Perinatal onset of hepatic gluconeogenesis in the lamb

Hepatic gluconeogenesis does not occur in the unstressed fetal sheep. After birth, in addition to glycogenolysis, the newborn lamb must eventually initiate gluconeogenesis to maintain glucose homeostasis. The regulation and time course of this transition have not been defined. We studied six animals in an acute preparation before and after delivery to determine hepatic lactate and glucose uptake, hepatic gluconeogenesis from lactate, and plasma catecholamine and cortisol concentrations. After a priming dose, continuous infusion of [14C]lactate provided tracer substrate for calculations of gluconeogenesis in the fetus and then for ten hours after delivery in the newborn lamb. The radionuclide-labelled microsphere method was used to measure hepatic blood flow. Appreciable gluconeogenesis was not present during the fetal period. Following delivery, the newborn lambs began to produce significant quantities of glucose from lactate at 6 h of age (1.37 +/- 0.84 mg.min-1.100 g-1 min-1 x 100 g-1 liver), when gluconeogenesis from lactate accounted for 22% of hepatic glucose output. Despite the onset of gluconeogenesis, postnatal lambs had blood glucose concentrations that remained less than fetal levels of 23.4 +/- 12.1 mg/dl for the duration of the 10-h study. Plasma norepinephrine concentration was 1380 +/- 1145 pg/ml in the fetus and fell by 2 h after birth. Plasma epinephrine concentrations were highest at 15 min after birth (205 +/- 262 pg/ml), but remained quite low for the remainder of the study. Plasma cortisol concentrations did not vary over the course of study, ranging from 40 to 50 ng/ml.(ABSTRACT TRUNCATED AT 250 WORDS)     

Lactate uptake by the fetal sheep liver

Lactate is produced by the sheep placenta and is an important metabolic substrate for fetal sheep. However, lactate uptake and release by the fetal liver have not been assessed directly. We measured lactate flux across the liver in 16 fetal sheep at 129 (120-138) days gestation that had catheters chronically maintained in the fetal descending aorta, inferior vena cava, right or left hepatic vein, and umbilical vein. Lactate and hemoglobin concentrations and oxygen saturation were measured in blood drawn from all vessels. Umbilical venous, portal venous, and hepatic blood flow were measured by injecting radionuclide-labeled microspheres into the umbilical vein while obtaining a reference sample from the descending aorta. We found net hepatic uptake of lactate (5.0 +/- 4.4 mg/min per 100 g liver). A large quantity of lactate was delivered to the liver (94.2 +/- 78.1 mg/min per 100 g), so that the hepatic extraction of lactate was only 7.7 +/- 6.5%. Hepatic oxygen consumption was 3.18 +/- 3.3 ml/min per 100 g, and the hepatic lactate/oxygen quotient was 2.07 +/- 1.54. There was no significant correlation between hepatic lactate uptake and hepatic lactate or glucose delivery, hepatic oxygen consumption, hepatic blood flow, hepatic glucose flux, total body oxygen consumption, arterial pH, oxygen content, or oxygen saturation. There was, however, a significant correlation between hepatic lactate uptake and umbilical lactate uptake (r = 0.74, P less than 0.005) such that net hepatic lactate uptake was nearly equivalent to that produced across the umbilical-placental circulation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of insulin on gluconeogenesis and the metabolism of lactate in sheep

Owing to the fermentative nature of their digestion, ruminant animals are highly dependent upon gluconeogenesis to meet their glucose needs. The role of hormones in regulating this process is not clear. The purpose of this study was to examine the effect of insulin on the utilization of lactate in glucose synthesis in sheep. The euglycemic model was used in sheep. [U-14C]Lactate and [6-3H]glucose were infused to monitor lactate and glucose fluxes. Hepatic metabolism was measured using radioisotopic and venoarterial concentration difference techniques. Insulin concentrations increased from basal concentrations of 16 +/- 2 to 95 +/- 9 microU/mL. Insulin reduced the net hepatic utilization of lactate (303 +/- 43 vs. 120 +/- 27 mumol/min), hepatic extraction efficiency of lactate (29 +/- 4 vs. 9 +/- 2%), hepatic output of glucose (338 +/- 33 vs. 103 +/- 21 mumol/min), and incorporation of lactate into glucose (90 +/- 5 vs. 46 +/- 8 mumol/min). Insulin at physiological levels can inhibit hepatic gluconeogenesis in ruminants.     

Effects of maternal fasting on hepatic gluconeogenesis and glucose metabolism in fetal lambs.

In unstressed, normoglycaemic fetal lambs, the liver produces little glucose, and gluconeogenesis is insignificant. Indirect measurements have suggested that the fetus may produce glucose endogenously during hypoglycaemia induced by prolonged maternal starvation. In eight fetal lambs we directly measured total and radiolabelled substrate concentration differences across the liver to determine whether the fetal liver produces glucose after four days of fasting-induced hypoglycaemia. Simultaneously we measured umbilical glucose uptake and fetal glucose utilization. Glucose concentrations in ewes (1.78 +/- 0.44 mmol.-1) and fetuses (0.61 +/- 0.17 mmol.l-1) were decreased. Fetal glucose utilization rate (21.7 +/- 8.9 mumol.min-1.kg-1) was not significantly different from umbilical glucose uptake (17.2 +/- 8.9 mumol.min-1.kg-1). Hepatic glucose production (8.9 +/- 17.2 mumol.min-1.100 g-1) and gluconeogenesis (6.1 +/- 4.4 mumol.min-1.100 g-1) were present, but could account for only 13% and 8% of fetal glucose requirements, respectively. To determine whether glucose output by the fetal liver was limited by substrate availability, we infused lactate, acetate, and acetone into the umbilical veins of four fasted animals, increasing hepatic substrate delivery. Hepatic glucose output did not increase during infusion of gluconeogenic substrates, indicating that substrate availability did not limit gluconeogenesis. We conclude that the gluconeogenic pathway is intact in late-gestation fetal lambs and that the fetal liver is capable of gluconeogenesis. However, the primary change in fetal metabolism during maternal starvation is the reduction in fetal glucose utilization, obviating the need for substantial hepatic glucose production. The factors stimulating this modest increase in fetal hepatic glucose production remain to be elucidated.     

Effect of cortisol on hepatic gluconeogenesis in the fetal sheep

To determine whether the prenatal surge in cortisol induces the onset of gluconeogenesis in the fetal sheep, we performed studies in eight fetal sheep of 124 +/- 3 days gestational age. Catheters were inserted chronically in the descending aorta, inferior vena cava, and hepatic and umbilical veins, allowing the measurement of substrate flux across the liver and placenta. Cortisol was infused over a 48-h period, raising plasma cortisol concentrations from 3.5 +/- 2.5 ng/ml to 78 +/- 22 ng/ml at 24 h and 111 41 ng/ml at 48 h. At 24 and 48 h, [14C]lactate was infused into the inferior vena cava, and blood samples were obtained to measure plasma concentrations and specific activities of glucose and lactate. Comparison of the cortisol-treated group with an untreated control group of animals revealed no differences in blood gases, haemoglobin concentrations, or glucose and lactate levels. Similarly, there were no differences between groups in liver oxygen consumption, glucose and lactate flux, or gluconeogenesis from lactate. In two animals we demonstrated hepatic glucose production from lactate. One of these was in active labor at the time of study, and one aborted within hours of the study. We conclude that the prenatal cortisol surge alone is not responsible for the onset of hepatic gluconeogenesis in the perinatal period. However, cortisol may have a permissive action, promoting hepatic gluconeogenesis in response to other hormonal stimuli.     

Rates of appearance and disappearance of plasma lactate after oral glucose: implications for indirect-pathway hepatic glycogen repletion in man

3-14C-lactate and 6-3H-glucose were infused to determine rates of plasma lactate appearance (Ra), disappearance (Rd) and conversion to plasma glucose following ingestion of 75 g glucose in 10 healthy volunteers. Lactate Ra (mumol/kg/min) increased from 10.2 +/- 0.9 to a peak of 15.7 +/- 0.8 at 60 min (p less than 0.01). Lactate Rd increased from 10.2 +/- 0.9 to a peak of 15.9 +/- 4.2 at 120 min (p less than 0.001). During the 3-hour experiment, 15.0 +/- 1.1 g of lactate appeared in plasma, and 14.1 +/- 1.2 g disappeared from plasma. Of lactate Rd, approximately 20% (2.8 +/- 0.2 g) was converted to plasma glucose leaving a maximum 11.3 +/- 0.8 g lactate available for indirect-pathway glycogen synthesis. The present data indicate that in man the indirect pathway could account for about 40% of hepatic glycogen repletion via uptake of circulating gluconeogenic precursors.     

Glucose and lactate kinetics in the neonate.

To evaluate the ontogeny of neonatal glucose homeostasis, glucose production and lactate production have been measured in nine prematurely born appropriate for gestational age neonates [birth weight 1985 +/- 100 g, (SEM) gestational age 33.6 +/- 0.7 weeks] and five full term appropriate for gestational age neonates [birth weight 3254 +/- 111 g, gestational age 40.8 +/- 0.4 wks] and compared to six non pregnant, nondiabetic adults [weight of 57.7 +/- 2.2 kg, age 32 +/- 2 years]. Ra glucose (preterm) averaged 27.7 +/- 2.8 mumol.kg-1 min-1 (5.0 +/- 0.5 mg.kg-1 min-1) and Ra glucose (term) averaged 28.9 +/- 3.9 mumol.kg-1 min-1 (5.2 +/- 0.7 mg.kg-1 min-1); both were higher than the Ra glucose of the adult controls (16.1 +/- 2.8 mumol.kg-1 min-1 (2.9 +/- 0.5 mg.kg-1 min-1) (P less than 0.05 vs preterm and P less than 0.05 vs. term). Ra lactate (preterm) averaged 100 +/- 11.9 mumol.kg-1 min-1 (9.1 +/- 1.1 mg.kg-1 min-1) and Ra lactate (term) average 77.2 +/- 13.0 mumol.kg-1 min-1 (7.1 +/- 1.2 mg.kg-1 min-1); both were higher than the Ra lactate of the adult controls 35.9 +/- 6.5 mumol.kg-1 min-1 (3.3 +/- 0.6 mg.kg-1 min-1) (P less than 0.01 vs preterm and P less than 0.05 vs. term). The potential for gluconeogenesis from lactate was estimated by determining the ratio of [Ra Lactate/Ra Glucose]. The [Ra Lactate/Ra Glucose] (preterm) (187 +/- 12 (x10(-2)) was similar to that of the [Ra Lactate/Ra Glucose] (term) (136 +/- 16) (x10(-2)).(ABSTRACT TRUNCATED AT 250 WORDS)     

Gluconeogenesis by the fetal sheep liver in vivo

Hepatic gluconeogenesis is an important source of glucose postnatally. Whether hepatic gluconeogenesis contributes to fetal glucose supply has not been studied directly in vivo. Previous studies of gluconeogenesis in fetal sheep have assessed total fetal glucose production, and the results have been controversial. To assess the specific role of the liver in gluconeogenesis in fetal sheep, we placed catheters in the right or left hepatic vein, umbilical vein and the inferior vena cava of six fetal sheep (mean gestational age 134 days) and infused a radioactive gluconeogenic substrate (14C-lactate or 14C-alanine) into the fetal inferior vena cava. We measured 14C-glucose radioactivity (dpm/ml) in the right or left hepatic vein and calculated the arteriovenous difference in 14C-glucose radioactivity (dpm/ml) across the right or left liver lobe. We found that only 0.35% of the 14C substrates perfusing either the right or the left hepatic lobe of the fetal liver were converted to 14C-glucose. Even when considerable glucose was released by the liver, the percentage of substrates converted to glucose remained very low (maximum 1.7%), indicating that gluconeogenesis did not contribute significantly to the glucose released. We conclude that gluconeogenesis by the fetal liver contributes negligibly to the glucose supply in fetal sheep.     

Effect of verapamil on glycogenolysis and gluconeogenesis in the perfused rat liver

In perfused livers from fed rats, rates of glucose production (glycogenolysis) were 133 +/- 12 mumol/g/hr. Infusion of 2 microM verapamil into these livers decreased the rates of glucose production significantly to 97 +/- 15 mumol/g/hr within 10 min. Conversely, rates of production of lactate plus pyruvate (glycolysis) of 64 +/- 6 mumol/g/hr were not significantly altered by verapamil (60 +/- 3 mumol/g/hr). When 50 microM verapamil was infused, however, rates of both glycogenolysis and glycolysis were diminished to 56 +/- 11 and 43 +/- 5 mumol/g/hr, respectively. In perfused livers from fasted rats, infusion of 20 mM fructose increased the rates of production of glucose (gluconeogenesis) significantly from 11 +/- 7 to 121 +/- 17 mumol/g/hr. These rates reached 138 +/- 7 mumol/g/hr upon the simultaneous infusion of verapamil (2 microM). In these livers, fructose also increased rates of production of lactate from 6 +/- 2 to 132 +/- 11 mumol/g/hr, which were further increased to 143 +/- 8 mumol/g/hr when 2 microM verapamil was infused. The results show that calcium-dependent processes involved in hepatic carbohydrate metabolism respond differently to the calcium channel blocker verapamil. Low concentrations of verapamil inhibited glycogenolysis significantly while having no effect on either glycolysis or gluconeogenesis. These data suggest that these two processes have different sensitivities to changes in intracellular calcium concentrations and/or different sources of regulatory calcium.     

Gluconeogenesis in the ruminant fetus: evaluation of conflicting evidence from radiotracer and other experimental techniques

Conflicting evidence exists as to whether the gluconeogenetic process is active in the late gestation fetal lamb. In vitro evidence based on measurements of enzyme activity and substrate flux into glucose indicates that the capacity for gluconeogenesis exists in fetal liver. The in vivo conversion of [14C]lactate and [14C]alanine into glucose in the lamb fetus has been demonstrated. Lactate and alanine account for 49 and 2.3% of the fetal glucose pool, respectively. Although gluconeogenesis can occur in the fetal lamb, alterations in net rates of umbilical uptake of glucose or lactate, fetal blood glucose concentrations, fetal or maternal glucose replacement rates, or maternal nutrition may alter the observed rates of fetal gluconeogenesis.     

Lactate as substrate for glycogen resynthesis after exercise

Muscle glycogen levels in the perfused rat hemicorpus preparation were reduced two-thirds by electrical stimulation plus exposure to epinephrine (10(-7) M) for 30 min. During the contraction period muscle lactate concentrations increased from a control level of 3.6 +/- 0.6 to a final value of 24.1 +/- 1.6 mumol/g muscle. To determine whether the lactate that had accumulated in muscle during contraction could be used to resynthesize glycogen, glycogen levels were determined after 1-3 h of recovery from the contraction period during which time the perfusion medium (flow-through system) contained low (1.3 mmol/l) or high (10.5 or 18 mmol/l) lactate concentrations but no glucose. With the low perfusate lactate concentration, muscle lactate levels declined to 7.2 +/- 0.8 mumol/g muscle by 3 h after the contraction period and muscle glycogen levels did not increase (1.28 +/- 0.07 at 3 h vs. 1.35 +/- 0.09 mg glucosyl U/g at end of exercise). Lactate disappearance from muscle was accounted for entirely by output into the venous effluent. With the high perfusate lactate concentrations, muscle lactate levels remained high (13.7 +/- 1.7 and 19.3 +/- 2.0 mumol/g) and glycogen levels increased by 1.11 and 0.86 mg glucosyl U/g, respectively, after 1 h of recovery from exercise. No more glycogen was synthesized when the recovery period was extended. Therefore, it appears that limited resynthesis of glycogen from lactate can occur after the contraction period but only when arterial lactate concentrations are high; otherwise the lactate that builds up in muscle during contraction will diffuse into the bloodstream.     

Hepatic lactate uptake versus leg lactate output during exercise in humans.

The exponential rise in blood lactate with exercise intensity may be influenced by hepatic lactate uptake. We compared muscle-derived lactate to the hepatic elimination during 2 h prolonged cycling (62 +/- 4% of maximal O(2) uptake, (.)Vo(2max)) followed by incremental exercise in seven healthy men. Hepatic blood flow was assessed by indocyanine green dye elimination and leg blood flow by thermodilution. During prolonged exercise, the hepatic glucose output was lower than the leg glucose uptake (3.8 +/- 0.5 vs. 6.5 +/- 0.6 mmol/min; mean +/- SE) and at an arterial lactate of 2.0 +/- 0.2 mM, the leg lactate output of 3.0 +/- 1.8 mmol/min was about fourfold higher than the hepatic lactate uptake (0.7 +/- 0.3 mmol/min). During incremental exercise, the hepatic glucose output was about one-third of the leg glucose uptake (2.0 +/- 0.4 vs. 6.2 +/- 1.3 mmol/min) and the arterial lactate reached 6.0 +/- 1.1 mM because the leg lactate output of 8.9 +/- 2.7 mmol/min was markedly higher than the lactate taken up by the liver (1.1 +/- 0.6 mmol/min). Compared with prolonged exercise, the hepatic lactate uptake increased during incremental exercise, but the relative hepatic lactate uptake decreased to about one-tenth of the lactate released by the legs. This drop in relative hepatic lactate extraction may contribute to the increase in arterial lactate during intense exercise.     

Route-dependent effect of nutritional support on liver glucose uptake

The liver is a major site of glucose disposal during chronic (5 day) total parenteral (TPN) and enteral (TEN) nutrition. Net hepatic glucose uptake (NHGU) is dependent on the route of delivery when only glucose is delivered acutely; however, the hepatic response to chronic TPN and TEN is very similar. We aimed to determine whether the route of nutrient delivery altered the acute (first 8 h) response of the liver and whether chronic enteral delivery of glucose alone could augment the adaptive response to TPN. Chronically catheterized conscious dogs received either TPN or TEN containing glucose, Intralipid, and Travasol for either 8 h or 5 days. Another group received TPN for 5 days, but approximately 50% of the glucose in the nutrition was given via the enteral route (TPN+EG). Hepatic metabolism was assessed with tracer and arteriovenous difference techniques. In the presence of similar arterial plasma glucose levels (approximately 6 mM), NHGU and net hepatic lactate release increased approximately twofold between 8 h and 5 days in TPN and TEN. NHGU (26 +/- 1 vs. 23 +/- 3 micromol.kg(-1).min(-1)) and net hepatic lactate release (44 +/- 1 vs. 34 +/- 6 micromol.kg(-1).min(-1)) in TPN+EG were similar to results for TPN, despite lower insulin levels (96 +/- 6 vs. 58 +/- 16 pM, TPN vs. TPN+EG). TEN does not acutely enhance NHGU or disposition above that seen with TPN. However, partial delivery of enteral glucose is effective in decreasing the insulin requirement during chronic TPN.     

Alterations in basal glucose metabolism during late pregnancy in the conscious dog

We assessed basal glucose metabolism in 16 female nonpregnant (NP) and 16 late-pregnant (P) conscious, 18-h-fasted dogs that had catheters inserted into the hepatic and portal veins and femoral artery approximately 17 days before the experiment. Pregnancy resulted in lower arterial plasma insulin (11 +/- 1 and 4 +/- 1 microU/ml in NP and P, respectively, P < 0.05), but plasma glucose (5.9 +/- 0.1 and 5.6 +/- 0.1 mg/dl in NP and P, respectively) and glucagon (39 +/- 3 and 36 +/- 2 pg/ml in NP and P, respectively) were not different. Net hepatic glucose output was greater in pregnancy (42.1 +/- 3.1 and 56.7 +/- 4.0 micromol. 100 g liver(-1).min(-1) in NP and P, respectively, P < 0.05). Total net hepatic gluconeogenic substrate uptake (lactate, alanine, glycerol, and amino acids), a close estimate of the gluconeogenic rate, was not different between the groups (20.6 +/- 2.8 and 21.2 +/- 1.8 micromol. 100 g liver(-1). min(-1) in NP and P, respectively), indicating that the increment in net hepatic glucose output resulted from an increase in the contribution of glycogenolytically derived glucose. However, total glycogenolysis was not altered in pregnancy. Ketogenesis was enhanced nearly threefold by pregnancy (6.9 +/- 1.2 and 18.2 +/- 3.4 micromol. 100 g liver(-1).min(-1) in NP and P, respectively), despite equivalent net hepatic nonesterified fatty acid uptake. Thus late pregnancy in the dog is not accompanied by changes in the absolute rates of gluconeogenesis or glycogenolysis. Rather, repartitioning of the glucose released from glycogen is responsible for the increase in hepatic glucose production.     

Regulation of gluconeogenesis during exposure of young rats to hypoxic conditions

1. Two-day-old rats were exposed at constant temperature to atmospheres containing air and nitrogen with the air content varied in steps from 100 to 0%. By using this system of graded hypoxia a comparison was made between rates of gluconeogenesis from lactate, serine and aspartate in the whole animal and the concentrations of several liver metabolites. 2. Gluconeogenesis, expressed as the percentage incorporation of labelled isotope into glucose plus glycogen, proceeds linearly for 30min when the animals are incubated in a normal air atmosphere, but is completely suppressed if the atmosphere is 100% nitrogen. 3. Preincubation of animals for between 5 and 30min under an atmosphere containing 19% air results in the attainment of a new steady state with respect to gluconeogenesis and hepatic concentrations of ATP, ADP, AMP, lactate, pyruvate, beta-hydroxybutyrate and acetoacetate. 4. When lactate (100mumol), aspartate (20mumol) or serine (20mumol) was injected, it was shown that the more severe the hypoxia the greater the depression of gluconeogenesis. Under conditions when gluconeogenesis was markedly inhibited there were no changes in the degree of phosphorylation of hepatic adenine nucleotides, but free [NAD(+)]/[NADH] ratios fell in both cytosol and mitochondrial compartments of the liver cell. 5. Measurements of total liver NAD(+) and NADH showed that the concentrations of these nucleotide coenzymes changed less with anoxia, in comparison with the concentration ratio of free coenzymes. 6. Calculations showed that the difference in NAD(+)-NADH redox potentials between mitochondrial and cytosol compartments increased with the severity of hypoxia. 7. From the constancy of the concentrations of adenine nucleotides it is concluded that liver of hypoxic rats can conserve ATP by lowering the rate of ATP utilization for gluconeogenesis. Gluconeogenesis may be regulated in turn by the changes in mitochondrial and cytosol redox state.     

Changes in fetal ovine metabolism and oxygen delivery with fetal bypass

Since the 1980s, attempts at experimental fetal cardiac bypass for the purpose of correcting severe congenital heart defects in the womb have been hampered by deterioration of placental function. This placental pathophysiology in turn affects transplacental transport of nutrients and gas exchange. To date, the effects of bypass on fetal metabolism and oxygen delivery have not been studied. Nine Suffolk sheep fetuses from 109-121 days gestation were instrumented and placed on fetal bypass for 30 min and followed postbypass for 2 h. Blood gases, glucose, and lactate were serially measured in the fetal arterial and umbilical venous circulations throughout the procedure. Insulin and glucagon levels were serially measured by immunoassay in fetal plasma. Fetal-placental hemodynamics were measured continuously. The expression of glycogen content was examined in fetal liver. Oxygen delivery to the fetus and fetal oxygen consumption were significantly deranged after the conduct of bypass (in-group ANOVA (P = 0.001) and overall contrast (P = 0.072) with planned contrast (P < 0.05) for delivery and consumption, respectively). There were significant alterations in fetal glucose metabolism in the postbypass period; however, insulin and glucagon levels did not change. Fetal liver glycogen content appeared lower after bypass. This is the first report documenting fetal metabolic dysregulation that occurs in response to the conduct of fetal bypass. The significant alterations in fetal oxygen and glucose delivery coupled with hepatic glycogen depletion complicate and impede fetal recovery. These initial findings warrant further investigation of interventions to restore metabolic and hemodynamic homeostasis after fetal bypass.     

Consumption of carbohydrates, amino acids and oxygen across the intestinal circulation in the fetal sheep

Since large volumes of nutrient rich amniotic fluid are swallowed by the fetus, it has been suggested that intestinal digestion and absorption contribute significantly to fetal nutrition. To see if nutrients are being gained across the intestine, we measured blood flow and intestinal arteriovenous concentration differences of glucose, alpha-amino nitrogen, lactate, fructose and oxygen in eleven third trimester fetal sheep with chronically implanted vascular catheters. We found that in fetal blood circulating through the intestine nutrient concentration decreased significantly with arterio-venous concentration differences for glucose of 0.78 +/- 0.21 (SEM) mg/dl (P < 0.002), for alpha-amino nitrogen of 0.52 +/- 0.15 mg/dl (P < 0.005), for lactate of 0.68 +/- 0.24 mg/dl (P < 0.05) and for oxygen of 1.50 +/- 0.08 ml/dl (P < 0.001). Fructose concentration did not change. Blood flow to the fetal intestine averaged 89.92 +/- 7.16 ml/min and the intestine consumed 0.74 +/- 0.24 mg of glucose, 0.43 +/- 0.17 mg of alpha-amino nitrogen, 0.83 +/- 0.28 mg of lactate and 1.37 +/- 0.14 ml of oxygen per minute. Compared to previously published values for the umbilical uptake of nutrients the fetal intestine metabolizes about 4% of the glucose, 6% of the alpha-amino nitrogen, 13% of the lactate and 6% of the oxygen obtained across the umbilical circulation. Intestinal absorption does not appear to serve as a source of simple nutrients for the rest of the fetus, in fact intestinal metabolism extracts significant amounts of nutrients from fetal blood.     

Induction of premature delivery in sheep following infusion of cortisol to the fetus. I. The effect of maternal administration of progestagens

Premature induction of delivery in fetuses infused with graded doses of cortisol was brought about in 123.5 +/- 7.7 h (mean +/- SEM, n = 6) after the start of cortisol infusion. This treatment caused a rise in fetal plasma cortisol similar to that observed at normal delivery. Maternal and fetal progesterone and 20 alpha-dihydroprogesterone concentrations decreased to basal levels during infusion of cortisol to the fetus. Induction of premature delivery was delayed or prevented by concomitant treatment of the ewe with progestagen. Maternal intramuscular injection of 100 mg progesterone, 2 times daily, prevented delivery in four of four ewes treated during the time that cortisol was infused into the fetus (11-13 days). Maternal plasma progesterone and 20 alpha-dihydroprogesterone concentrations were maintained during this period, but fetal plasma progesterone concentrations decreased to the same extent as in the fetuses infused with cortisol alone. A single intramuscular injection of 250 mg of medroxyprogesterone acetate to ewes on the day before commencement of infusion of cortisol to the fetus prevented delivery in four of six ewes during the time that cortisol was infused for 9, 13, 14, and 15 days, respectively. One ewe delivered a live lamb at 133.5 h and another at 147.7 h after the start of infusion of cortisol to the fetus. Maternal and fetal plasma cortisol, progesterone, and 20 alpha-dihydroprogesterone concentrations were similar to those observed during infusion of cortisol alone to the fetus. Although fetal cortisol concentrations rose in a similar fashion, and to a similar extent, in all three groups during infusion of cortisol to the fetus, fetal 11-desoxycortisol concentrations only rose above basal levels close to the time of delivery in cortisol-infused fetuses or, in the progestagen-treated groups, when the fetus showed signs of being stressed.     

Effect of acutely-induced lactic acidemia on fetal breathing movements, heart rate, blood pressure, ACTH and cortisol in sheep.

Experiments were conducted in 8 chronically-catheterized fetal sheep at 125-135 days gestation in order to determine the effect of exogenously administered lactic acid to the fetus on fetal heart rate, blood pressure, breathing movements (FBM), electrocortical activity (ECOG), plasma immunoreactive (IR-ACTH) and cortisol concentrations. When fetal arterial pH decreased from 7.37 +/- 0.01 during the control period to 7.20 +/- 0.01, there was an initial bradycardia followed by tachycardia but no change in blood pressure. The amplitude of FBM increased 2-fold initially in association with an increase in PCO2 from 47.9 +/- 2.1 mmHg to 58.8 +/- 3.6 mmHg at 5 min into the lactate infusion. There was no change in the incidence of FBM or low-voltage ECOG and there was no change in the plasma concentrations of IR-ACTH and cortisol with the infusion of lactate. We conclude that the major effects of acutely elevating circulatory lactate concentrations in fetal sheep are to increase the amplitude of FBM and to cause an initial bradycardia followed by a tachycardia.