Effects of multiple-dose maternal ethanol infusion on fetal cardiovascular and brain activity in lambs

Ethanol's disruptive effects upon early breathing plasticity and blood parameters associated with hypoxia and hypercapnia

Early ethanol exposure affects respiratory neuroplasticity; a risk factor associated with the Sudden Infant Death Syndrome. High and chronic ethanol doses exert long-lasting effects upon respiratory rates, apneic episodes and ventilatory processes triggered by hypoxia. The present study was performed in 3-9-day-old rat pups. Respiratory processes under normoxic and hypoxic conditions were analyzed in pups intoxicated with different ethanol doses which were pre-exposed or not to the drug. A second major goal was to examine if acute and/or chronic early ethanol exposure affects blood parameters related with hypercapnic or hypoxic states. In Experiment 1, at postnatal day 9, animals previously treated with ethanol (2.0 g/kg) or vehicle (0.0 g/kg) were tested sober or intoxicated with 0.75, 1.37 or 2.00 g/kg ethanol. The test involved sequential air conditions defined as initial normoxia, hypoxia and recovery normoxia. Motor activity was also evaluated. In Experiment 2, blood parameters indicative of possible hypoxic and hypercapnic states were assessed as a function of early chronic or acute experiences with the drug. The main results of Experiment 1 were as follows: i) ethanol's depressant effects upon respiratory rates increased as a function of sequential treatment with the drug (sensitization); ii) ethanol inhibited apneic episodes even when employing the lowest dose at test (0.75 g/kg); iii) the hyperventilatory response caused by hypoxia negatively correlated with the ethanol dose administered at test; iv) ventilatory long-term facilitation (LTF) during recovery normoxia was observed in pups pre-exposed to the drug and in pups that received the different ethanol doses at test; v) self-grooming increased in pups treated with either 1.37 or 2.00 g/kg ethanol. The main result of Experiment 2 indicated that acute as well as chronic ethanol exposure results in acidosis-hypercapnia. The results indicate that early and brief experiences with ethanol are sufficient to affect different respiratory plasticity processes as well as blood biomarkers indicative of acidosis-hypercapnia. An association between the LTF process and the acidosis-hypercapnic state caused by ethanol seems to exist. The mentioned experiences with the drug are sufficient to result in an anomalous programming of respiratory patterns and metabolic conditions.

Ethanol increases uterine blood flow and fetal arterial blood oxygen tension in the near-term pregnant ewe

Fetal hypoxia is a hypothesized mechanism of ethanol teratogenesis. The objective of this study was to test this hypothesis by determining the effects of maternal ethanol infusion on uterine blood flow (UBF) and fetal oxygen status. UBF was measured with an electromagnetic flow probe placed around the left maternal uterine artery of the surgically recovered instrumented near-term pregnant sheep at 124 +/- 3 days of gestation (term = 147 days). Experimental treatment involved maternal infusion of 2 g (n = 3) or 4 g (n = 5) ethanol/kg maternal body weight, or 0.9% saline (n = 4) over a 5-h period. Arterial blood samples were collected at regular intervals to monitor maternal ethanol concentration and fetal PO2. Maternal ethanol infusion produced a dose-dependent increase (p = 0.0009) in UBF. Ethanol infusion also increased (p = 0.03) fetal arterial PO2. Overall, these findings indicate that fetal hypoxia is not a mechanism of ethanol teratogenesis.

Effect of cocaine on electrocortical activity in fetal sheep

The effect of cocaine on the behavioral state of six fetal sheep was studied during gestational ages between 128-135 days. Two to eight days after surgery, fetuses received either a continuous 60 min intravenous infusion of cocaine HCl (33.4 mg) or saline. The infusions were preceded and followed by control periods of 102 min. Cocaine induced a disruption in fetal behavioral state cyclicity and a decrease in the amount of time spent in rapid eye movement sleep (P < 0.01) and non-rapid eye movement sleep (P < 0.05) during the infusion, but not during the recovery period. Spectral amplitude of the electrocortical activity at all three cortical locations increased within most one-third octave bands between 0.8-4 Hz and decreased within most bands between 16-25 Hz (P < 0.05) compared to controls. There were no differences in spectral amplitude between pre- and post-cocaine periods at any location over the 25 frequency bands studied (P > 0.6) except for one frequency band centered at 12.5 Hz. The effects of a one hour cocaine infusion on fetal cortical electrical activity are diffuse, but short-lived, and occur independently of changes in fetal oxygenation.

Fetal guinea pig brain 15-hydroxyprostaglandin dehydrogenase: ontogeny and effect of ethanol

The objectives of this study were to determine the ontogeny of 15-hydroxyprostaglandin dehydrogenase (15-OH-PGDH) activity in the brain of the fetal guinea pig and to test the hypothesis that acute in vitro ethanol exposure produces concentration-dependent inhibition of fetal brain 15-OH-PGDH activity. Enzyme activity was determined in vitro by measuring the rate of oxidation of PGE2 to 15-keto-PGE2 using an optimized radiometric procedure. The study was conducted utilizing the whole brain of the fetal guinea pig at mean gestational ages of 34, 43 and 62 days (term, about 66 days) and the brain stem (pons and medulla) of the fetal guinea pig at mean gestational ages of 43 and 62 days. The direct effect of acute in vitro exposure to ethanol was assessed by incubating 15-OH-PGDH with ethanol in the concentration range of 10 to 80 mM. 15-OH-PGDH was measurable in the whole brain and brain stem, and the enzyme activity was similar for the gestational ages examined. There was no significant ethanol-induced inhibition of 15-OH-PGDH activity in the whole brain or brain stem. The data demonstrate that the whole brain and brain stem of the fetal guinea pig have the capacity to metabolize PGE2 to 15-keto-PGE2, an inactive metabolite, during the second half of gestation. The data apparently are not consistent with the hypothesis that acute in vitro exposure to ethanol directly inhibits 15-OH-PGDH activity in fetal brain.