Effects of thyroid antagonists on rat embryos cultured in vitro

A literature review of individual pregnancies and recent surveys involving large cohorts reveal an association between congenital malformation and maternal hyperthyroidism, suggesting that some aspect of hyperthyroidism or its treatment might compromise the development of the fetus. Experiments have shown that the thyroid antagonist, ethylenethiourea (ETU), causes fetal malformations when administered to pregnant rats, but it is not known whether it is ETU or the imbalance in maternal thyroid hormone which it causes which is the teratogenic agent. Here we employ in vitro culture to determine the possible direct effects on rat embryos of two thyroid antagonists, ETU and methimazole (MMI), the latter being one which is used for treatment of thyrotoxicosis in humans. It was found that ETU can compromise the development of rat embryos in vitro, confirming that ETU has a direct effect on the rat embryo. It was also found that MMI can cause abnormal development of rat embryos in vitro, although the concentration at which MMI disturbs rat embryogenesis is higher than that which is reached in hyperthyroid patients treated with clinical doses of MMI or carbimazole.     

Amelioration of the teratogenicity of cadmium by the metallothionein induced by bismuth nitrate

The participation of maternal hepatic metallothionein (MT) in the amelioration of cadmium teratogenicity in mice was examined. Pretreatment with bismuth nitrate (subcutaneously) ameliorated the teratogenicity, including exencephaly and abnormalities of the axial skeleton, caused by a single intraperitoneal injection of cadmium sulfate. Pretreatment with bismuth nitrate for 3 days induced MT drastically in maternal liver and kidney. Six and 24 hr after the injection of cadmium sulfate, the accumulation of maternal hepatic cadmium increased and that in the decidua, including embryos, decreased after pretreatment with bismuth nitrate. Mouse embryos on day 7 of gestation were cultured for 48 hr. Exposure to cadmium sulfate in vitro induced unfused brain fold, which corresponds to exencephaly in vivo. From the in vitro experiment, it was suggested that the teratogenicity of cadmium on day 7 of gestation is a direct action against the mouse embryo. In the present experiment it was suggested that pretreatment with bismuth nitrate induced maternal hepatic and renal MT; cadmium was therefore trapped and detoxicated, and consequently embryos were exposed to a lower concentration of cadmium.     

Comparative distribution and embryotoxicity of hydroxyurea in pregnant rats and rhesus monkeys.

Hydroxyurea was given to pregnant rhesus monkeys and pregnant rats in regimens adjusted to produce similar degrees of teratogenicity, for the purpose of comparing the distribution of the drug in the females and their embryos. According, in rats 137 mg/kg/day ip on days 9-12 resulted in a drug half-life in maternal plasma of about 15 min and in embryos about 85 min, after the last injection; and in monkeys 100 mg/kg/days iv on days 23-32 resulted in drug half-life in maternal plasma estimated to be 120 min and in embryos 265 min, after the last injection. Using as a baseline of biological effects the minimal concentration known to inhibit DNA synthesis in rat embryos and cancer cells, namely 10(-4) M, it was calculated that the rat embryos in the present study were exposed to this level or more for approximately 12 h whereas the monkey embryos were exposed for approximately 100 h. Although the teratogenic effects were not identical in the two species, these data are interpreted to mean that rat embryos are teratogenically much more sensitive to hydroxyurea than monkey embryos. These observations have important implications in the selection of appropriate species for tests to estimate human teratogenic risks. The rat, which is currently the most widely used animal for such tests, displays sizeable differences from rhesue monkeys, which is one of the animals thought to be most like man in teratogenic susceptibility.     

A comparison of the distribution, metabolism and excretion of ethylenethiourea in the pregnant mouse and rat

Pregnant mice and rats were treated by stomach intubation on day 15 g of gestation with 240 mg/kg of ethylenethiourea (ETU) made up in part with radiolabeled ETU. Animals were sacrificed at specific times post-treatment, and maternal tissues, fetus, urine and feces were collected for determination of radioactivity. Maternal and fetal tissue levels of ETU were similar at three hours post treatment; thereafter, the mouse (maternal and fetus) showed much less ETU than the rat. The t1/2 of ETU elimination from the maternal blood was 9.4 and 5.5 hours for the rat and mouse, respectively. Analysis of urine by thin-layer chromatography and radiochromatography revealed that the mouse and rat metabolized ETU by different pathways. Furthermore, the mouse is able to metabolize ETU to a greater extent than the rat.     

Theoretical and applied aspects of experimental teratology]

The dependence of teratogenic effect from the agent specific properties, dose and exposition and the genotype of embryo and maternal organism is considered. The stage specificity of teratogens and the concepts of critical developmental periods are analyzed. The data on general mechanisms of embryonic defects related to the mutations and their phenocopies induced by teratogens are evaluated. The applied aspects of experimental teratology and, in particular, the testing of drugs' teratogenicity and the development of mathodical bases for the establishment of teratogens among the chemical pollutions are intimately connected with and depend on more profound studies of the theoretical bases of teratology. A new method of testing the chemical substances is proposed: search for embryotoxic and teratogenic factors in the blood of animals which were in contact with teratogens. With this aim the cleaving postimplantation mouse and rat embryos are cultivated in the medium with the blood serum from the animals treated with teratogens. This allows to detect in the blood not only the substance in question, but also the toxic products of its metabolism and the toxic substances formed in the maternal organism under the effect of this teratogen. The approaches to the express methods of estimation of teratogenicity are evaluated and the grounds of many steps testing the chemical polutions for teratogenicity are provided.     

The toxicity of niridazole in rat embryos in vitro

The antischistosomal drug niridazole (NDZ) was found to be teratogenic in a concentration-dependent manner from 10 to 50 micrograms/ml (47-233 microM) in rat embryos cultured from day 10 to day 11. A striking malformation consisting of axial asymmetry in which the right side of the embryo showed severe necrosis was the predominant malformation. The drug showed significantly greater dysmorphogenic activity at low (5%) compared to high (20%) oxygen tensions in cultures. Coincubation of embryos and NDZ with an exogenous source of metabolic enzymes and cofactors (NADPH) failed to modify teratogenicity. Inclusion of CO in the culture atmosphere significantly reduced the malformation incidence as did preincubation of the drug with S-9 and cofactors in medium with low O2 tension. Treatment of gravida with NDZ up to and including the maternal-lethal dose failed to result in observable malformations despite the use of several routes of exposure. These data lead us to hypothesize that rat embryos are capable of performing the reductive activation of NDZ in a fashion analogous to the schistosome but that reductive extraembryonic metabolism may result in teratogenic bioinactivation.     

Structural teratogenicity evaluation of methyl chloride in rats and mice after inhalation exposure

One hundred bred Fischer-344 female rats were exposed daily for 6 hours to atmospheres containing 0, 100, 500, or 1,500 ppm methyl chloride, 25 females per exposure concentration, from gestation day (gd) 7 through gd 19. On gd 20, the females were sacrificed for evaluation of maternal reproductive and fetal parameters. Maternal and fetal toxicity was apparent at the highest exposure concentration. There were no methyl chloride-induced external, skeletal, or visceral abnormalities seen in the fetuses. One hundred thirty-two C57BL/6 female mice bred to C3H males to produce B6C3F1 offspring were exposed daily for 6 hours to atmospheres containing 0, 100, 500, or 1,500 ppm methyl chloride, 33 females per exposure concentration, from gd 6 through gd 17. Exposure to the entire 1,500-ppm group was terminated on gd 10-14, with the animals killed in extremis. Selective necrosis of neurons in the internal granular layer of the cerebellum, ranging from individual cell involvement to focal areas comprising large numbers of neurons, was found in all females. On gd 18, the females from the other treatment groups, all of which survived, were killed for evaluation of maternal reproductive and fetal parameters. No evidence was seen of maternal or fetal toxicity in these exposure groups. There were no significant alterations in external appearance in fetuses from any of the exposure groups. Visceral examination of mouse fetuses revealed a small, but statistically significant, incidence of heart defects in litters of the 500-ppm group. The anomaly, a reduction or absence of the atrioventricular valve, chordae tendineae, and papillary muscle, was observed on the left side (bicuspid valve) in three fetuses and the right side (tricuspid valve) in six fetuses: three males and six females. It is concluded that methyl chloride inhalation exposure in pregnant rats, during critical periods of embryo and fetal development, is not teratogenic at concentrations which elicit maternal and fetal toxicity. In pregnant mice, methyl chloride was severely toxic to dams following 4 days or more of exposure to 1,500 ppm in air. Methyl chloride, at 500, but not 100 ppm, was teratogenic in mice, leading to a malformation in the heart. No embryo-fetal toxicity or teratogenicity was associated with exposure of mice, during critical periods of embryo and fetal development, to 100 ppm of ethyl chloride.     

Ethylenethiourea-induced hydrocephalus in vivo and in vitro with a note on the use of a constant gaseous atmosphere for rat embryo cultures

Embryos were studied either after direct exposure to ethylenethiourea (ETU) during incubation of embryo cultures or after maternal ETU dosing and subsequent embryonic development in utero with a view to assess the similarity of these two systems to produce hydrocephalus. Ten-day-old rat embryos were incubated with nutrient media containing 0-2.0 mM of ETU in a constant gasseous environment following a newly modified method. The cultured embryos showed hydrocephalus in the form of dilated rhombencephalon and other anomalies at the 1.5 and 2.0 mM of ETU after 26 hours of incubation. No anomalies were seen in the control group. In in vivo studies, dilated rhombencephalon or hydrocephalus was not observed when dams, orally dosed with ETU on gestation day 10, were either killed daily for three postdosing days to examine embryos or killed at term to evaluate fetuses. This discrepancy in dilatation that was incidental to the rhombencephalon in the two systems pointed out that the fourth ventricle of the cranial neural tube responded by dilatation in vitro but remained unaffected in vivo following ETU exposure. ETU dosing of dams on the 12th day of pregnancy, when embryos are known to be sensitive to ETU-induced hydrocephalus, followed by serial gross examination of embryos, suggested that edema occurred in a generalized form but only after the appearance of both hydrocephalus (dilatation primarily in mesencephalon) and, the previously reported, neuroblastic necrosis.     

In vitro teratogenicity of ethylenethiourea in the rat

We have demonstrated that ethylenethiourea (ETU) is a potent teratogen to the rat embryo developing in vitro. Sprague Dawley rat embryos were explanted on gestation day 10 and cultured for 48 hours in the presence of 40-200 micrograms/ml ETU. This resulted in a dose-related inhibition of growth and differentiation as assessed by crown-rump length, protein and DNA content, and somite number and in an increase in the frequency of abnormalities. A variety of anomalies was produced, including fluid accumulation in the brain (hydrocephalus), decreased mandibular size, decreased telencephalon size, abnormal dorsiflexion, as well as subectodermal blisters on the tail and limb buds and maxilla. Frank malformations have been observed at these same sites--hydrocephalus, brachygnathia, kyphosis, limb and tail defects, cleft palate--in the term fetus in vivo. The presence of abnormal fluid accumulation in the embryos--distended neural tube and subectodermal blisters--suggesting that the osmotic environment of the embryo had been altered by ETU exposure. Osmolality of the exocoelomic fluid (ECF) surrounding the embryo was measured after 48 hours of exposure to a concentration of ETU that caused nearly a 100% incidence of subectodermal blisters. ECF osmolality was found to be significantly lower than that of control embryos. Lowered osmolality would cause water to move out of the ECF, presumably causing the observed fluid accumulation in the embryo. It is speculated that altered osmotic balance and localized edema in the embryo are contributory steps in the formation of defects after ETU exposure.     

Teratogenic effect of the cholesterol synthesis inhibitor AY 9944 on rat embryos in vitro.

AY 9944 [trans-1,4-bis(2-chlorobenzylaminomethyl) cyclohexane dihydrochloride] is an amphiphilic cationic molecule. This chemical is an established inhibitor of cholesterol synthesis and is teratogenic in rats. The mechanisms of this teratogenicity remain to be clarified. This study used cultured rat whole embryos to ascertain whether AY 9944 had a direct effect on embryos, or whether its action was indirect, via the maternal cholesterol metabolism. Four experimental conditions were investigated: (A) controls; (B) 10 day untreated embryos were cultured in serum of treated rats; (C) 10 day untreated embryos were cultured in serum containing added AY 9944 (0-1,000 micrograms/ml); and (D) 10 day embryos from females treated on day 4 of gestation were cultured in normal serum. In group B there was no growth retardation; some slight nonspecific abnormalities were not significant. In group C, direct addition of AY 9944 to culture medium retarded growth and differentiation in a dose-dependent manner. No malformation was observed, but histological examinations showed numerous areas of cell necrosis, especially in the CNS. In group D, not only was growth retardation observed, but also characteristic malformations of AY 9944 teratogenesis, including pituitary agenesis. These results show that AY 9944 teratogenicity is initiated prior to day 10.     

Studies on the mechanism of trypan blue teratogenicity in the rat developing in vivo and in vitro

Trypan blue is a potent teratogen in vivo and in vitro in the rat. Many of the abnormalities produced by trypan blue--including swollen neural tube and pericardium, subectodermal blisters, hematomas, and generalized edema--may result from altered fluid balance in and around the embryo. The present study demonstrates relationships between changes in the fluid environment around the embryo and appearance of anomalies. Rat embryos were exposed in utero or in vitro to trypan blue during the early period of organogenesis. Both exposures resulted in defects that are typical of trypan blue treatment. Osmolality of exocoelomic fluid (ECF) was measured on gestation day 10 in vivo and day 12 in vitro, both after 48 hr of exposure to trypan blue. In both cases ECF osmolality was significantly lower than controls. This was correlated with the presence of edema-related anomalies in the embryo. On gestation day 11 in vivo, three days after maternal injection of trypan blue, ECF osmolalities were significantly higher than controls; however, there was tremendous variability in this parameter in day 11 treated embryos, and some had ECF osmolalities below the control range. Increased frequency of abnormalities was correlated with abnormal ECF osmolality, below and above the control range. Trypan blue probably exerts its teratogenic effects by disturbing the function of the visceral yolk sac. The movements of an amino acid and a monosaccharide across the visceral yolk sac were measured on gestation day 12 embryos in vitro. This aspect of yolk sac function was not altered by trypan blue exposure. Ultrastructure of the visceral yolk sac was observed after trypan blue exposure in vivo and in vitro. Endodermal cells in trypan blue-treated yolk sacs contained fewer large, electron dense lysosomes than controls. These were replaced by numerous small vacuoles, which may contain trypan blue. Trypan blue causes osmotic changes in the rat embryo in vivo and in vitro. These changes are correlated with embryonic malformations. Alterations in yolk sac ultrastructure indicate that trypan blue affects the function of this membrane.     

The embryolethality and teratogenicity of acrolein in cultured rat embryos

Acrolein, a three-carbon unsaturated aldehyde, is teratogenic to rats in vivo following intraamniotic administration but has been reported not to be teratogenic in vitro in the rat whole embryo culture system. In this study the effects of acrolein on rat embryos cultured in the standard medium consisting of rat serum were assessed over a narrow-concentration range. Additionally, a comparison was done of the effects of culture in a serum medium vs. a serum-free medium. In the serum medium acrolein caused 100% embryolethality at 140 microM and was found to be teratogenic in the concentration range of 80-120 microM. In the serum-free medium acrolein was 100% embryolethal at 20 microM and was teratogenic in the range of 5-15 microM. The EC50 for malformations in the serum medium was 137 microM, whereas that for embryolethality was 115 microM; the EC50s for malformations and embryolethality in the serum-free medium were 2.8 microM and 8.3 microM, respectively. Malformations were observed in the brain, facial area, and heart in addition to blebs and twisted or kinked bodies. Decreases in yolk sac diameter, crown-rump length, head length, number of somites, morphological score, and protein content were observed within the teratogenic ranges in each type of medium. Thus acrolein is teratogenic and embryolethal in vitro as well as in vivo. Dissociation between embryolethality and teratogenicity was seen in the serum-free medium. The slope of the acrolein log concentration-response curve in the serum-free medium was twice that in the serum medium, indicating that acrolein may have a different mechanism of action in this medium.     

Comparison of the effects of retinol and retinoic acid on postimplantation rat embryos in vitro

Rat embryos were explanted on day 8 or 9 of pregnancy and cultured for up to 48 hours in serum containing added retinol (vitamin A), retinoic acid (vitamin A acid), or absolute ethanol. They were examined morphologically and their protein content determined. Retinoic acid was more teratogenic and growth-retarding than retinol. Electron microscopy of embryos cultured for 30 minutes or one hour revealed that both forms of vitamin A brought about similar ultrastructural effects on the embryonic cells; however, the abnormally large intracellular lipid droplets observed in a previous study following exposure to retinol in vitro and retinyl palmitate in vivo were not observed in embryos exposed to retinoic acid. It is possible that the differential teratogenicity may be due to the inability of the embryonic cells to convert and store retinoic acid in a less teratogenic form.     

Zinc concentrations in mouse embryo and maternal plasma

The effect of a single teratogenic dose of the antiepileptic drug valproic acid and its nonteratogenic metabolite, 2-en-valproic acid, on zinc concentrations in mouse plasma, embryo, and decidua on d 9 of gestation was investigated. The substances were injected subcutaneously (sc) as their sodium salts. In this mouse model, valproic acid induced between 20% (400 mg/kg dose) and 60% (600 mg/kg dose) incidence of exencephaly in living fetuses; 2-en-valproic acid was not teratogenic at these dose levels. The zinc concentrations in plasma were significantly increased 1 and 2 h after administration of both substances. The embryonic zinc concentrations were increased 2 and 4 h after application of both substances. The concentrations of zinc in the decidua were not affected. The similarity of effects of valproic acid and its nonteratogenic analog on zinc concentrations in maternal plasma and embryo suggests that the teratogenicity of a single administration of valproic acid in the mouse is not owing to interference with the zinc metabolism in this species.     

Factors affecting the efficiency of embryo cryopreservation and rederivation of rat and mouse models

The efficiency of embryo banking for rat and mouse models of human disease and normal biological processes depends on the ease of obtaining embryos. Authors report on the effect of genotype on embryo production and rederivation. In an effort to establish banks of cryopreserved embryos, they provide two databases for comparing banking efficiency: one that contains the embryo collection results from approximately 11,000 rat embryo donors (111 models) and another that contains the embryo collection results from 4,023 mouse embryo donors (57 induced mutant models). The genotype of donor females affected the efficiency of embryo collection in two ways. First, the proportion of females yielding embryos varied markedly among genotypes (rats: 16-100 %, mean =71 %; mice: 24-95 %, mean =65 %). Second, the mean number of embryos recovered from females yielding embryos varied considerably (rats: 4-10.6, mean =7.8; mice 5.3-32.2, mean =13.7). Genotype also affected the efficiency of rederivation of banked rat and mouse embryos models by embryo transfer. For rats, thawed embryos (n =684) from 33 genotypes were transferred into 66 recipient females (pregnancy rate, 78 %). The average rate of developing live newborns for individual rat genotypes was 30 % with a range of 10 to 58 %. For mice, thawed embryos (n =2,064) from 59 genotypes were transferred into 119 pseudopregnant females (pregnancy rate: 76 %). The average rate of development of individual mouse genotypes was 33 % with a range of 11 to 53 %. This analysis demonstrates that genotype is an important consideration when planning embryo banking programs.     

Strain differences in phenobarbital-induced teratogenesis in mice

Anticonvulsant drugs are widely prescribed medications known to complicate more than 11,500 pregnancies each year in the United States. Although there is no clear consensus as to the teratogenicity of all of the clinically available compounds, it appears that most anticonvulsant drugs can induce congenital abnormalities in susceptible individuals. In a study designed to examine the role of the genotype on sensitivity to phenobarbital-induced malformations, three highly inbred mouse strains (SWV, C57BL/6J, and LM/Bc) received the drug via chronic oral administration. Phenobarbital was found to have a significant teratogenic potential in mice, resulting in skeletal, cardiac, renal, neural, and urogenital defects in a dose-related fashion. The LM/Bc strain was most sensitive to phenobarbital, with 46.7% of the fetuses exposed to the highest maternal plasma concentrations having malformations. C57BL/6J fetuses were the most resistant strain, with only 28.6% abnormalities.     

Some teratogenic properties of ethanol and acetaldehyde in C57BL/6J mice: implications for the study of the fetal alcohol syndrome

To investigate the teratogenic effect of acute alcohol exposure, pregnant C57BL/6J mice were exposed to 25% ethanol (either two doses of 2.9g/kg or one dose 5.8g/kg) during the organogenic period either by intraperitoneal injections or by intubation. The incidence of malformations varied according to (1) the stage of embryonic development at the time of exposure, (2) the route of administration of the alcohol, and (3) the amount of alcohol given and the time period over which it was administered. Oral doses of alcohol were teratogenic although less so than the same dose given intraperitoneally, and two intraperitoneal doses four hours apart produced significantly more malformation than the same two doses six hours apart. The primary metabolite of alcohol, acetaldehyde, was also investigated for its teratogenicity. It was found that one or two doses of four percent acetaldehyde (0.32g/kg), administered intraperitoneally were teratogenic. A further attempt was made to raise blood acetaldehyde levels by exposing mice to disulfiram, an inhibitor of acetaldehyde dehydrogenase, prior to administration of alcohol. The disulfiram pretreatment did not increase the malformation rate. Treatment with alcohol on day 7 or 8 caused a variety of facial abnormalities, some of which were comparable to those seen in children with fetal alcohol syndrome. Exposure on day 9 or 10 resulted in limb defects. The results suggest that one or more episodes of heavy maternal drinking at critical periods in pregnancy may severely damage the embryo and may produce many features of the fetal alcohol syndrome.     

Phenylalanine and its metabolites induce embryopathies in mouse embryos in culture

The aim of this study was to determine the teratogenicity of phenylalanine (Phe) and Phe metabolites in neurulating mouse embryos. Therefore, the system of whole embryo culture was employed and D9 (neurulating) mouse embryos were exposed to Phe, phenylethylamine (PEA), phenylpyruvic acid (PPA), phenylacetic acid (PAA), 2-OH phenylacetic acid (2-OH PAA), and phenyl-lactic acid (PLA) at concentrations ranging from 0.01 mM to 10 mM for 24 hours. After 24 hours, embryos were examined for morphological abnormalities and protein content by the Lowry method. Phe at 1 and 6 mM concentrations was not teratogenic; however, 10 mM inhibited cranial neural tube closure in 82% of the embryos. PEA was the most toxic factor and concentrations of 1 and 10 mM were embryo-lethal, whereas neural tube closure defects (NTDs) were observed in 67% of the embryos at 0.1 mM. 2-OH PAA was the second most toxic metabolite with concentrations of 1 and 10 mM producing NTDs in 10 and 100% of the embryos, respectively. PLA and PAA produced no NTDs at concentrations of 1 mM, 60% at 5 mM, and 100% at 10 mM. Finally, PPA produced approximately 50% NTDs at both 1 mM and 10 mM concentrations. PLA, PAA, 2-OH PAA, and PPA produced a significant reduction in embryonic protein, and PEA and 2-OH PAA reduced yolk sac protein values. PEA, 2-OH PAA, PPA, PAA, and PLA also produced craniofacial abnormalities, i.e., incomplete expansion of the forebrain, collapse of the optic vesicle, and hypoplasia of the mandible and/or the maxilla.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of lithium carbonate on mouse and rat embryos in vitro

Lithium is effective in the treatment of manic-depressive psychosis but is suspected to be a developmental toxicant in humans. It is a developmental toxicant in mice and rats in vivo, but at human therapeutic serum levels of 0.6-1.6 meq/L, rats appear to be more sensitive to the effects of the drug than do mice. The species susceptibility to lithium-induced defects was evaluated by using a rodent whole embryo culture system employing mouse and rat embryos treated at comparable developmental stages. Mouse embryos were cultured on gestational days 8-10, and rat embryos were cultured on gestational days 10-12. Care was taken to insure that all embryos had 10 +/- 2 somite pairs at the beginning of the culture period. Embryos were cultured for 44 hours in rat serum to which lithium was added to attain final drug concentrations of 0.6, 1.2, 1.8, 2.4, or 5.0 meq/L. Control embryos were treated with distilled water, which served as the vehicle. In rats, lithium induced significant decreases in various parameters at 1.8, 2.4, and 5.0 meq/L; no malformations were observed in rats of this stage. In mice, significant decreases occurred at 2.4 and 5.0 meq/L, and embryos treated at the highest concentration had a significantly increased frequency of open neural tubes. Rat embryos were also cultured with lithium on gestational days 9-11. The lowest dose producing developmental toxicity at this stage was 0.6 meq/L. Open neural tubes were present among younger rat embryos; however, this defect occurred in all groups, including the control group.(ABSTRACT TRUNCATED AT 250 WORDS)