Limb bud cell culture for in vitro teratogen screening: validation of an improved assessment method using 51 compounds

An Evaluation of a Novel Chick Cardiomyocyte Micromass Culture Assay with Two Teratogens/Embryotoxins Associated with Heart Defects

This study was aimed at determining whether the chick cardiomyocyte micromass (MM) system could be employed to predict the teratogenicity/embryotoxicity of exogenous chemicals. Two documented teratogens/embryotoxins, sodium valproate (the sodium salt of valproic acid; VPA) and all -trans retinoic acid (tRA), were used in the initial phase of the study. White Leghorn 5-day-old embryo hearts were dissociated to produce a cardiomyocyte suspension in Dulbecco's Modified Eagle's Medium. Cultures were incubated at 37°C in 5% CO2 in air, and observations were made every 24 hours over 5 days, for the detection of beating. Culture viability was assessed by using the resazurin reduction assay for determining culture activity and the kenacid blue assay for determining cell number. It was found that tRA significantly reduced cell activity and beating, whilst not affecting total cell number. VPA up to 500μM induced no cytotoxicity in the MM cardiomyocyte cultures, whilst all the VPA concentrations tested reduced beating. The results demonstrate the potential of the chick cardiomyocyte MM culture assay to identify teratogens/embryotoxins that alter functionality, which may result in a teratogenic outcome, whilst not causing cytotoxicity (direct embryotoxicity). This could form part of a screen for developmental toxicity related to cardiac function, whilst limb cultures and brain cultures based on the same system could be relevant to teratogenic effects on those tissues.

Comparison of rat and chick limb bud micromass cultures for developmental toxicity screening

This study compares the responses of rat and chick limb bud micromass cultures to chemical treatment. Eight chemicals, of diverse structure, potency and mechanism, were tested, using two endpoints: extractable alcian blue stain as a measure of differentiation to chondrocytes, and extractable neutral red stain as an index of proliferation. Each chemical reduced differentiation and proliferation in a concentration-related manner. IC(50)s, concentrations that reduced staining by 50%, ranged from 10 nm (colchicine) to 4 mm (acetazolamide). Rat and chick responses to acetazolamide, colchicine and diazepam were indistinguishable. For diphenhydramine and sulphisoxazole, concentration-response curves were very similar, but rat IC(50)s were half that of chick. For two chemicals, concentration-response slopes were markedly steeper for chick; in the case of beta-aminopropionitrile, IC(50)s were similar, but rat cultures were three-fold more sensitive than chick to cytosine arabinoside. 6-Aminonicotinamide gave a U-shaped response curve, for both endpoints and both species, so IC(50)s may be misleading, but the IC(50) for proliferation was lower for chick (0.6 mum) than rat (4 mum). In vivo and in vitro parameters for validation of developmental toxicity screens are contentious. Diphenhydramine apart, these chemicals can be teratogenic in vivo, although their 'hazard' can be debated. An IC(50)-proliferation/IC(50)-differentiation ratio > 2 has been suggested to predict specific developmental toxicity. Only sulphisoxazole and 6-aminonicotinamide had significantly different IC(50)s for proliferation and differentiation, with ratios of 4.4 (both species), and 10.4 for rat and 1.9 for chick, respectively. All other ratios were close to 1. The general consistency of this ratio, and the concentration-responses, in the two species suggests that the chick is a viable alternative to laboratory mammals, but the predictive ability of micromass remains to be determined.

Substance-tailored testing strategies in toxicology: an in silico methodology based on QSAR modeling of toxicological thresholds and Monte Carlo simulations of toxicological testing

The design of toxicological testing strategies aimed at identifying the toxic effects of chemicals without (or with a minimal) recourse to animal experimentation is an important issue for toxicological regulations and for industrial decision-making. This article describes an original approach which enables the design of substance-tailored testing strategies with a specified performance in terms of false-positive and false-negative rates. The outcome of toxicological testing is simulated in a different way than previously published articles on the topic. Indeed, toxicological outcomes are simulated not only as a function of the performance of toxicological tests but also as a function of the physico-chemical properties of chemicals. The required inputs for our approach are QSAR predictions for the LOAELs of the toxicological effect of interest and statistical distributions describing the relationship existing between in vivo LOAEL values and results from in vitro tests. Our methodology is able to correctly predict the performance of testing strategies designed to analyze the teratogenic effects of two chemicals: di(2-ethylhexyl)phthalate and Indomethacin. The proposed decision-support methodology can be adapted to any toxicological context as long as a statistical comparison between in vitro and in vivo results is possible and QSAR models for the toxicological effect of interest can be developed.

Diethylene glycol monomethyl ether, ethylene glycol monomethyl ether and the metabolite, 2-methoxyacetic acid affect in vitro chondrogenesis

Diethylene glycol monomethyl ether (DEGME), ethylene glycol monomethyl ether (EGME) and their common metabolite, methoxyacetic acid (MAA) have been associated with adverse reproductive effects. The objective of this research is to investigate the effects of DEGME, EGME and MAA on in vitro chondrogenesis and the mechanisms by which these effects occur. Micromass cultures were exposed to DEGME, EGME or MAA for 5 days and proteoglycan abundance and cell proliferation determined. Longer-term 9- and 14-day cultures were exposed to MAA and apoptosis analyzed. All three chemicals decreased proteoglycan abundance and cell proliferation at the highest dose tested (100 microL/mL). However, only MAA showed a dose-dependent effect for both parameters at 0.01, 10, and 100 microL/mL. Furthermore, micromass cultures show an increase in apoptotic cells which when treated with MAA suggest that cell death could result from induced apoptosis. These results suggest that effects of DEGME and EGME are the result of generalized toxicity, but their metabolite MAA induces mitochondrial-mediated apoptosis during in vitro chondrogenesis.

Discriminative power of an assay for automated in vitro screening of teratogens

Screening for potential teratogenicity of 20 test compounds was performed using a computerised microscope workstation for determination of cytotoxicity, proliferation and morphology of fibroblastoid murine L929-cells. The test compounds, which were divided into four classes according to teratogenicity were: 5-bromo-2(')-deoxyuridine, 6-aminonicotinamide, acrylamide, boric acid, D-(+)-camphor, dimethadione, dimethyl phthalate, diphenhydramine, hydroxyurea, isobutyl-ethyl-valproic acid, lithium chloride, methyl mercury chloride, methotrexate, methoxyacetic acid, penicillin G, all-trans-retinoic acid, pentyl-4-yn-valproic acid, saccharin, salicylic acid and valproic acid. All compounds, with the exception of dimethadione inhibited proliferation in a linear dose-dependent manner, and there were statistically significant compound class-dependent differences between the IC(50)-values for the compounds (p<0.0374), the strongest teratogens being the most potent. Furthermore, the average efficacies (maximum relative change) for 10 parameters describing cell morphology exhibited statistically significant compound class-dependent differences (p<0.0001), the class I and II compounds exhibiting significantly lower efficacies than the class III and IV compounds (p<0.01). Thus, test compounds affected both the proliferation and morphology of L-cells in manner demonstrating a general relationship with the teratogenic potency of the compounds. However, the moderate teratogens dimethadione and lithium chloride only had minor effects on the morphology and proliferation of the cells whereas the non-teratogen diphenhydramine had effects on both proliferation and morphology comparable to the strong teratogens.

Effects of aliphatic nitriles in micromass cultures of rat embryo limb bud cells

The relative effects of a series of eight saturated (acetonitrile, propionitrile and n-butyronitrile) and unsaturated (acrylonitrile, allylnitrile, methacrylonitrile, cis-2-pentenenitrile, and 2-chloroacrylonitrile) aliphatic nitriles were evaluated using an in vitro test for embryotoxicity, the rat limb bud micromass assay. The concentrations that produced 50% inhibition (IC50) of viability and differentiation of the cultured embryonic cells were of the same order of magnitude, whatever tested compound. The IC50 values spread over a wide concentration range from 7-11 microM to 150 mM. Acetonitrile and 2-chloroacrylonitrile were the least and most potent compounds, respectively. The tested chemicals were evaluated using different criteria proposed to identify teratogens in the micromass system, based on either active concentrations or specific inhibition of cell differentiation. A few incorrect classifications were obtained with both nonteratogens and teratogens, when comparing the activity in limb bud cell cultures with the data available on their in vivo teratogenic potential in rats. The concordance between the in vitro and in vivo responses of this set of nitriles was judged insufficient to consider the micromass assay valuable for predicting the in vivo teratogenic outcome of this class of compounds.

Organ culture of the fetal mouse palate for screening the developmental toxicity of chemicals: a validation study

Using in vitro organ culture of the fetal mouse palate in a chemically defined serumless medium, the toxicity of 24 chemical compounds was investigated. Explanted palates of day-12.5 mouse fetuses were exposed for 72 h in vitro to various concentrations of each chemical, and the fusion rate and growth parameters were compared between the experimental group and respective controls. The average rate of palate fusion was 84% in vehicle controls. For compounds that are teratogenic in experimental animals in vivo, the fusion rates of palatal shelves decreased as the concentration of the test chemicals increased, showing a dose-dependent relationship. Palate fusion was inhibited by 11 of the 15 in vivo teratogens, and the predictability of in vivo developmental toxicity in this culture system was 73%. Cyclophosphamide itself did not inhibit the growth and fusion of explanted palates, but supplementation of hepatic S-9 fraction and cofactors for a monooxygenase system converted it to a toxic substance, as was shown in other in vitro systems. The 50% inhibitory concentration (IC50) value calculated based on the fusion rate was also found to be a useful parameter for evaluating the developmental toxicity of drugs. The teratogenic risk in the human fetus could be assessed by comparing the minimal toxic concentrations of the test compound on cultured palates with the maximal plasma level in pregnant women under therapeutic conditions and with the plasma concentrations when its minimal teratogenic dose is given to pregnant mice. This organ culture system of the fetal palate should be useful for screening the developmental toxicity of drugs and other environmental agents, and its value should increase when it is used in combination with other battery test systems.

An in vitro screening paradigm for extracts of whole foods for detection of potential toxicants

The application of organic, conventional and biotechnology techniques can alter the intrinsic levels of natural toxicants in crop foods and methods are needed to screen for unexpected changes in toxicant levels. We evaluated crude, aqueous preparations of 37 foods purchased from a local market in a battery of four in vitro mammalian toxicity screens. The foods were evaluated in one or more of the following tests: (1) cytotoxicity (37 foods) and (2) chromosomal aberration test (nine foods), both in Chinese hamster ovary cells, (3) limb bud micromass assay (nine foods) using 11-day old CD-1 mouse embryos and (4) estrogenicity (MCF-7 cells transfected with estrogen receptor and lucerifase reporter constructs, 12 foods). IC50s for cellular proliferation ranged from < 1% (v/v, garlic) to > 10% (v/v, 18 foods), the maximal concentration tested. Five of nine preparations (soybeans, broccoli, garlic, snow peas and corn) were clastogenic and two (soybeans and snow peas) inhibited chrondrogenesis in the limb bud micromass assay. Five of nine preparations (soybeans, snow peas, cumin, asparagus and bean sprouts) produced significant estrogenic responses. Overall, the 12 foods evaluated in two or more of the tests showed different patterns of response. These preliminary data indicate that screening for potential toxicants is possible with fast, relatively inexpensive in vitro tests. These in vitro tests, while potentially useful to detect unexpected toxicants in plants that may signal the need for further evaluation, are not directly useful to predict human or animal risk from eating these plants.

Assessment of the U.S. Environmental Protection Agency methods for identification of hazards to developing organisms, Part II: The developmental toxicity testing guideline

BACKGROUND

The effects of toxins on developing animals depend not only on the nature of the chemical but also on the timing of exposure and assessment of outcomes. This complicates the task of regulatory agencies such as the U.S. Environmental Protection Agency (EPA), which must comply with the 1996 Food Quality Protection Act to ensure that their standards and policies protect infants and children from environmental toxins. For this task, the Agency relies heavily on scientific data obtained by manufacturers of industrial chemicals and pesticides following protocols collected under EPA's Health Effects Test Guidelines.

METHODS AND RESULTS

This article reviews the protocols included in the EPA guidelines to assess developmental toxicity, which are required for food-use pesticides under the core testing battery. We reviewed these protocols on the basis of their adequacy for identifying hazards to infants and children. Our analysis found limitations in the protocols that hinder their potential for identifying developmental hazards.

CONCLUSIONS

Methods that the EPA currently depends upon to identify developmental toxicity of chemicals have limitations that impede obtaining complete and reliable data on which to base regulatory decisions that protect children. Other methodological approaches need to be explored as alternatives or supplements to the current protocols. Until more accurate testing protocols become available, it may well be necessary under existing laws to employ safety factors that are more protective of the health of children at all stages of development.

Retinoid-induced limb defects 1: inhibition of cell proliferation in distal mesenchyme of limb buds in rats

The present study was undertaken to investigate the effects of all-trans-retinoic acid (RA) on cell death and limb bud growth in forelimb buds and also to examine whether these events are involved in limb bone defects induced by RA in rats. RA was given at doses of 50 and 100 mg/kg to pregnant rats on Day 12 of pregnancy. Although RA did not show teratogenecity in the 50 mg/kg group, micromelia was observed in the 100 mg/kg group in all live fetuses on Day 21 of gestation. Micromelia was characterized by high incidences of proximodistal reduction of forearm bones without reduction of the humerus. The incidence of cell death in prechondrogenic areas, which differentiate into humerus and forearm bone, significantly increased 24 h after RA treatment in not only the 100 mg/kg, but also the 50 mg/kg, group. There was no difference in the incidence of cell death in the prechondrogenic area between the two groups. These observations indicate that the bone-specific defects were not the result of cell death alone in the prechondrogenic area. We examined the effects of RA on early forelimb bud growth, which is indispensable for the morphogenesis of the forelimb. Proximodistal length and protein content were decreased significantly in the forelimb bud 24 h after RA treatment at a dose of 100 mg/kg, but not 50 mg/kg. The immunohistochemical detection of bromodeoxyuridine (BrdU) incorporated into cells showed that at a dose of 100 mg/kg, cell proliferation was reduced in the distal mesenchyme, but not in the forearm-bone prechondrocytes of the forelimb bud. As the distal margin provides the cells differentiating into the prechondrocytes of future bones in the limb bud, these observations suggested that RA-induced inhibition of cell proliferation in the distal margin resulted in a decrease of forearm-bone prechondrocytes localized at more distal sites. We conclude that RA may inhibit the chondrogenesis of forearm bones by reducing cell proliferation in the distal margin of the forelimb bud, not by increasing cell death, and that this results in reduction defects in forearm bones.

The Comparative Testing of Eight Coded Chemicals in the Rat Limb Bud Micromass and Rat Embryo Culture Systems

When cultured at high density, mesenchymal cells from rat limb buds proliferate and differentiate into chondrocytes. Inhibition of this in vitro chondrogenic process has been used for the preliminary evaluation of teratogenic potential. Alternatively, intact post-implantation rat embryos, maintained in short-term culture, provide a system for the in vitro study of abnormal development not limited to the skeletal system. Both systems isolate the test agent from maternal metabolism and pharmacokinetic restraints. In this study, drug-associated selective inhibition of alcian blue uptake by cartilage proteoglycans, in micromass cultures of limb bud cells prepared from 13-day-old rat embryos, was used to assess teratogenic potential in vitro following exposure for 48 hours to eight coded compounds (acetylsalicylic acid, isoniazid. penicillin G, saccharine, vincristine sulphate, 6-aminonicotinamide, retinoic acid, and amaranth). Following drug exposure, cultures were incubated for another 96 hours, and the cells were then fixed and stained with 0.5% alcian blue. Bound dye was then extracted and quantitated. In parallel cultures, cell viability was measured by neutral red uptake, and protein content was assayed by using the bicinchoninic acid method. Except for retinoic acid and vincristine sulphate, the maximum test concentration was 1000μg/ml. Inhibition of alcian blue uptake (> 50%) was noted at 0.001μg/ml vincristine sulphate, 0.5/μg/ml retinoic acid and 5μg/ml 6-aminonicotinamide, demonstrating that strong teratogens inhibit differentiation in micromass cultures at lower concentrations than those which affect limb cell viability. When the same eight compounds were tested in a 24-hour embryo culture model, dysmorphogenesis was evident at 0.005μg/ml vincristine sulphate, 0.1μg/ml retinoic acid and 0.3μg/ml 6-aminonicotinamide. For the other five chemicals, little or no toxicity was noted up to the maximum test concentration in either model. We conclude that the two test systems, both based on the developing rat embryo, are consistent with each other, and that either of them would be useful for the preliminary screening of potential teratogens.

Effects of UVC irradiation on cultured mouse embryonic limb bud cells

Effects of UVC irradiation (UVC) at a dose range from 0 to 30 J/m(2) were investigated on the cultured embryonic limb bud cells (LBC), isolated from fore- and hindlimbs of day 11 mouse embryos. Although dose-dependent inhibition was found for both cellular proliferation and chondrogenesis, the chondrogenic proteoglycan (PG) synthesis was more sensitive to UVC than cellular proliferation when compared at ID(50), the inhibitory dose that reduced assessment value by 50% of the control. No significant difference in induction and repair kinetics of UV-induced cyclobutane pyrimidine dimers (CPDs) and (6-4) photoproducts ((6-4)PPs) were found between LBC and NIH3T3 mouse cell line. The fluorescent light (FL) treatment of LBC pre or post UVC irradiation did not affect repair kinetics of CPDs and (6-4)PPs, cellular proliferation, formation of PG-producing nodule and the PG synthesis.

Pyridoxine for nausea and vomiting of pregnancy: a randomized, double-blind, placebo-controlled trial

OBJECTIVE

Our purpose was to determine the effectiveness of pyridoxine for nausea and vomiting of pregnancy.

STUDY DESIGN

During an 11-month period 342 women who first attended Chiang Mai University Hospital antenatal clinic at < or = 17 weeks' gestation were randomized to received either oral pyridoxine hydrochloride, 30 mg per day, or placebo in a double-blind fashion. Patients graded the severity of their nausea by a visual analog scale and recorded the number of vomiting episodes over the previous 24 hours before treatment and again during 5 consecutive days on treatment.

RESULTS

There was a significant decrease in the mean of posttherapy minus baseline nausea scores in the pyridoxine compared with that in the placebo group (t test, p = 0.0008). There was also a greater reduction in the mean number of vomiting episodes, but the differences did not reach statistical significance (p = 0.0552).

CONCLUSION

Pyridoxine is effective in relieving the severity of nausea in early pregnancy.

Maternal toxicokinetics, metabolism, and embryo exposure following a teratogenic dosing regimen with 13-cis-retinoic acid (isotretinoin) in the cynomolgus monkey

The maternal pharmacokinetics, metabolism, and placental transfer of 13-cis-retinoic acid (isotretinoin) have been determined in the cynomolgus monkey using a dosing regimen which had been previously shown to result in retinoid-specific teratogenic effects [Hummler et al. (1990) Teratology 42:263-272]. The drug (2.5 mg/kg body weight) was administered by nasogastric intubation once a day between gestational days (GD) 16-26, and twice a day between GD 27-31. Maternal plasma kinetics were determined following dosing on GD 26 and GD 31, and placental transfer was studied following the last dose on GD 31. The plasma half life of 13-cis-retinoic acid in the monkey (13.2 h) was comparable to that in the human. The main plasma metabolite in the monkey was the 13-cis-4-oxo-retinoic acid which occurred at levels lower or comparable to those of the administered drug. During multiple dosing, this metabolite accumulated to the same degree as the parent drug. All-trans-retinoic acid was present in maternal plasma in very low concentrations (2% of 13-cis-retinoic acid). The beta-glucuronides of all-trans- and 13-cis-retinoic acid were further minor plasma metabolites. 13-cis-retinoic acid and its 4-oxo-metabolite reached the monkey embryo slowly but extensively during organogenesis and reached 24 h-AUC values of 956 and 590 ng.h/g embryo wet weight, resulting in embryo/maternal plasma concentration ratios of 0.41 and 0.33, respectively. The AUC value of all-trans-retinoic acid (316 ng.h/g) was only raised approximately 40% above the endogenous AUC level (225 ng.h/g); only at two time periods examined were the embryonic all-trans-retinoic acid concentrations above endogenous levels (at 4 h and 8 h; P < 0.01 and < 0.05, respectively; Student's t-test). The beta-glucuronides of all-trans- and 13-cis-retinoic acid were not detected in the embryo. Accumulation of 13-cis-retinoic acid and the 4-oxo-metabolite during the twice-per-day dosing regimen was apparent both in maternal plasma and embryo. An interspecies comparison suggests that the half life as well as the metabolic pattern of 13-cis-retinoic acid in plasma were similar in monkey and human: 13-cis-4-oxo-retinoic acid was the main metabolite in both species and the beta-glucoronides as well as all-trans-retinoic acid were minor metabolites. However, the plasma AUC values of the administered drug and particularly the 4-oxo-metabolite were found to be lower in the monkey as compared to the human.(ABSTRACT TRUNCATED AT 400 WORDS)

Interleukin-1 beta-specific partial agonists defined by site-directed mutagenesis studies

Monocyte-derived interleukin 1 (IL-1) mediates a wide range of biological effects including destruction of the cartilage matrix in articular diseases such as rheumatoid and osteoarthritis. To elucidate further the relationships between protein structure and biological activities, we have analyzed the sequence of several IL-1 polypeptides using the algorithm of Parker, the hydrophobic cluster analysis method and published structural data. This led us to identify several residues that seemed to be strictly topologically conserved, with respect to identifiable secondary structures features, although this was not readily apparent from sequence alignments. We performed site-directed mutagenesis on some of these conserved residues, as well as on those predicted to occur in external loops of the polypeptide. Human IL-1 beta mutant polypeptides were expressed in Escherichia coli in soluble form and purified to homogeneity by anion-exchange and gel-filtration chromatography. Their biological effects (binding to EL4-6.1 murine thymocytes, Raji human B cells and rabbit chondrocytes cells, lymphocyte activation, neutral protease induction, proteoglycan degradation and synthesis) have been determined. Among the 20 IL-1 beta mutant polypeptides we present here, four showed a markedly reduced activity in cartilage matrix assays without any significant change in their binding to the cartilage matrix cells (chondrocytes). Furthermore, some of these mutants were specific partial agonists of the effects of IL-1 on connective tissue since they have a low affinity for thymocytes.

In vitro tests for teratogens: desirable endpoints, test batteries and current status of the micromass teratogen test

Information from in vitro tests can be usefully used as a component of the risk/hazard assessment process. In vivo studies will be required to confirm the in vitro data. If the in vitro test system is designed around endpoints that reflect changes following in vivo toxic insult then it may be possible to modify the in vitro system to account for some of the discrepancies observed between in vivo and in vitro outcomes. When the discrepancy can be accounted for by low bioavailability in vivo, pharmacokinetic studies may be required to determine the relevance of the in vitro toxic concentrations. Reproductive hazard, especially teratogenicity, has been the subject of intensive in vitro test development. The observation of teratogenicity may affect the development of new products more significantly than any other type or category of reproductive toxicity. The micromass test, involving culture of differentiating rat embryo limb and midbrain cells exposed to test agents, may be useful as part of a battery of in vitro tests for teratogens. The most recent protocol for the micromass test is described, followed by a summary of validation and mechanistic studies confirming its usefulness. The test is robust in its transfer to new laboratories. Interlaboratory variability is small.

Activity profiles of developmental toxicity: design considerations and pilot implementation

The available literature was searched for quantitative test results from both in vitro and in vivo assays for developmental toxicity for five model compounds: cyclophosphamide, methotrexate, hydroxyurea, caffeine, and ethylenethiourea. These compounds were chosen on the basis of their extensive utilization in a variety of assay systems for developmental toxicity as evidenced by their representation in the ETIC database (each generally has 100-500 citations encompassing multiple test systems). Nine cellular-based assays, six assays using whole embryos in culture, as well as Segment II and abbreviated exposure tests for mammalian test species are included in the database. For each assay, the critical endpoints were identified, each of which was then provided a three-letter code, and the criteria for extraction of quantitative information were established. The extracted information was placed into a computerized reference file and subsequently plotted such that the qualitative (positive/negative) and quantitative (e.g., IC50, highest ineffective dose (HID), lowest effective dose (LED] results across all test systems could be displayed. The information contained in these profiles can be used to compare qualitative and quantitative results across multiple assay systems, to identify data gaps in the literature, to evaluate the concordance of the assays, to calculate relative potencies, and to examine structure-activity relationships.

Embryolethality of new herbicides is not detected by the micromass teratogen tests

New herbicidal compounds (11 pyrimidine-diones, 3 benzoates and 1 sulfonamide) were found to be embryolethal but not teratogenic in rats. The range of the embryolethal dose varied from 0.2 to greater than 200 mg/kg. This broad range enabled us to validate whether proposed in vitro teratogen tests can detect the embryolethality of these herbicides. The IC50 values (inhibition concentration 50%) for both differentiation and proliferation of midbrain and limb bud cells of rat embryos were determined and found to be above 50 micrograms/ml in all cases, confirming that the herbicides were not teratogenic. No correlation, however, was observed between the embryolethality in vivo and the activities in these cells. In order to test whether the potential to cause embryolethality could be predicted and detected as a general cytotoxic effect, the inhibition of colony forming ability in V79 cells was determined. The results indicated that cytotoxicity in V79 cells may be useful for preliminary testing of the embryolethal effect of herbicides.

The effect of acetylsalicylic acid on the development of the skeletal system in rats

The authors wished to clarify the cause of micro- and phocomelia developing in rat fetuses following administration of acetylsalicylic acid. It has been proved by histological examinations that the positive ground substance of the epiphyseal cartilage, detected by Rivanol reaction, became disarranged or negative. The sulphation of glycosaminoglycans was diminished or inhibited by acetylsalicylic acid in the chondrocytes depending on the dose applied. The conclusion has been drawn that the malformation developed is due to the reduced production of sulphated mucopolysaccharides.

Teratogenicity of arotinoids (retinoids) in vivo and in vitro

The effect of structural modifications on the arotinoid molecule, a new class of retinoids, on their teratogenicity in mice was studied. Animals were treated on days 8 and 9 of gestation, the most susceptible stages to retinoid-induced malformations in rodents. The teratogenic potency of the 13 arotinoids tested varied over a dose range of more than five orders of magnitude. Next, we tested whether the quantitative differences in the teratogenicity of these arotinoids correlates with their activity in high density (micromass) cultures of rat embryonic limb bud and midbrain cells. There was a good quantitative correlation between the in vivo teratogenicity and the in vitro activity in limb bud cells but no correlation was found in midbrain cells. Thus, the limb bud cell culture system may be useful for a preliminary testing to select non-teratogenic retinoids. For the risk assessment in humans, however, the in vitro results should be verified in animals studies.

Examination of a rodent limb bud micromass assay as a prescreen for developmental toxicity

The mouse limb bud micromass assay is one of many short-term tests proposed as preliminary screens for potential developmental toxicity. Previous efforts to validate this assay have used too few "nonteratogens." The purpose of this study was to examine additional compounds, most of which, based on the literature, were perceived to have low potential for developmental toxicity in vivo. In addition, a method of data analysis was sought that would identify selective developmental toxins in the micromass assay, i.e., those that are effective at dosages not maternally toxic. The concentration of each of 23 compounds that produced a 50% inhibition (IC50) of radiolabeled thymidine (T) and sulfate (S) incorporation was determined and used to calculate a T/S ratio. The T/S ratio may be a useful measure of developmental hazard, since T incorporation measures toxicity toward a general cell function (DNA synthesis) and S incorporation measures mainly toxicity toward a developmentally specific cell activity (chondroitin sulfate synthesis). All compounds tested produced T/S ratios of less than 2.0. Since 22 of these 23 compounds are classified as "nonteratogens" or nonselective developmental toxins in vivo, a low T/S ratio in this in vitro assay system may be capable of discriminating potential for developmental hazard in vivo.