Developmental neurotoxicity evaluation of acrylamide in Sprague-Dawley rats.

Based on the literature to-date, the potential of acrylamide (ACRL) to cause developmental neurotoxicity in laboratory animals has not been assessed. We examined this potential in Sprague-Dawley rats using a study design similar to that proposed by the USEPA. Dosages of 0 (deionized water), 5, 10, 15, or 20 mg/kg/day were administered at 5 ml/kg by oral gavage from gestational day 6 to lactational day 10 to groups of 12 mated females each. Females were allowed to deliver and the offspring were evaluated for survival, growth, development, behavior, and histological changes to brain, spinal cord, and peripheral nerve. Behavioral assessments consisted of open-field motor activity, auditory startle habituation, and passive avoidance tests during both the preweaning and adult periods (1 animal/sex/litter). All F0 and F1 animals in the 20 mg/kg/day group were euthanized early in the lactation period due to high pup mortality. Significantly increased pup mortality was also present in the 15 mg/kg/day group. There were dose-related decreases in average F0 maternal body weight gains during the dosing period in the 10, 15, and 20 mg/kg/day groups, and characteristic hindlimb splaying was observed in dams of the two highest dosage groups. Pup body weight proved to be the most sensitive indicator of developmental toxicity. Dose-related decrease in preweaning average weights were observed at all dose levels, although only transiently in the 5 mg/kg/day group. Average weight gain during the postweaning period was significantly decreased only in males of the 15 mg/kg/day group. Significant decreases in average horizontal motor activity and auditory startle response were observed only in weanlings of the 15 mg/kg/day group. The only behavioral effect in F1 adult animals was a decrease in auditory startle response in females of the 15 mg/kg/day group. There were no effects in the passive avoidance test or in the histological examination of the nervous system of preweaning pup or adult animals. Based on these results, the NOAEL (No Observed Adverse Effect Level) for developmental toxicity is less than 5 mg/kg/day, the NOAEL for maternal toxicity is 5 mg/kg/day, and that for developmental neurotoxicity is 10 mg/kg/day. Thus behavioral changes in the offspring were observed only at a dose which was also maternally toxic. These results suggest that acrylamide may be a selective developmental toxicant but not a selective developmental neurotoxicant, because a conventional measure of offspring toxicity (i.e., pup body weight) was affected at a dosage lower than that which produced maternal effects or offspring behavioral effects.

Selection of food allotment for New Zealand white rabbits in developmental toxicity studies.

In three initial studies, female rabbits were fed 125, 150, or 230 g of Purina Certified Rabbit Chow No. 5322 ("regular" chow) per day or 150 g/day of Purina Certified High Fiber Rabbit Chow ("high fiber" chow) for at least 5 weeks prior to artificial insemination and until Day 28 of gestation when fetuses were removed and examined. Animals allotted 230 g/day of regular chow ate approximately 180 g/day and gained more weight than the 150 g/day group until Day 14 of gestation after which food consumption declined and body weight decreased. Animals fed 150 g/day regular chow ate all food provided until after Day 22 of gestation when food consumption decreased dramatically in some animals. Animals in the 125 g/day regular chow and 150 g/day high fiber chow groups ate essentially all food provided throughout gestation. Ad lib feeding in the 230 g/day groups was associated with adverse reproductive consequences consisting of decreased numbers of implants and live fetuses and decreased fetal weight. In one study involving 3 groups fed 125 and 150 g/day regular chow and 150 g/day high fiber chow, reproductive parameters were similar in all 3 groups. However, fetal weight in the 150 g/day regular chow group was 50% more variable than the other groups in association with more variable maternal body weight change late in gestation in that group. In subsequent studies using 125 g/day, there has consistently been fewer animals going off feed late in gestation and a decrease in fetal weight variance of approximately 60% compared to previously when the standard daily allotment was 150 g/day.(ABSTRACT TRUNCATED AT 250 WORDS)

Toxicity of the HMG-coenzyme A reductase inhibitor, lovastatin, to rabbits.

Lovastatin, a specific inhibitor of the rate-limiting enzyme in cholesterol biosynthesis, HMG-CoA reductase, has been shown to be highly effective in lowering serum cholesterol in animals and humans and thus represents a promising approach to the treatment and prevention of cardiovascular disease. During the preclinical safety assessment of lovastatin, oral doses that were tolerated by dogs, rats and mice were found to be lethal to rabbits in subacute studies. Postmortem findings in rabbits consisted of centrilobular hepatic necrosis, frequently accompanied by renal tubular necrosis and occasionally gallbladder necrosis. The liver lesions were associated with up to 300-fold elevations in serum aspartate and alanine aminotransferase activities, whereas the kidney lesions resulted in accumulations of serum urea nitrogen and creatinine. The organ damage was preceded by a progressive decline in food consumption and loss of body weight. All histopathological and serum biochemical changes induced by lovastatin were completely prevented by coadministration of mevalonate, the product of the inhibited HMG-CoA reductase enzyme. In addition, administration of mevalonate after the onset of lovastatin-induced hepatotoxicity effectively reversed the toxicity despite continued drug treatment. These findings indicated that the toxicity of high doses of lovastatin to rabbits is a consequence of a highly exaggerated pharmacologic action in blocking mevalonate synthesis. However, supplementation of lovastatin-treated rabbits with oral doses of the major product of mevalonate metabolism, cholesterol, paradoxically enhanced the liver and kidney damage, which suggested that the toxicity of lovastatin stemmed from depletion of a nonsterol metabolite(s) of mevalonate critical for cell viability.