Identical phalangeal defects induced by phenytoin and nifedipine suggest fetal hypoxia and vascular disruption behind phenytoin teratogenicity.

In previous experimental studies in rabbits, we have shown that vasodilating drugs (including nifedipine) cause distal digital defects. These defects were preceded by edema, hemorrhage, and finally necrosis of the developed cartilage in the phalanges. The underlying mechanism is most likely a fetal hypoxic response, secondary to maternal hypotension and decreased uteroplacental blood flow. Since phenytoin is known to cause distal digital defects both in man and rabbits, we decided to compare the defects provoked by oral administration of phenytoin (100 mg/kg) versus nifedipine (8.3 mg/kg) to New Zealand White rabbits on days 6-18 of gestation. In order to investigate phase-specificity, phenytoin (150 mg/kg) was given on days 14-17. The result of single dose administration on day 16 of phenytoin (300 mg/kg) versus nifedipine (33.2 mg/kg) was also studied. In this latter experiment maternal heart rate was measured up to 21 hours after phenytoin administration. Phenytoin induced digital defects identical with those produced by nifedipine and caused marked maternal cardiodepression. The defects consisted of a reduction, absence, or abnormal structure of the distal phalanges. The distal phalanx of the fourth digit on the hindpaw was the first to be affected, with inclusion of other phalanges, both on the hind- and forepaws, with increasing dose. The sensitive period for induction and histological appearance of these defects was identical for phenytoin and nifedipine. These results suggest that vascular disruption due to a fetal hypoxic response lies behind phenytoin teratogenicity, as has been shown for vasodilators. A cardiodepressive action on the maternal and fetal hearts, possibly in combination with decreased uteroplacental blood flow, is discussed as a probable factor behind phenytoin teratogenicity.     

On the pathogenesis of abortion in acute nitrite toxicosis of pregnant dairy cows

Six cows, 220 to 260 d pregnant, were used to study possible abortifacient effects of absorbed nitrite. Maternal and fetal bloodvessels were catheterized. Nitrite was infused intravenously (i.v.) for 30 minutes on Days 1, 3 and 5, commencing at least 5 d postcatheteration. The dose used was 7, 9.5 and 12 mg NO(2)(-)/kg bodyweight, respectively. Nitrite caused a dose-related (P < 0.05) conversion of maternal hemoglobin (Hb) into methemoglobin (MHb); a 30 to 50% decrease of mean arterial bloodpressure; an increase in heart rate, with dose-related recovery periods; and a decrease in partial oxygen tension (PO(2)) of maternal blood. Maternal partial carbon dioxide tension (PCO(2)), pH and electromyographic activity of the uterus were unchanged. Fetal changes included a small increase in MHb content, variable changes in heart rate (tachycardia and bradycardia), and decreases in fetal PO(2), with considerable differences between animals. All calves were born alive. Three cows calved early, 2 to 3 d after the highest nitrite dose. The hematological and cardiovascular data suggest that these three fetuses experienced a more serious hypoxemic stress than the other fetuses.     

Fetal cardiovascular responses to asphyxia induced by decreased uterine perfusion

Cardio-respiratory responses to asphyxia produced by decreased uterine perfusion were studied in 15 sheep fetuses. In chronic (spinal-anesthetized) and acute (inhalation-anesthetized) preparations, we measured fetal PO2, PCO2, pH, heart rate, arterial and umbilical venous pressures at rest and 5 min after controlled reductions of maternal aortic blood flow. Umbilical blood flow was determined by electromagnetic flow transducer on the fetal descending aorta with the iliac arteries ligated, in conjunction with radionuclide-labelled microspheres. In contrast to previous studies in which fetal hypoxaemia was produced by decreased maternally inspired O2 concentrations, decreasing degrees of uterine perfusion were associated with increasing degrees of hypercapnea and acidemia, as well as hypoxaemia. In chronic experiments, heart rate and umbilical blood flow fell significantly in response to decreased uterine perfusion with all degrees of hypoxaemia studied. In acute experiments, during the control period, PO2 values were similar to those of chronic experiments while values for pH and umbilical blood flow were lower and those for umbilical vascular resistance were higher. In the acute experiments, hypoxic stresses identical to those in the chronic studies failed to produce significant hemodynamic changes, except for bradycardia in response to severe hypoxaemia. These differences were apparently due to the pharmacologic effects of halothane and the operative stresses.     

Erythropoietin responses to progressive blood loss over 10 days in the ovine fetus

Long-term loss of fetal blood can occur with fetomaternal hemorrhage, vasoprevia, or placental previa. Our objective was to determine the effects of progressive fetal blood loss over 10 days on fetal plasma erythropoietin (EPO) concentration and its relationship to arterial PO(2), hematocrit, and the volume of blood loss. Late-gestation fetal sheep (n = 8) were hemorrhaged daily at a rate of 1 ml/min over 10 days. The extent of hemorrhage differed in each fetus and ranged from 30 to 80 ml/day, with the cumulative volume removed ranging from 78 to 236 ml/kg estimated fetal weight. Four fetuses served as time controls. EPO concentration measurements were by radioimmunoassay. Statistical analyses included regression, correlation, and analysis of variance. We found that EPO and arterial PO(2) were unchanged until the cumulative hemorrhage volume exceeded 20-40 ml/kg. Once this threshold was exceeded, plasma EPO concentration increased progressively throughout the study and averaged 14.3 +/- 3.2 times basal values on day 10. EPO concentration, arterial PO(2), and hematocrit changes were related curvilinearly to cumulative hemorrhage volume (P < 0.01), whereas the relationship between plasma EPO and arterial PO(2) was log linear (P < 0.001). We conclude that 1) fetal plasma EPO concentration and arterial PO(2) are insensitive to a slow, mild-to-moderate blood loss over several days; 2) unlike the rapid return of EPO to normal within 48 h after acute hemorrhage, fetal EPO concentration undergoes a progressive increase with moderate-to-severe blood loss over several days; 3) the long-term hemorrhage-induced changes in EPO are best correlated with arterial PO(2); and 4) the fetal EPO response to hemorrhage does not appear to be limited by the fetus's ability to produce EPO.     

Plasma adenosine and cardiovascular responses to dipyridamole in fetal sheep.

The effects of dipyridamole infusion on fetal arterial plasma adenosine level, [ADO], and the systemic cardiovascular system were studied in 10 fetal sheep at 130-135 days gestational age. Dipyridamole (0.25 mg/kg) was infused into the fetuses intravenously during normoxia and hypoxia. Plasma [ADO] was measured using high-performance liquid chromatography, (HPLC), and fetal heart rate and arterial blood pressure were monitored throughout the study. These studies were performed in the absence and presence of theophylline, an adenosine receptor antagonist. During normoxia (PO2, 23.8 +/- 2.0 Torr), dipyridamole infusion increased fetal plasma [ADO] from 0.82 +/- 0.10 microM to 1.41 +/- 0.16 microM within 1 min (P < 0.01) and fetal heart rate from 157 +/- 6 bpm to 174 +/- 7 bpm (P < 0.01), but did not change mean blood pressure. Fetal plasma [ADO] and fetal heart rate returned to basal levels quickly. Treatment with theophylline did not alter the elevation of plasma [ADO] after dipyridamole infusion, but abolished responses of fetal heart rate to dipyridamole infusion. After 15 min of hypoxia with an average arterial PO2 of 15.4 +/- 1.1 Torr, fetal plasma [ADO] increased to 1.15 +/- 0.14 microM (P < 0.01). Dipyridamole infusion then further raised fetal plasma [ADO] to 1.67 +/- 0.27 microM (P < 0.01). The duration of the increase of fetal plasma [ADO] after dipyridamole infusion was no longer in hypoxia than in normoxia, however there was no significant change in the pattern of transient fetal bradycardia and persistent hypertension.(ABSTRACT TRUNCATED AT 250 WORDS)     

Umbilical cord occlusion stimulates breathing independent of blood gases and pH

The role of umbilical cord occlusion in the initiation of breathing at birth was investigated by use of 16 unanesthetized fetal sheep near full term. Artificial ventilation with high-frequency oscillation was used to control fetal arterial blood gas tensions. At baseline, PCO2 was maintained at control fetal values and PO2 was elevated to between 25 and 50 Torr. In the first study on six intact and four vagotomized fetuses, arterial PCO2 and PO2 were maintained constant during two 30-min periods of umbilical cord occlusion. Nevertheless, the mean fetal breathing rate increased significantly when the umbilical cord was occluded. In the second study on six intact fetuses, hypercapnia (68 Torr) was imposed by adding CO2 to the ventilation gas. When the umbilical cord was occluded, there was a significantly greater stimulation of breathing (rate, incidence, and amplitude) in response to hypercapnia than in response to hypercapnia alone. During cord occlusion, plasma prostaglandin E2 concentration decreased significantly. Results indicate that cord occlusion stimulates breathing possibly by causing the removal of a placentally produced respiratory inhibitor such as prostaglandin E2 from the circulation.     

Repetitive reduction of uterine blood flow and its influence on fetal transcutaneous PO2 and cardiovascular variables

The influence of repeated asphyxia on fetal transcutaneous PO2, relative local skin perfusion, heart rate, blood gases and pH was investigated in 15 experiments on 8 acutely instrumented sheep fetuses in utero between 125 and 145 days gestation (term is 147 days). Uterine blood flow was intermittently arrested (11 times within 33 min) by intra-vascular maternal aortic occlusion, exposing the fetuses to repeated episodes of asphyxia of 30 (n = 3), 60 (n = 9) and 90 (n = 3) s duration. The fetal transcutaneous PO2 fell as the duration of asphyxia (2 alpha less than 0.01), heart rate deceleration area (2 alpha less than 0.01) and acidaemia (2 alpha less than 0.01) increased. With decreasing skin perfusion, which was dependent on the duration of asphyxia (2 alpha less than 0.001) and acidaemia (2 alpha less than 0.001), a discrepancy developed between transcutaneous and arterial PO2. The increase (delta) in transcutaneous-arterial PO2 difference was related linearly to the duration of asphyxia (2 alpha less than 0.01), the mean haemoglobin oxygen saturation (2 alpha less than 0.001), acidaemia (2 alpha less than 0.001) and relative local skin flow (2 alpha less than 0.05). It was highest after severe episodes of asphyxia (90 s), when O2 saturation, skin blood flow and arterial blood pH values were low. Fetal heart rate deceleration area was only correlated with the cutaneous-arterial PO2 difference when the mean fetal haemoglobin oxygen saturation was below 35%. Thus, a discrimination of heart rate decelerations that are significant for the fetus seems to be possible, when associated with low transcutaneous PO2 values. We conclude that in the sheep fetus transcutaneous PO2 measurements during repeated asphyxial episodes yield information on fetal oxygenation and on the skin vasomotor response.     

Phenytoin-induced cleft palate: evidence for embryonic cardiac bradyarrhythmia due to inhibition of delayed rectifier K+ channels resulting in hypoxia-reoxygenation damage

BACKGROUND: Phenytoin (PHT) teratogenicity has been related to embryonic arrhythmia due to the capacity of PHT to block I(K) channels pharmacologically, resulting in hypoxia-reoxygenation damage. The aim of this study was to further elucidate the proposed mechanism. METHODS: Pregnant CD-1 mice were given PHT (85 mg/kg) or saline intraperitoneally on gestational days 10-11. Embryonic heart rhythm and presence of hemorrhage in orofacial region was recorded on day 12, fetuses were examined for malformations on day 18. Embryonic heart rate was also recorded on individual days after dosing days 9-16. In addition, PHT was given at doses of 10, 25, or 85 mg/kg on day 12 for analysis of plasma concentrations. RESULTS: PTH-induced bradycardia and arrhythmia in approximately 20% of the embryos, 48% showed hemorrhage in the orofacial region; 39% of the fetuses had cleft palate. The region in which hemorrhages were visible in the embryo corresponded with the region where tissue deficiency (cleft palate) was visible in the fetus at term. None of the controls showed hemorrhages, dysrhythmia, or cleft palate. PHT affected embryonic heart rates on days 9-13, but not on days 14-16. Single dose administration on day 12, the most sensitive day, resulted in a dose-dependent decrease in embryonic heart rate (12-34%). Embryonic arrhythmia occurred at 25 and 85, but not at 10 mg/kg or in the controls. Mean maternal free plasma concentrations were 6 and 14 micromol/L in the 10- and 25-mg/kg groups, respectively. CONCLUSIONS: PHT-induced cleft palate was preceded by embryonic dysrhythmia and hemorrhage in the orofacial region. Embryonic heart rhythm was phase specifically affected, as described for selective I(Kr) channel blockers, at clinically relevant concentrations. The results support the idea that PHT teratogenicity is a consequence of pharmacologically induced dysrhythmia and hypoxia-related damage.     

Teratogenic effects of dosage levels and time of administration of carbamazepine, sodium valproate, and diphenylhydantoin on craniofacial development in the CD-1 mouse fetus

The objective of this investigation was to study the teratogenic effects of dosage levels and time of administration of three anticonvulsant drugs (carbamazepine [CMZ], sodium valproate [NaV], and diphenylhydantoin [DPH]) on craniofacial development in the CD-1 mouse fetus. Pregnant females were intubated on each of days 8-10, 11-13, 14-16, and 8-16 of gestation with the following dose levels for each drug: 375, 563, 938 mg/kg CMZ; 225, 338, 563 mg/kg NaV; 50, 75, 125 mg/kg DPH. Appropriate control groups were maintained for each drug. On gestation day 17, pregnant females were killed and implantation sites were recorded as live, dead, or resorbed. All live fetuses were examined for craniofacial defects. Results of examination of 1,398 fetuses indicated that CMZ, NaV, and DPH were teratogenic and embryotoxic at all dose levels. This study indicated that the observed decrease in mean fetal weight was drug-, dose-, and time-dependent. There was a drug-, dose-, and time-dependent increase observed in the number of dead fetuses, whereas the number of resorbed fetuses was observed to be only time-dependent. The observed frequencies of hydrocephalies, secondary palatal clefts, and submucous palatal clefts were significant for all three factors (drug, dose, and time) whereas the observed frequencies of hematomas and exencephalies were significant only for drug and time. Cleft lips were observed only in the highest dose level of DPH. Uterine horn distribution of defects indicated that fetuses located at the proximal end of the horns were less subject to major defects than those fetuses located at the distal end of the uterine horns. Fetuses with craniofacial hematomas were found in the proximal one-third of the uterine horn, resorbed fetuses, and fetuses with submucous palatal clefts in the middle one-third of the uterine horns and dead fetuses and fetuses with exencephalies, cleft lips, and secondary palatal clefts were localized in the distal one-third of the uterine horns. In comparing the effect of drug, dosage, and time on the development of craniofacial malformations in the CD-1 mouse fetus, CMZ was the least teratogenic and embryotoxic of the three anticonvulsant drugs employed in this study.     

Mechanism of stimulation of pulmonary prostacyclin synthesis at birth

In order to investigate the mechanism behind ventilation-induced pulmonary prostacyclin production at birth, chloralose anesthetized, exteriorized, fetal lambs were ventilated with a gas mixture that did not change blood gases (fetal gas) and unventilated fetal lungs were perfused with blood containing increased O2 and decreased CO2. Ventilation with fetal gas (3%O2, 5%CO2) increased net pulmonary prostacyclin (as 6-keto-PGF1 alpha) production from -5.1 +/- 4.4 to +12.6 +/- 7.6 ng/kg X min. When ventilation was stopped, net pulmonary prostacyclin production returned to nondetectable levels. Ventilation with gas mixtures which increased pulmonary venous PO2 and decreased PCO2 also stimulated pulmonary prostacyclin production, but did not have greater effects than did ventilation with fetal gas. In order to determine if increasing PO2 or decreasing PCO2 could stimulate pulmonary prostacyclin production independently from ventilation, unventilated fetal lamb lungs were perfused with blood that had PO2 and PCO2 similar to fetal blood, blood with elevated O2, and blood that had PO2 and PCO2 values similar to arterial blood of newborn animals. Neither increased O2 nor decreased CO2 in the blood perfusing the lungs stimulated pulmonary prostacyclin synthesis. We conclude that the mechanism responsible for the stimulation of pulmonary prostacyclin production with the onset of ventilation at birth is tissue stress during establishment of gaseous ventilation and rhythmic ventilation.     

Renal and metabolic effects of glucagon in the fetus.

The effects of pharmacological doses of glucagon (0.5 micrograms/kg/min) were studied in 8 chronically-catheterised fetal sheep. These doses of glucagon raised fetal blood glucose, and caused a small fall in fetal arterial PO2 (P less than 0.05). Arterial PCO2 rose (P less than 0.05) and pH fell (P less than 0.05) while plasma osmolality increased (P less than 0.01). There were no effects of glucagon on fetal renal function but in the fetus, like the adult, i.v. glucagon caused increases in heart rate (P less than 0.01) which were not associated with changes in arterial pressure.     

Male disadvantage? Fetal sex and cardiovascular responses to asphyxia in preterm fetal sheep

Clinically and experimentally male fetuses are at significantly greater risk of dying or suffering injury at birth, particularly after premature delivery. We undertook a retrospective cohort analysis of 60 female and 65 male singleton preterm fetal sheep (103-104 days, 0.7 gestation) with mean arterial blood pressure (MAP), heart rate, and carotid and femoral blood flow recordings during 25 min of umbilical cord occlusion in utero. Occlusions were stopped early if fetal MAP fell below 8 mmHg or if there was asystole for >20 s. Fetuses that were able to complete the full 25-min period of occlusion showed no differences between sexes for any cardiovascular responses. Similar numbers of occlusions were stopped early in males (mean: 21 min, n = 16) and females (mean: 23 min, n = 16); however, they showed different responses. Short-occlusion males (n = 16) showed a slower initial fall in femoral vascular conductance, followed by greater bradycardia, hypotension, and associated organ hypoperfusion compared with full-occlusion fetuses. In contrast, short-occlusion females (n = 16) showed a significantly more rapid early increase in femoral vascular conductance than the full-occlusion fetuses, followed by worsening of bradycardia and hypotension that was intermediate to the full-occlusion fetuses and short-occlusion males. Among all fetuses, MAP at 15 min of occlusion, corresponding with the time of the maximal rate of fall, was correlated with postmortem weight in males (R(2) = 0.07) but not females. In conclusion, male and female fetuses showed remarkably similar chemoreflex and hemodynamic responses to severe asphyxia, but some males did show impaired hemodynamic adaptation within the normal weight range.     

Ethylnitrosourea (ENU)-induced apoptosis in the rat fetal tissues

Ethylnitrosourea (ENU), a well known DNA alkylating agent, induces anomalies in the central nervous system (CNS), craniofacial tissues and male reproductive organs. In this study, pregnant rats were treated with 60 mg/kg ENU at day 13 of gestation, and their fetuses were examined from 1 to 48 hours after treatment (HAT) to find a clue for clarifying the mechanisms of the ENU fetotoxicity and teratogenicity. From 3 to 12 HAT, the moderate to marked increase in the number of pyknotic cells was detected in the fetal CNS, craniofacial mesenchymal tissues, gonads and so on. These pyknotic cells had nuclei positively stained by the TUNEL method, which is widely used for the detection of apoptotic nuclei, and they also showed electron microscopic characteristics identical to those of apoptotic cells. The present results strongly suggest that excess cell death by apoptosis in the fetal CNS, craniofacial tissues and gonads may have a close relation to the later occurrence of anomalies reported in these tissues following ENU-administration.     

The effect of vasopressin on fetal oxygenation in sheep

To examine the effects of vasopressin on fetal oxygenation the hormone was infused intravenously for 1 h (1.4-3.5 mU X min-1 X kg fetal weight-1) to chronically catheterized fetal lambs in utero (113-137 days gestation). Arterial pressure rose (48.3 to 59.6 mmHg) (1 mmHg = 133.322 Pa) and heart rate fell (185.3 to 141.0 beats/min) during the infusion. There was a significant increase in fetal arterial PO2 (20.0 to 23.1 mmHg) and significant declines in pH (7.414 to 7.381) and base excess. Umbilical blood flow rose, and the percentage increase in flow (23%) was identical to the proportional rise in arterial pressure. Accompanying the rise in umbilical blood flow was a rise in umbilical oxygen delivery. But as there was no change in fetal oxygen consumption, fractional oxygen extraction by the fetus fell significantly (0.31 to 0.25). These data indicate that the vasopressin-induced rise in fetal vascular PO2 results from an increase in umbilical oxygen delivery and concomitant fall in fractional extraction. Fetal vasopressin levels are greatly elevated during hypoxia, and under conditions of reduced oxygen supply, the effects of the hormone on umbilical oxygen delivery and vascular PO2 could have definite survival value.     

The effect of hyperglycemia on acid-base and sympathoadrenal responses in the hypoxemic fetal monkey.

We investigated the influence of hyperglycemia on the fetal acid-base and sympathoadrenal responses to hypoxemia (maternal FIO2 9%) in rhesus monkey fetuses. In chronic preparations, we determined PO2, O2 content, PCO2, pH, lactate, glucose, insulin, catecholamines, heart rate, and arterial pressure. Combined hyperglycemia and hypoxemia resulted in a decrease in fetal pH and an increase in lactate; however, the magnitude of these changes was only modestly, and not significantly, greater than those observed during euglycemic hypoxemia. These effects were much less striking than expected, based on earlier work in sheep (Shelley, Bassett & Milner, 1975; Robillard, Sessions, Kennedy & Smith, 1978). Although catecholamines increased significantly in response to hypoxemia both in hyperglycemic and euglycemic fetuses, the increase was less in the hyperglycemic group, possibly resulting from a modulating effect of the high glucose concentration on catecholamine release from the adrenal medulla. Finally, a significant fetal insulin response to hyperglycemia was seen which, suggestively, was partially inhibited in the presence of hypoxemia and its associated increase in sympathoadrenal activity.     

Cocaine as a cause of congenital malformations of vascular origin: experimental evidence in the rat

Cocaine hydrochloride was administered to pregnant Sprague-Dawley rats as a single intraperitoneal dose or as two doses 1-4 hours apart. A single dose administered on day 16 of gestation was teratogenic in a dose-dependent manner, with 40 mg/kg being a no-effect dose and 50 mg/kg the lowest teratogenic dose; 80 mg/kg was lethal to the dam. Forty-eight hours after exposure to a teratogenic dose on day 16 of pregnancy, the fetuses showed severe hemorrhage and edema in the their extremities, particularly the footplates, tail, genital tubercle, and upper lip/nose. When the fetuses were examined on day 21 of gestation, the main externally visible malformations were reduction deformities of the limbs and tail. When two doses of cocaine were administered 1-4 hours apart, the incidence of affected fetuses increased as the time interval between the two doses decreased. Two doses of cocaine administered 2 hours apart were not teratogenic on day 9, 10, 11, 12, 13, or 14 of gestation but did induce reduction deformities on days 15, 16, 17, 18, or 19. The same dose administered 1 hour apart was teratogenic on days 14-19. In general, cocaine administration on gestational days 14, 15, or 16 induced more severe and more widespread hemorrhage and edema than administration on days 17, 18, or 19. In the latter cases, damage was restricted to the distal parts of the hindlimb digits and the tail. The results show that in the rat cocaine is only teratogenic during the late organogenic or postorganogenic period.(ABSTRACT TRUNCATED AT 250 WORDS)     

Changes to metabolite concentration in fetal sheep subjected to prolonged hypobaric hypoxia

The effect of hypobaric hypoxaemia on the concentration of metabolic substrates in the ovine fetus and pregnant ewe with implanted vascular catheters, was investigated. At 120 to 141 days of gestation sheep were subjected to hypobaria (mean fetal carotid PO2 12.7 +/- 0.7 torr; n = 9) or normobaria (mean fetal carotid PO2 22.7 +/- 0.7 torr; n = 11; P less than 0.001). At 141 days gestation mean fetal weight was 3.46 +/- 0.72 kg in the hypobaric group compared to 4.15 +/- 0.51 in the normobaric group (P less than 0.05). Concentrations of glucose in maternal and fetal plasma and fructose in fetal plasma were similar in hypobaric and normobaric fetuses. The concentration of lactate in fetal plasma rose from 1.68 +/- 1.34 to 8.79 +/- 5.8 mmol/l (P less than 0.001) within 24 h of onset of hypoxia, but fell to 3.36 +/- 1.13 mmol/l by day 3 of treatment, though still significantly above the concentration of lactate in the control fetuses (1.47 +/- 0.47; P less than 0.001). There was no significant effect of hypoxia on the concentration of lactate or alanine in maternal plasma. Alanine concentration in the plasma of fetuses subjected to hypoxia significantly increased within 24 h of exposure (0.28 +/- 0.10 vs 0.58 +/- 0.39 mmol/l; P less than 0.01) and remained elevated for the duration of the study. There was no significant effect of gestational age on the concentration of metabolic substrates in either the control or experimental groups. Hypoxia is associated with a sustained rise in the concentration of plasma lactate and alanine in the fetus.(ABSTRACT TRUNCATED AT 250 WORDS)     

Histological effects of 6-mercaptopurine on the fetal rat central nervous system: a light-microscopic study.

Wistar rats were administered single doses of 16 or 50 mg/kg 6-mercaptopurine (6-MP) on day 12 of pregnancy. Necrosis in the fetal forebrain and spinal cord was studied by light microscope 6, 12, 14, 48, 72, and 81 h and 8 days afterward. The extent of necrosis was dose dependent. The first necroses were seen after 24 h, regardless of location (brain, spinal cord) or dose; but the extent was greatest after 48 h. All necrotic cells had a typical appearance; they were ballooned and often fragmented, their nuclei were darkly colored and frequently pyknotic, and they were often karyorhexic. Necroses appeared almost exclusively at sites of beginning cellular differentiation, i.e., in the intermediate zone. In the spinal cord the ventricular zone was also necrotic and the alar plate (dorsal horn) always affected. Phagocytizing cells (macrophages) appeared in the spinal cord after 48 h and in the brain after 72 h. After 81 h all the necrotic material had been phagocytized, at which time there was a massive congestion of the extra- and intracerebral vessels. Hemorrhages appeared in defined localizations. Eight days after exposure to 16 mg/kg 6-MP fetuses no longer showed any visible deviations. Fetuses exposed to 50 mg/kg showed deviations in the cytoarchitecture of the neopallium: an extremely broadened ventricular zone, few cells in the intermediate zone, and extensive rarefaction cells in the cortical plate with no clear layer structure. In the spinal cord, cleft formations were especially noticeable in the dorsal-horn region. All fetuses showed a hydrocephalus externus after 50 mg/kg. The mechanism leading to necrosis is discussed.     

Exercise responses in pregnant sheep: blood gases, temperatures, and fetal cardiovascular system

In an effort to examine the effects of maternal exercise on the fetus we measured maternal and fetal temperatures and blood gases and calculated uterine O2 consumption in response to three different treadmill exercise regimens in 12 chronically catheterized near-term sheep. We also measured fetal catecholamine concentrations, heart rate, blood pressure, cardiac output, blood flow distribution, blood volume, and placental diffusing capacity. Maternal and fetal temperatures increased a mean maximum of 1.5 +/- 0.5 (SE) and 1.3 +/- 0.1 degrees C, respectively. We corrected maternal and fetal blood gas values for the temperatures in vivo. Maternal arterial partial pressure of O2 (PO2), near exhaustion during prolonged (40 min) exercise at 70% maximal O2 consumption, increased 13% to a maximum of 116.7 +/- 4.0 Torr, whereas partial pressure of CO2 (PCO2) decreased by 28% to 27.6 +/- 2.2 Torr. Fetal arterial PO2 decreased 11% to a minimum of 23.2 +/- 1.6 Torr, O2 content by 26% to 4.3 +/- 0.6 ml X dl -1, PCO2 by 8% to 49.6 +/- 3.2 Torr, but pH did not change significantly. Recovery was virtually complete within 20 min. During exercise total uterine O2 consumption was maintained despite the reduction in uterine blood flow because of hemoconcentration and increased O2 extraction. The decrease of 3 Torr in fetal arterial PO2 and 1.5 ml X dl -1 in O2 content did not result in major cardiovascular changes or catecholamine release. These findings suggest that maternal exercise does not represent a major stressful or hypoxic event to the fetus.     

Effects of naloxone on the breathing, electrocortical, heart rate, glucose and cortisol responses to hypoxia in the sheep fetus

Continuous infusions of naloxone HC1 (0.5 mg/kg or 3.8 mg/kg) or saline were given intravenously to fetal sheep at 119 to 137 days of gestation during a one hour period of air administration and a one hour period of hypoxia induced by having ewes breathe 9% O2, 3% CO2 and 88% N2. Fetal carotid PaO2 fell to 13.0 +/- 0.5 mmHg during hypoxia with no change in pH. During hypoxia, plasma cortisol concentration increased significantly more in naloxone-infused fetuses than controls. Ewes, whose fetuses received naloxone, showed a significant increase in cortisol during hypoxia whereas no increase was observed in controls. There were no significant differences between saline and naloxone-infused fetuses during hypoxia in fetal breathing incidence, amplitude, frequency, number of deep inspiratory efforts per hour, heart rate, electrocortical activity or in the rise in plasma glucose caused by hypoxia. Results suggest that endogenous opiates may have a role in modulating cortisol production in the ewe and fetus during hypoxia but do not have a role in mediating the decrease in incidence of breathing activity or rise in plasma glucose. During air administration, naloxone significantly increased fetal breath amplitude, fetal and maternal plasma glucose, fetal heart rate, and the number of electrocortical changes per hour. This suggests endogenous opiates may have a more important role in the normoxic pregnant ewe and fetus.