Effects of Estrogen Coadministration on Epoxiconazole Toxicity in Rats

Epoxiconazole (EPX; CAS‐No. 133855‐98‐8) is a triazole class–active substance of plant protection products. At a dose level of 50 mg/kg bw/day, it causes a significantly increased incidence of late fetal mortality when administered to pregnant rats throughout gestation (gestation day [GD] 7–18 or 21), as reported previously (Taxvig et al., 2007, 2008) and confirmed in these studies. Late fetal resorptions occurred in the presence of significant maternal toxicity such as clear reduction of corrected body weight gain, signs of anemia, and, critically, a marked reduction of maternal estradiol plasma levels. Furthermore, estradiol supplementation at dose levels of 0.5 or 1.0 μg/animal/day of estradiol cyclopentylpropionate abolished the EPX‐mediated late fetal resorptions. No increased incidences of external malformations were found in rats cotreated with 50 mg/kg bw/day EPX and estradiol cyclopentylpropionate, indicating that the occurrence of malformations was not masked by fetal mortality under the study conditions. Overall, the study data indicate that fetal mortality observed in rat studies with EPX is not the result of direct fetal toxicity but occurs indirectly via depletion of maternal estradiol levels. The clarification of the human relevance of the estrogen‐related mechanism behind EPX‐mediated late fetal resorptions in rats warrants further studies. In particular, this should involve investigation of the placenta (Rey Moreno et al., 2013), since it is the materno‐fetal interface and crucial for fetal maintenance. The human relevance is best addressed in a species which is closer to humans with reference to placentation and hormonal regulation of pregnancy, such as the guinea pig (Schneider et al., 2013). Birth Defects Res (Part B) 98:247–259, 2013. © 2013 Wiley Periodicals, Inc.     

An Evaluation of Reproductive and Developmental Toxicity of Sitaxentan (Thelin) in Rats

Sitaxentan sodium (Thelin) is a once daily, orally bioavailable, highly selective endothelin A receptor antagonist. Initially approved for the treatment of pulmonary arterial hypertension, sitaxentan was withdrawn in 2010 following the recognition of a pattern of idiosyncratic liver injury. During development of this drug, a series of nonclinical studies investigated the effects of orally administered sitaxentan on fertility, embryofetal development, and pre‐ and postnatal development in the rat; results of these studies are reported here. In the fertility study, sitaxentan did not affect mating behavior, fertility, sperm morphology, or estrous cycle. Sitaxentan was teratogenic in the embyrofetal development study, which was expected based on its pharmacologic mechanism of action. Teratogenic effects included malformations of the head, mouth, face, and large blood vessels. In the pre‐ and postnatal study, sitaxentan administration was associated with reduced pup survival, large or abnormally shaped livers, and delays in markers of auditory and sexual development. Sitaxentan was detected in plasma of suckling pups receiving milk from females dosed with sitaxentan. These nonclinical study findings were reflected in the sitaxentan product label warnings. Birth Defects Res (Part B) 00:1‐10, 2012. © 2012 Wiley Periodicals, Inc.     

Commentary on the Role of Maternal Toxicity on Developmental Toxicity

Maternal mammalian toxicity impacts prenatal development, with general systemic maternal toxicity, from reduced weight gain to morbidity, causative for reduced fetal weights/litter and increased fetal variations (especially skeletal)/litter, but not, in the author's opinion, for increased fetal malformations, reduced litter sizes or full litter losses. Increased fetal malformations are likely due to exposure to specific chemicals which alter specific maternal functions at critical point(s) in pregnancy, typically exaggerated effects from higher doses by drugs under development with known, desired pharmacological effects. Malformations can also be from genetic/epigenetic alterations, specific altered proteins, molecular pathways, etc. Full litter losses are triggered by the mother and are rare in rats. Information to inform maternal (and developmental) toxicity includes ovarian corpora lutea counts, uterine implantation profile, degree of litter reduction (if present), timing and extent of maternal toxicity relative to those of adverse embryofetal effects, etc. The view of maternal toxicity as confounding results in in vivo developmental toxicity studies, worldwide concerns about increased research animal usage, increasing time, labor, costs, and new software and hardware sophistication all drive the interest in development, validation, and performance of in vitro/in silico assays. These assays are fast, inexpensive, responsive to animal use concerns and amenable to mechanistic questions. The strength of these in vitro/in silico assays is considered by many to be the absence of the maternal organism/placenta. These assays inform mechanism and hazard, but NOT risk. The Environmental Protection Agency currently estimates that these new assays are approximately 70% accurate versus the whole animal tests.     

Postnatal development of rat pups after maternal exposure to diethanolamine

BACKGROUND: Diethanolamine (DEA), a widely used surfactant, was administered to pregnant mice at the oral LD10 resulting in failure of pups to grow and thrive through postnatal day (PND) 3 [National Toxicology Program, 1987; York et al., Teratology 37:503-504, 1988]. The toxicity profile for DEA differs among rodent species. This study investigated DEA-induced postnatal toxicity in a second species. METHODS: Timed-mated Sprague-Dawley rats were dosed (0, 50, 125, 200, 250, or 300 mg DEA/kg/day, p.o.) on gestational days (GD) 6-19. Dams and pups were monitored for body weight, feed/water intake, clinical signs, litter size, and sex ratio. At necropsy (PND 21), maternal liver and kidney weights and number of uterine implantation sites were recorded. RESULTS: The high-dose group was terminated early due to excessive toxicity. The estimated maternal LD10 was 218 mg/kg/day. Maternal effects included decreased body weight and relative feed intake (>or=200 mg/kg/day), transiently reduced relative water intake (125 and 250 mg/kg/day), and increased absolute kidney weight (>or=125 mg/kg/day). Postimplantation loss (PND 0) and pup mortality (PND 0-4) were increased (>or=200 and >or=125 mg/kg/day, respectively). Pup body weight was reduced (>or=200 mg/kg/day) as late as PND 21. CONCLUSIONS: This study demonstrates reduced postnatal growth and survival in a second species after gestational exposure to DEA, persistence of toxic effects through the end of lactation, possibly due to long elimination half-life, and maternal and developmental toxicity no-observed-adverse-effect level (NOAELs) (50 mg/kg/day) and lowest-observed-adverse-effect level (LOAELs) (125 mg/kg/day) for oral DEA exposure during embryo/fetal development in the rat.     

Lack of adverse effects in pregnant/lactating female rats and their offspring following pre- and postnatal exposure to ELF magnetic fields

We have recently reported that exposure of pregnant rats to 60 Hz at field strengths up to 0.5 mT during the entire period of pregnancy did not induce any biologically significant effects on both pregnant dams and embryo-fetal development. The present study was carried out to investigate the potential effects of gestational and lactational MF exposure on pregnancy, delivery, and lactation of dams and growth, behavior, and mating performance of their offspring in rats. Timed-pregnant female Sprague-Dawley (SD) rats (24/group) received continuous exposure to 60 Hz magnetic field (MF) at field strengths of 0 (sham control), 5 microT, 83.3 microT, or 0.5 mT. Dams received MF or sham exposures for 21 h/day from gestational day 6 through lactational day 21. Experimentally generated MF was monitored continuously throughout the study. No exposure-related changes in clinical signs, body weight, food consumption, pregnancy length, and necropsy findings were observed in dams. Parameters of growth, behavior, and reproductive performance of offspring showed no changes related to MF exposure. There were no adverse effects on embryo-fetal development of F2 offspring from dams exposed to MF. In conclusion, exposure of pregnant SD rats to 60 Hz at field strengths up to 0.5 mT from gestational day 6 to lactational day 21 did not produce biologically significant effects in dams, F1 offspring, or F2 fetuses.     

Developmental Toxicity Studies with Pregabalin in Rats: Significance of Alterations in Skull Bone Morphology

Pregabalin was administered to pregnant Wistar rats during organogenesis to evaluate potential developmental toxicity. In an embryo‐fetal development study, compared with controls, fetuses from pregabalin‐treated rats exhibited increased incidence of jugal fused to maxilla (pregabalin 1250 and 2500 mg/kg) and fusion of the nasal sutures (pregabalin 2500 mg/kg). The alterations in skull development occurred in the presence of maternal toxicity (reduced body weight gain) and developmental toxicity (reduced fetal body weight and increased skeletal variations), and were initially classified as malformations. Subsequent investigative studies in pregnant rats treated with pregabalin during organogenesis confirmed the advanced jugal fused to maxilla, and fusion of the nasal sutures at cesarean section (gestation day/postmating day [PMD] 21) in pregabalin‐treated groups. In a study designed to evaluate progression of skull development, advanced jugal fused to maxilla and fusion of the nasal sutures was observed on PMD 20–25 and PMD 21–23, respectively (birth occurs approximately on PMD 22). On postnatal day (PND) 21, complete jugal fused to maxilla was observed in the majority of control and 2500 mg/kg offspring. No treatment‐related differences in the incidence of skull bone fusions occurred on PND 21, indicating no permanent adverse outcome. Based on the results of the investigative studies, and a review of historical data and scientific literature, the advanced skull bone fusions were reclassified as anatomic variations. Pregabalin was not teratogenic in rats under the conditions of these studies     

Embryo‐Fetal Developmental Toxicity Studies with Pregabalin in Mice and Rabbits

Pregabalin was evaluated for potential developmental toxicity in mice and rabbits. Pregabalin was administered once daily by oral gavage to female albino mice (500, 1250, or 2500 mg/kg) and New Zealand White rabbits (250, 500, or 1250 mg/kg) during organogenesis (gestation day 6 through 15 [mice] or 6 through 20 [rabbits]). Fetuses were evaluated for viability, growth, and morphological development. Pregabalin administration to mice did not induce maternal or developmental toxicity at doses up to 2500 mg/kg, which was associated with a maternal plasma exposure (AUC_0–24) of 3790 μg?hr/ml, ≥30 times the expected human exposure at the maximum recommended daily dose (MRD; 600 mg/day). In rabbits, treatment‐related clinical signs occurred at all doses (AUC_0–24 of 1397, 2023, and 4803 μg?hr/ml at 250, 500, and 1250 mg/kg, respectively). Maternal toxicity was evident at all doses and included ataxia, hypoactivity, and cool to touch. In addition, abortion and females euthanized moribund with total resorption occurred at 1250 mg/kg. There were no treatment‐related malformations at any dose. At 1250 mg/kg, compared with study and historical controls, the percentage of fetuses with retarded ossification was significantly increased and the mean number of ossification sites was decreased, which correlated with decreased fetal and placental weights, consistent with in utero growth retardation. Therefore, the no‐effect dose for developmental toxicity in rabbits was 500 mg/kg, which produced systemic exposure approximately 16‐times human exposure at the MRD. These findings indicate that pregabalin, at the highest dose tested, was not teratogenic in mice or rabbits     

Preclinical Reproductive and Developmental Toxicity Profile of a Glycine Transporter Type 1 (Glyt1) Inhibitor

Bitopertin is a glycine type 1 (GlyT1) inhibitor intended for the treatment of psychiatric disorders. The principle adverse effect in the regulatory reproductive toxicity studies was peri‐natal pup death when rat dams were treated during parturition at a dose resulting in five‐times the human therapeutic exposure (AUC). Cessation of dosing two days before parturition prevented the pup deaths. Investigatory experiments and pharmacokinetic modelling suggested that the neonatal mortality was related to transplacental passage of bitopertin leading to high systemic levels in the newborn pups. Brain levels of bitopertin in the rat fetus and neonate were two‐fold higher than in the mother. As illustrated by knock‐out mice models, GlyT1 function is essential for neonatal pup survival in rodents, but is not necessary for normal prenatal morphological development. The glycine transport systems are immature at birth in the rat, but are functionally well‐developed in the human newborn. While the relevance to humans of the neonatal mortality seen in rats following late gestational exposure is unknown, bitopertin would not be recommended for use during late pregnancy unless the anticipated benefit for the mother outweighs the potential risk to the newborn.     

Developmental Toxicity Studies with Atrazine and its Major Metabolites in Rats and Rabbits

Atrazine (ATR), hydroxyatrazine (OH‐ATR), and the three chloro metabolites of ATR (deethylatrazine [DEA], deisopropylatrazine [DIA], diaminochlorotriazine [DACT]) were evaluated for developmental effects in rats and rabbits. Three developmental toxicity studies were conducted on ATR in rats (two studies) and rabbits and a developmental toxicity study was conducted in rats for each of the four ATR metabolites DEA, DIA, DACT, and OH‐ATZ. ATR administration by gavage to pregnant rats and rabbits from implantation (gestation day [GD] 6 in rat, GD 7 in rabbit) through closure of the palate (GD 15 in rat and GD 19 in rabbit) did not statistically significantly alter the incidence of developmental abnormalities or malformations at dose levels up to 100 (rat) or 75 (rabbit) mg/kg bw/day. There were no effects on developmental toxicity parameters for DEA, DIA, DACT, or OH‐ATR at oral dose levels up to 100, 100, 150, or 125 mg/kg bw/day, respectively, with the exception of reductions in fetal body weight by DACT and OH‐ATR in the presence of decreased maternal body weight gain. ATR did not adversely affect developmental end points in a two‐generation study conducted in rats exposed to dose levels up to 500 ppm (38.7 mg/kg/day) in the diet. The 500‐ppm dose level resulted in significantly reduced maternal body weight gain. Overall, data show that neither ATR nor its metabolites statistically significantly affected rat or rabbit embryo‐fetal development even at dose levels producing maternal toxicity.     

Numeric Estimates of Teratogenic Severity from Embryo–Fetal Developmental Toxicity Studies

A developing organism exposed to a toxicant will have a response that ranges from none to severe (i.e., death or malformation). The response at a given dosage may be termed teratogenic (or developmental toxic) severity and is dependent on exposure conditions. Prenatal/embryo–fetal developmental (EFD) toxicity studies in rodents and rabbits are the most consistent and definitive assessments of teratogenic severity, and teratogenesis screening assays are best validated against their results. A formula is presented that estimates teratogenic severity for each group, including control, within an EFD study. The developmental components include embryonic/fetal death, malformations, variations, and mean fetal weight. The contribution of maternal toxicity is included with multiplication factors to adjust for the extent of mortality, maternal body weight change, and other parameters deemed important. The derivation of the formula to calculate teratogenic severity is described. Various EFD data sets from the literature are presented to highlight considerations to the calculation of the various components of the formula. Each score is compared to the concurrent control group to obtain a relative teratogenic severity. The limited studies presented suggest relative scores of two‐ to <fivefold higher than control have detectable but a low level of teratogenic severity, and scores ≥fivefold higher than control have increasingly more severe teratogenicity. Such scores may help refine the concept of an exposure‐based validation list for use by proponents of screening assays (Daston et al., 2014) by estimating the severity of “positive” exposures, or in other situations by defining the severity of a LOAEL (lowest observed adverse effect level)     

Developmental toxicity assessment of d,l-methylphenidate and d-methylphenidate in rats and rabbits

BACKGROUND: Previous investigations reported no teratogenicity for methylphenidate (MPH). These studies investigated potential teratogenicity of d‐MPH and d,l‐MPH as commitments to the FDA. METHODS: Rabbits received 15, 50, 150 mg/kg/day (mkd) d‐MPH or 20, 60, 200, 300 mkd d,l‐MPH on gestation days 7–20. Rats received 2.5, 10, 40 mkd d‐MPH, or 7, 25, 75, 80 mkd d,l‐MPH on gestation days 6–17. RESULTS: d‐MPH—In rabbits, mortality occurred at 150 mkd. Dilated pupils, increased activity, biting/chewing, respiration, and salivation occurred at ≥15 mkd in rabbits and ≥10 mkd in rats. Decreased food consumption occurred at 40 mkd in rats. Decreased body weight parameters occurred at 150 mkd in rabbits and ≥10 mkd in rats. There were no fetal findings in rabbits. In rats, skeletal variations occurred at 40 mkd. d,l‐MPH—In rabbits, mortality occurred at ≥200 mkd. Dilated pupils, increased activity, biting/chewing, respiration, and salivation occurred at ≥20 mkd in rabbits and ≥25 mkd in rats. Decreased food consumption occurred at ≥200 mkd in rabbits and ≥25 mkd in rats. Decreased body weight parameters occurred at ≥200 mkd in rabbits and ≥25 mkd in rats. In rabbits, two fetuses (separate litters) had spina bifida and malrotated hindlimbs at 200 mkd. In rats, skeletal variations occurred at ≥75 mkd. CONCLUSIONS: There was no teratogenicity with d‐MPH. There was a low teratogenic risk with d,l‐MPH in only the rabbit. Higher C_max may explain differences in results from previous studies. Birth Defects Res (Part B) 83:489‐501, 2008. © 2008 Wiley‐Liss, Inc.     

Toxicity of bryostatin‐1 on the embryo‐fetal development of Sprague‐Dawley rats

BACKGROUND: Bryostatin‐1, a highly oxygenated marine macrolide with a unique polyacetate backbone isolated from the marine animal Bugula neritina (Linnaeus), is now being developed as an anti‐cancer drug for treating malignancy. In the present study, developmental toxicity of bryostatin‐1 was evaluated in Sprague–Dawley rats. METHODS: Bryostatin‐1 was intravenously administered to rats on gestation days 6–15 at 4.0, 8.0, and 16.0 µg/kg on a daily basis. Then the reproductive parameters were determined in animals, and fetuses were examined for external, visceral, and skeletal malformations. RESULTS: The total weight gains were significantly different in animals between the control group and 8.0 and 16.0 µg/kg bryostatin‐1 groups during and after treatment. The resorption and death fetus rates were significantly different between the bryostatin‐1 group (16 µg/kg) and the control group. The fetal weight and fetal crown‐rump length in the bryostatin‐1 groups were significantly lower than that in the control group. CONCLUSIONS: Our results indicated that maternal toxicity occurred when the dose of bryostatin‐1 was at 8.0 µg/kg, embryotoxicity at 16.0 µg/kg, and fetotoxicity at 4.0 µg/kg; but bryostatin‐1 showed no teratogenic effect in rats. In light of our findings, bryostatin‐1 should be used with caution in pregnant women with cancer, if they would like to continue the pregnancy. Birth Defects Res (Part B) 89:171–174, 2010. © 2010 Wiley‐Liss, Inc.     

Developmental immunotoxicity investigations in the SD rat following pre- and post-natal exposure to cyclosporin

BACKGROUND: The development and function of the immune system was assessed in juvenile SD rats following pre- or post-natal exposure to cyclosporin. The main objective was to assess the feasibility of the methods available for the detection of adverse effects on the development of the immune system for use in the safety assessment of medicines. METHODS: In a pre-natal experiment, 15 pregnant rats were given 10 mg/kg/day of cyclosporin by gavage from day 6 of gestation until 4 days after parturition. A control group received olive oil. In a post-natal experiment, the pups from 35 litters were given 10 mg/kg/day of cyclosporin by gavage from 4 to 28 days of age. Half of the pups in each litter were given water and acted as controls. Immune endpoints were determined in the pups in both experiments from two to 10 weeks of age, including: lymphocyte subsets, serum immunoglobulin titres, serum autoantibodies, primary antibody response to sheep red blood cells (SRBC), delayed-type hypersensitivity response, humoral response to keyhole limpet haemocyanin, spleen cellularity, immune organ weights, and histopathology. RESULTS: Pre-natal exposure caused no effects on immune function. Post-natal exposure caused immune depression during the treatment period and a persistent impairment of the immune system characterised by lymphoid hyperplasia in the spleen and a reduced primary antibody response to SRBC at 10 weeks of age. CONCLUSIONS: These results demonstrate the importance of a post-treatment follow-up period in developmental immunotoxicity studies, in order to distinguish between the transient effects of immune modulation and the persistent consequences of developmental toxicity.     

Juvenile toxicity assessment of open-acid lovastatin in rats

BACKGROUND: Lovastatin, an inhibitor of 3‐hydroxy‐3‐methylglutaryl‐coenzyme A reductase, reduces de novo cholesterol biosynthesis primarily in the liver. Since cholesterol is a major component of brain myelin and peak periods of brain myelination occurs after birth, this study was designed to encompass this period in rats and evaluate the potential neurotoxic effects. METHODS: The pharmacologically active, open‐acid form of lovastatin was administered to groups of 50 Sprague–Dawley rats per sex subcutaneously once daily at dose levels of 0 (vehicle), 2.5, 5, or 10 mg/kg/day beginning on postnatal day 4 and continuing until termination on postnatal day 41 to 51. Physical signs and body weights were monitored during the study. Animals were assessed in a battery of behavioral tests, and at termination a set of animals were examined for gross and histological changes. RESULTS: There were no test article‐related deaths, physical signs, or effects on preweaning and postweaning body weights during the study. In the behavior tests there were no test article‐related effects in the passive avoidance, auditory startle habituation, open‐field motor activity, or FOB. No test article‐related postmortem findings were observed, including brain weights and histomorphology of brain, spinal cord, eye, optic nerve, or peripheral nerve. CONCLUSION: Based on these results, the no‐effect level for general and neurobehavioral toxicity in neonatal rats was ≥10 mg/kg/day for open‐acid lovastatin. Birth Defects Res (Part B) 92:314–322, 2011. © 2011 Wiley‐Liss, Inc.     

Species differences in the renal toxicity of the antiarthritic drug,gold sodium thiomalate

Two gold compounds, gold sodium thiomalate (AuTM) and auranofin, are presently in clinical use in therapy of rheumatoid arthritis. In these studies, AuTM administered to Sprague-Dawley rats and three strains of mice, Swiss-Webster, C3H/HeJ, and DBA/2J, were studied with regard to its effect on liver and renal monooxygenases, metallothionein contents, and serum levels of alanine aminotransferase and urea nitrogen. These effects of AuTM were compared to those of cadmium, since the latter metal has exhibited tissue and species differences in the induction of metallothionein. Benzo(a)pyrene hydroxylase and benzphetamine N-demethylase activities were not altered by AuTM in livers of rats and the three strains of mice. Benzo(a)pyrene hydroxylase activity was significantly decreased in rat kidney, whereas this enzyme activity was not affected in the kidneys of mice. In rats, AuTM caused a sevenfold induction in liver metallothionein, while in mice, liver metallothionein was induced twofold in Swiss-Webster mice and about fivefold in the inbred strains. AuTM caused minimal changes in renal metallothionein contents in the three strains of mice studied. Serum alanine amino-transferase, an indicator of hepatotoxicity, was not altered by AuTM in rats and mice studied. Blood urea nitrogen, an indicator of kidney dysfunction, was increased threefold in rats, but not in AuTM-treated mice. These data demonstrate that AuTM, a nephrotoxic agent in rats and humans, showed no nephrotoxic effects in the mouse strains studied here. © 1997 John Wiley & Sons, Inc.