatic glycogen content and activities of key gluconeogenic enzymes, were also less in AX than intact fetuses in fasted animals. Insulin concentrations were also lower in AX than intact fetuses in both nutritional states. Maternal glucose utilization and its distribution between the fetal, uteroplacental, and nonuterine maternal tissues were unaffected by fetal AX in both nutritional states. Ovine fetal adrenal glands, therefore, have little effect on basal rates of fetal glucose and oxygen metabolism but are essential for activating fetal glucogenesis in response to maternal fasting. They may also be involved in regulating insulin sensitivity in utero.     

Progestagen metabolites in fetal sheep plasma: the effect of fetal nephrectomy.

Fetal sheep (100-115 days gestation) were surgically implanted with femoral arterial and venous cannulae and then either sham-operated (control) or bilaterally nephrectomized. Following a 5-day recovery period, fetal blood samples (10 ml/48 h) were taken and the steroid sulphate fraction analysed as trimethylsilyl esters by gas-liquid chromatography (g. l.c.). Three progestagen metabolites were repeatedly detected in plasma samples from control and nephrectomized fetuses and identified by g.l.c.-mass-spectrometric techniques as 5 beta-pregnane-3 beta,20 beta-diol, 5 beta-pregnane-3 beta,20 alpha-diol and 5 beta-pregnane-3 alpha,20 alpha-diol. In three control fetuses the plasma concentration of both 5 beta-pregnane-3 beta,20 beta-diol and -20 alpha-diol showed a steady increase from about 0.5 micrograms/ml at 105 days to about 1.5 and 2-2.5 micrograms/ml, respectively, at 143 days gestation. A study in one fetus indicated that the values then fell precipitously by term (147 days) as plasma cortisol concentrations rose. In contrast, whilst no consistent patterns were seen in their concentration in five nephrectomized fetuses the levels were 2-10 times higher than the control values (0.5-10 micrograms/ml) at all stages. The plasma concentration of 5 beta-pregnane-3 alpha,20 alpha-diol was less perturbed by nephrectomy and only showed a slight increase over control values (0.2-0.5 micrograms/ml). Three sham-operated fetuses which aborted following infection also showed increased plasma concentrations of 5 beta-pregnane-3 beta,20 beta-diol and -20 alpha-diol, similar to the nephrectomized fetuses. It is postulated that high levels of circulating progesterone metabolites may reflect induced increases in adrenal endocrine activity culminating in premature activation of those changes in adrenal function which trigger parturition.     

Vasopressin in fetal sheep: a review.

Advance in fetal sheep surgery has allowed investigation of vasopressin physiology at the end of gestation (100 to 140 days). In the fetus of that age, vasopressin is present in the pituitary and in the blood. The hormonal secretion is stimulated by hypotensive and hyperosmolar stimulus. Hypoxemia is also reported as being a potent stimulus of vasopressin secretion and may have an important effect on blood pressure control.     

Angiotensin-induced vasopressin release and activation of hypothalamic neuron in pre-term fetuses

Our previous studies have shown that central administration of angiotensin II (ANG II) causes vasopressin release in the near-term fetus in utero as evidence that the hypothalamic-neurohypophysial system has relatively matured before birth. However, it is still unknown whether the vasopressin controlling centers have been functionally developed in younger fetuses. This study determined fetal plasma vasopressin levels and hypothalamic vasopressin neuron activity in the chronically instrumented pre-term ovine fetuses. Introcerebroventricular (i.c.v.) administration of ANG II did not affect fetal plasma osmolality and sodium concentrations. However, fetal plasma vasopressin levels were significantly increased ( approximately 3-fold) in response to central injection of ANG II. Central ANG II also induced vasopressin-neuron activity marked with c-fos expression in the fetal hypothalamus at pre-term. In addition, the fetal organum vasculosum of the lamina terminalis and the subfornical organ were activated. The results suggest that hypothalamic-neurohypophysial system has been relatively intact and functional at 70% gestational age, and that central angiotensin is important in inducing fetal vasopressin release in utero.     

The effects of hypoxia on glucose turnover in the fetal sheep

The origin of the hypoxia-induced rise in fetal blood glucose concentration in fetal sheep of 124-135 days was investigated. Hypoxia was induced in pregnant sheep and fetuses with chronically implanted vascular catheters by causing the ewes to breathe 9% O2 and 3% CO2 in N2 for 60 min. The rise in fetal plasma glucose caused by a 60% reduction in maternal PaO2 was associated with a 50% fall in plasma insulin concentration. The fall in insulin and rise in glucose was prevented by the alpha-adrenergic blocking agent phentolamine but not by the beta-antagonist propranolol. Turnover of glucose in the fetus under these conditions was measured with [6-3H] and [U-14C] glucose. Hypoxia reduced fetal glucose consumption despite the hyperglycaemia. After 30 min of hypoxia there was no evidence of fetal production of glucose but by 60 min substantial production was evident. The reduced fetal consumption and increased production of glucose was inhibited by phentolamine but not by propranolol. It is concluded that in the fetal sheep hypoxia induced hyperglycaemia is first caused by reduced consumption of glucose and thus fetal glycogen stores are not depleted. If the hypoxia persists fetal blood glucose is elevated further by fetal production of glucose.     

The role of peripheral chemoreceptors in the rapid response of the pulmonary vasculature of the late gestation sheep fetus to changes in PaO2.

The effect of removing the input from the peripheral arterial chemoreceptors on pulmonary vascular responses to changes in PaO2 was examined in late gestation fetal sheep. Blood flow in the left pulmonary artery and driving pressure across the pulmonary vascular bed were monitored in chronically prepared fetal sheep at 126-129 days gestation. Five fetuses had carotid sinus and vagus nerves sectioned bilaterally and four were left intact. In normoxia (PaO2 ca. 23 mmHg) pulmonary vascular resistance was slightly greater and pulmonary blood flow reduced in the denervated group relative to the intact group but these differences were not significant. When made hypoxic (PaO2 ca. 14 mmHg), pulmonary blood flow fell and pulmonary vascular resistance increased in all fetuses. However, in the intact fetuses these changes were significantly more rapid. In all fetuses the vasoconstriction was prolonged after their return to normoxia. When made hyperoxic (PaO2 ca. 27 mmHg), pulmonary blood flow increased by a similar amount in all fetuses. We conclude that in the term fetus the peripheral chemoreceptors play no appreciable role in the maintenance of the high pulmonary vascular resistance in normoxia, or the fall in resistance produced by a rise in PaO2. The chemoreceptors do however initiate the rapid phase of pulmonary vasoconstriction in hypoxia.     

Steroidogenic acute regulatory protein expression is decreased in the adrenal gland of the growth-restricted sheep fetus during late gestation

Functional development of the adrenal cortex is critical for fetal maturation and postnatal survival. In the present study, we have determined the developmental profile of expression of the mRNA and protein of an essential cholesterol-transporting protein, steroidogenic acute regulatory protein (StAR), in the adrenal of the sheep fetus. We have also investigated the effect of placental restriction (PR) on the expression of StAR mRNA and protein in the growth-restricted fetus. Adrenal glands were collected from fetal sheep at 82-91 days (n = 10), 125-133 days (n = 10), and 140-144 days (n = 9) and from PR fetuses at 141-145 days gestation (n = 9) (term = 147 +/- 3 days gestation). The adrenal StAR mRNA:18S rRNA increased (P < 0.05) between 125 days (7.44 +/- 1.61) and 141-144 days gestation (13.76 +/- 1.88). There was also a 13-fold increase (P < 0.05) in the amount of adrenal StAR protein between 133 and 144 days gestation in these fetuses. However, the amount of StAR protein (6.9 +/- 1.7 arbitrary densitometric units [AU]/microg adrenal protein) in the adrenal of the growth-restricted fetal sheep was significantly reduced, when compared with the expression of StAR protein (17.1 +/- 1.9 AU/microg adrenal protein) in adrenals from the age-matched control group. In summary, there is a developmental increase in the expression of StAR mRNA and protein in the fetal sheep adrenal during the prepartum period when adrenal growth and steroidogenesis is dependent on ACTH stimulation. We have found that, while the level of expression of StAR protein is decreased in the adrenal gland of the growth-restricted fetus during late gestation, this does not impair adrenal steroidogenesis. Our data also suggest that the stimulation of adrenal growth and steroidogenesis in the growth-restricted fetus may not be ACTH dependent.     

Foetal circulatory responses to arrest of uterine blood flow in sheep: effects of chemical sympathectomy.

Acute foetal asphyxia, caused by arrest of uterine blood flow, increases both sympathetic activity and peripheral vascular resistance and decreases blood flow to peripheral organs (Jensen et al., J. Dev. Physiol., 9, 543-559). The rapidity and uniformity of this peripheral vasoconstriction suggest that the sympatho-neuronal system may reflexly cause these initial blood flow changes during acute asphyxia. To test this hypothesis, we studied 5 intact and 6 chemically sympathectomized (6-hydroxy-dopamine, 46.1 +/- 6 mg/kg foetal weight) chronically prepared normoxaemic foetal sheep in utero at 0.9 of gestation. Organ blood flows (microsphere method), plasma concentrations of catecholamines, vasopressin, and angiotensin II, acid-base balance and blood gases were measured before, during and after arrest of uterine blood flow for 2 min, i.e., at 0, 1, 2, 3, 4 & 30 min. In intact foetuses there was a progressive increase in arterial blood pressure and a rapid circulatory centralization in favour of the brain stem and heart and at the expense of most of the peripheral organs. The changes in peripheral blood flow during and after asphyxia were well reflected by those in the skin and scalp. In chemically sympathectomized foetuses, arterial blood pressure fell transiently at 1 min of asphyxia and cardiac output was redistributed towards the carcass and intestinal organs at the expense of the heart, spinal medulla, and placenta. We conclude that in foetal sheep at 0.9 of gestation, the short-term adaptation to arrest of uterine blood flow is a rapid and profound peripheral vasoconstriction to effect an increase in arterial blood pressure. This initial response during circulatory centralization, which is necessary to increase or maintain blood flow to the heart, brain stem, and placenta, is blunted by sympathectomy. Thus, the foetal sympatho-neuronal system is important for short-term adaptation to and intact survival of asphyxia.     

Characterization of opioid peptides from maternal and fetal sheep adrenal glands

Enkephalin immunoreactive material from adrenal glands was characterized both in maternal and fetal sheep at various gestational ages. Whole gland extracts from both maternal and fetal sheep contained three major peaks of Enk immunoreactivity corresponding to apparent molecular weights of 10,000, 2800, and less than 1200 daltons. The majority of maternal adrenal Enk immunoreactivity was found in medullary tissue, although cortex also contained low but detectable amounts. This was also the case in newborn lambs and 139 day fetuses, where adrenal cortex was sufficiently developed to allow extraction and quantitation of opioid material. In fetuses at mid-gestation (70-80 days), adrenal medullary Enk immunoreactivity was approximately 75% of maternal values. Met-Enk and Leu-Enk content in 139 day fetal medulla were 70 and 76% of maternal values respectively, while newborn Met- and Leu-Enk medullary content were similar to maternal values. The molar ratio of Met-Enk to Leu-Enk was approximately 4:1 in both maternal and fetal adrenal medulla, and 2:1 in adrenal cortex, suggesting different synthetic processing of opioid peptides in the two tissues. The early appearance of significant levels of adrenal medullary Enk immunoreactivity and subsequent development paralleling that of catecholamines suggest a predominant role for adrenal enkephalins in regulation of fetal cardiovascular function early in gestation.     

Effects of acute acidemia on the fetal cardiovascular defense to acute hypoxemia

In complicated pregnancy, fetal hypoxemia rarely occurs in isolation but is often accompanied by fetal acidemia. There is growing clinical concern about the combined effects of fetal hypoxemia and fetal acidemia on neonatal outcome. However, the effects on the fetal defense responses to acute hypoxemia during fetal acidemia are not well understood. This study tested the hypothesis that fetal acidemia affects the fetal defense responses to acute hypoxemia. The hypothesis was tested by investigating, in the late-gestation sheep fetus surgically prepared for long-term recording, the in vivo effects of acute fetal acidemia on 1) the fetal cardiovascular responses to acute hypoxemia and 2) the neural and endocrine mechanisms mediating these responses. Under general anesthesia, five sheep fetuses at 0.8 gestation were instrumented with catheters and Transonic flow probes around the femoral and umbilical arteries. After 5 days, animals were subjected to an acute hypoxemia protocol during intravenous infusion of saline or treatment with acidified saline. Treatment with acidified saline reduced fetal basal pH from 7.35 +/- 0.01 to 7.29 +/- 0.01 but did not alter basal cardiovascular variables, blood glucose, or plasma concentrations of catecholamines, ACTH, and cortisol. During hypoxemia, treatment with acidified saline increased the magnitude of the fetal bradycardia and femoral vasoconstriction and concomitantly increased chemoreflex function and enhanced the increments in plasma concentrations of catecholamines, ACTH, and cortisol. Acidemia also reversed the increase in umbilical vascular conductance during hypoxemia to vasoconstriction. In conclusion, the data support our hypothesis and show that acute acidemia markedly alters fetal hemodynamic, metabolic, and endocrine responses to acute hypoxemia.