Teratogenic effects on the neuroepithelium of the CD-1 mouse embryo exposed in utero to sodium valproate

A causal association has now been recognized between the use of the anticonvulsant drug sodium valproate during pregnancy and the increased incidence of spina bifida in the human population. The objective of this study was to investigate the teratogenic effects of sodium valproate on the cephalic 1) neuroepithelium, 2) extracellular matrix, and 3) embryonic protein content in the CD-1 mouse embryo. Nulliparous female CD-1 mice were dosed intraperitoneally on day 8 of gestation with 340 mg/kg of sodium valproate. On day 10 of gestation, females were killed by cervical dislocation, and all live embryos were assigned to one of the following groups and processed accordingly for: 1) head measurements, 2) scanning electron microscopy, 3) total protein determination, 4) two-dimensional polyacrylamide gel electrophoresis, 5) immunohistochemistry, and 6) light microscopy. Exposure to sodium valproate at the selected dosage resulted in a 30% incidence of neural tube defects in the cranial region of these embryos. Treated embryos showed a significant reduction in head size, indicating a drug-induced microcephaly. No major differences were seen in the total embryonic protein patterns between control and treated embryos. Immunoreactivity to laminin and fibronectin showed a similar distribution in control and treated embryos except in the vasculature pattern of the hindbrain neuroepithelium. The neuroepithelium of the treated embryos showed marked disorganization when it was examined histologically, particularly in the forebrain region. Cells were disoriented, and there was a noticeable loss of intercellular adhesion in the juxtaluminal region. Increased cellular blebbing was apparent at the ependymal surface, and large protrusions of cells were seen invading the neural tube lumen. The lumen was distorted in shape and frequently contained blood cells. Irregularities and gaps were observed in the underlying basal lamina. These results suggest that treatment with sodium valproate during a critical time in neurogenesis in the CD-1 mouse embryo alters the normal architecture of the neuroepithelium, with a loss of integrity at both the basal and apical surfaces. The alterations seen in the neuroepithelium at any of these sites in this animal model could help explain the increased incidence of spina bifida seen in children of epileptic mothers receiving sodium valproate.     

Pre- and post-conceptional tobacco effects on the CD-1 mouse fetus

The objective of this study was to examine the effect of subchronic administration of an aqueous extract of smokeless tobacco (ST) on the development of the CD-1 mouse fetus. Mice were administered ST for approximately 5 weeks: for 2 weeks prior to breeding, during breeding, and during gestational days 0 to 17. Thus the initial peak nicotine levels occurred prior to breeding and not during the critical periods of gestation. Two ST dosages were administered by gastric intubation three times daily: ST/D-1, equivalent to a dose of 12 mg nicotine/kg of body weight, and ST/D-2, equivalent to 20 mg nicotine/kg body weight. Maternal plasma nicotine levels were determined 30 min after the second intubation during the pretreatment and gestational phases of treatment. At these ST dosages, the weight gain of ST-treated dams was not significantly affected in comparison to treated controls. The mean maternal plasma nicotine level for the low-dosage group was 363 ng/ml, and 481 ng/ml for the high-dosage group, with maternal lethality observed at 9.6% and 28.2%, respectively. No significant differences were seen between control and ST/D-1 maternal and/or fetal values, except for placental weights which were heaviest in the ST group (P less than 0.05). Several differences were noted between the ST/D-2 group and controls: fetal weights were reduced by 5.4% (P less than 0.05); decreased ossification was seen in femur measurements and in nine of ten characteristics measured (P less than 0.05); the frequency of resorptions (7.6%) was almost doubled (controls 4.2%); and the frequency of deaths and malformations was not affected. Under these experimental conditions, the low dose produced a negligible effect on the CD-1 mouse fetus and the dam. The high dose demonstrated growth retardation (P less than 0.05), increased embryotoxicity, and a significant decrease in ossification (P less than 0.05).     

Alcohol and smokeless tobacco effects on the CD-1 mouse fetus.

Tobacco products and alcohol are commonly used as nonmedicinal drugs by pregnant women, and both are known to cause various effects on the fetus and the newborn. The objective of this study was to examine the fetal effects of both drugs when administered individually and simultaneously to pregnant CD-1 mice at moderate dosages. Specifically, we wanted to determine whether or not the effect on the fetus of these two biologically active substances was additive, ameliorative, or synergistic. A total of 65 CD-1 dams were divided among four groups receiving either ST equivalent to 8 mg/kg nicotine, ethanol (ETOH) 1.8 g/kg, a combination of ST+ETOH in the same dosages, or D-glucose (controls and ST alone) to supply calories equivalent to the dose of ethanol. Mice were dosed three times per day on gestational days 6-15. On gestational day 17 all dams were killed, fetal and placental weights recorded, and the number of resorbed, dead, and malformed fetuses noted. The mean maternal plasma drug levels were: nicotine-321 ng/ml and ethanol-0.105 g%. No significant differences were observed in maternal weight gain, litter size, or in the incidence of resorptions, deaths and/or malformations. Fetal weights were reduced in all three treatment groups (P less than 0.05), with the greatest reduction (13% decrease) recorded in the ST group, followed by a 9% decrease in the ETOH group, and a 7% decrease in the ST+ETOH group. Placentas of the ST group weighed significantly less (P less than 0.05) than controls. Ossification of the fetal skeleton, observed in ten sites, was affected to the greatest extent in the ST group, followed by the ETOH and ST+ETOH groups. Craniofacial measurements were significantly affected (P less than 0.05) in all three treatment groups, compared to controls. We conclude that under these experimental conditions, in terms of fetal growth and ossification, ST had the greatest effect, followed by ETOH and ST+ETOH. The interaction of ST+ETOH was neither additive, synergistic, nor ameliorative.     

Effects of sodium valproate and oxygen on the craniofacial skeletal pattern in the CD-1 mouse embryo

Growth retardation is a consistent finding in animal studies on the effect of sodium valproate (NaVP) in the embryo. Apart from fetal weight, the state of ossification in the embryo may be regarded as an indication of growth. The present study was to determine what effect sodium valproate at human therapeutic drug plasma levels had on the craniofacial skeletal pattern in the CD-1 mouse embryo relative to oxygen conditions, drug treatment or the interaction of the two. Two NaVP-filled Alzet osmotic minipumps were implanted subcutaneously on day 5 of gestation for continuous delivery of a total daily dosage of 850 mg/kg for 7 days. During this same time period the dams were also exposed to either normoxic (21% oxygen), hyperoxic (50% oxygen), or hypoxic (12% oxygen) controlled environments. Dams were removed from the oxygen chambers on day 12 and killed on day 18 of gestation. The fetuses were then processed for skeletal evaluation of the craniofacial region. Ossification centers were present in all but six of the skeletal elements studied. The primary ossification delay was in the tympanic bony labyrinth. In addition, there was a decrease in maxillary and mandibular length and cranial base measurements. The greatest toxic effect on the fetus for all skeletal components studied was in the NaVP/hypoxia treated group. This finding suggests that fetal skeletal maturation may be affected by a combination of intrauterine as well as external factors.     

Teratogenic effects of dosage levels and time of administration of carbamazepine, sodium valproate, and diphenylhydantoin on craniofacial development in the CD-1 mouse fetus

The objective of this investigation was to study the teratogenic effects of dosage levels and time of administration of three anticonvulsant drugs (carbamazepine [CMZ], sodium valproate [NaV], and diphenylhydantoin [DPH]) on craniofacial development in the CD-1 mouse fetus. Pregnant females were intubated on each of days 8-10, 11-13, 14-16, and 8-16 of gestation with the following dose levels for each drug: 375, 563, 938 mg/kg CMZ; 225, 338, 563 mg/kg NaV; 50, 75, 125 mg/kg DPH. Appropriate control groups were maintained for each drug. On gestation day 17, pregnant females were killed and implantation sites were recorded as live, dead, or resorbed. All live fetuses were examined for craniofacial defects. Results of examination of 1,398 fetuses indicated that CMZ, NaV, and DPH were teratogenic and embryotoxic at all dose levels. This study indicated that the observed decrease in mean fetal weight was drug-, dose-, and time-dependent. There was a drug-, dose-, and time-dependent increase observed in the number of dead fetuses, whereas the number of resorbed fetuses was observed to be only time-dependent. The observed frequencies of hydrocephalies, secondary palatal clefts, and submucous palatal clefts were significant for all three factors (drug, dose, and time) whereas the observed frequencies of hematomas and exencephalies were significant only for drug and time. Cleft lips were observed only in the highest dose level of DPH. Uterine horn distribution of defects indicated that fetuses located at the proximal end of the horns were less subject to major defects than those fetuses located at the distal end of the uterine horns. Fetuses with craniofacial hematomas were found in the proximal one-third of the uterine horn, resorbed fetuses, and fetuses with submucous palatal clefts in the middle one-third of the uterine horns and dead fetuses and fetuses with exencephalies, cleft lips, and secondary palatal clefts were localized in the distal one-third of the uterine horns. In comparing the effect of drug, dosage, and time on the development of craniofacial malformations in the CD-1 mouse fetus, CMZ was the least teratogenic and embryotoxic of the three anticonvulsant drugs employed in this study.     

Morphometric analysis of the craniofacial development of the CD-1 mouse fetus exposed to alcohol on gestational day eight

Fetal alcohol syndrome (FAS) describes a pattern of dysmorphogenesis observed in some offspring of women who consumed alcohol during pregnancy; partial expression of this pattern are fetal alcohol effects (FAE). The purpose of this investigation was to measure selected craniofacial parameters in the CD-1 mouse fetus following exposure to alcohol on gestational day (D) 8. CD-1 mice were mated for 1 hr; D0.0 designated by the presence of a vaginal plug. On D8, 0 hr, and D8, 4 hr, 33 dams were injected intraperitoneally (IP) with 25% (v/v) alcohol in physiological saline solution (0.015 ml/gm maternal body weight). Appropriate controls were maintained. The animals were sacrificed every 12 hr from D12.0 through D17.0. Implantation sites were examined and recorded as live, dead, or resorbed fetuses. All live fetuses were weighed, examined for gross defects, and fixed in Bouin's solution. Twenty-three bilateral parameters were recorded for linear dimensions defining face and cranium. The fetal weights were statistically lower in treated as compared to control fetuses only on D16.0 through D17.0. Statistical analysis of the morphometrics identified five distinct growth patterns in treated mice as compared to controls. The anomalies induced in the CD-1 mouse fetus following exposure to alcohol on D8.0 resembled FAE rather than FAS. Morphometric analysis of the craniofacial region may be an important clinical tool for the quantitative identification of alcohol-related effects in the offspring of women who consumed alcohol while pregnant.     

Teratogenic effects of lead in the mouse

Female mice of the C57B1 strain were mated and given from the first day of the pregnancy a normal diet, containing 1.1% of calcium, or a calcium-deficient one, containing 0.2% of calcium. Animals of the 2 groups were injected intra-peritoneally with 15 or 35 mg of lead acetate/kg at different times of the fetal organogenesis (8th, 9th, 10th or 12th day of the pregnancy). In the normal diet group, injection of lead increases the postimplantation mortality and the rate of skeletal anomalies among the fetuses. The anomalies are restricted to the anterior part of the axial skeleton and consist essentially in the fusion of 2 or more cervical vertebrae. In addition, lead diminishes the blood calcium levels in the pregnant females. In the calcium deficient group, all these effects of lead are considerably increased and fetuses suffer a loss of weight and delayed ossification. In the animals given such a diet but non lead-injected, the fetal weight is already diminished. However, the ossification and the rate of skeletal anomalies are not affected, and the blood calcium levels of the mothers are similar to those of the control females given a normal diet.     

Postnatal effects of nicotine on first molar development in the CD-1 mouse

Young CD-1 mice, 4 days old, exposed to 0.1% nicotine sulfate on gestational days 6-20 were compared with untreated pups of the same age to determine its effect on the development of mandibular first molars. Pregnant mice were given intraperitoneal injections of nicotine at a dose of 1.67 mg/kg/day. Pups were then decapitated, their entire mandibles were excised, routinely prepared and embedded in paraffin, sectioned in the frontal plane and stained with hematoxylin and eosin for histological examination of developing lower first molars. The results demonstrated that the process of odontogenesis appears retarded in nicotine-treated animals while the molars of the control group revealed dentin and enamel formation. It was concluded that nicotine has a detrimental effect on molar development. Nicotine may interfere with cellular maturation of the tooth germ indicating that this effect is prenatal and extends postnatally.     

High lovastatin doses combined with hypercholesterolemic diet induce hepatic damage and are lethal to the CD-1 mouse.

The addition of 1% lovastatin (LVT) to hypercholesterolemic diets [1% cholesterol or 1% cholesterol plus 0.1% sodium deoxycholate (HD)] induced hepatic damage and was lethal to CD-1 mice in the first days of treatment; the females were more resistant than males. LVT or HD administered alone was harmless to male or female mice. After a 3-day treatment all groups that received LVT (1%, 0.1% or 0.05%) plus HD showed a higher percentage of liver weight, with respect to whole body weight. Cholesterol serum levels increased in males with HD, but remained low in female mice. In the liver, total lipids and cholesterol levels increased in male mice with HD, but cholesterol remained unchanged in females. The addition of LVT to HD prevented the increase of serum and liver cholesterol levels in male mice. These results allow us to propose the CD-1 male-mouse as a model to evaluate the toxicity of LVT or other vastatins.     

Onset of puberty in CD-1 mouse pups exposed prenatally through weaning to endophyte-infected tall fescue seed

This study was undertaken to investigate the effects of feeding endophyte - infected (Acremonium coenophialum ) tall fescue seed to CD-1 mouse dams (P(1)) during gestation and lactation, and on the subsequent growth and sexual maturity (onset of puberty) of their male and female offspring (F(1)). Forty-eight 21 d old pups (24 male and 24 female F(1) mice) were weaned from dams fed one of two diets containing 50% rodent chow (w/w) and 50% KY-31 tall fescue (Festuca arundinacea ) seed. The seed in Diet 1 was noninfected, while the seed in Diet 2 was 80% endophyte-infected. At weaning (21 d), the F(1) pups were fed rodent chow, ad libitum throughout the remaining experimental period. At 24 d, they were paired with sexually mature non-treated virgin CD-1 mice (fed 100% rodent chow) for one parturition cycle. Male F(1) mice were sacrificed at 84 d to determine testicular development. The age at the birth of the first litter for Diet 2 F(1) male (76.8 +/- 2.2 d) and female (58.4 +/- 2.1 d) was significantly greater (P<0.05) than the age at parturition for Diet 1 male and female F(1) test mice (64.1 +/- 1.8 and 51.9 +/- 1.2 d, respectively). At parturition, the female F(1) mice showed no significant differences (P>0.05) in either mean parturition weight or number of F(2) pups born per litter. However, total F(2) litter wight (11.38 +/- 1.14 g) and mean weight per F(2) pup (1.40 +/- 0.04 g) for Diet 2 female F(1) mice litters were lower (P<0.05) when compared with Diet 1 females (14.53 +/- 0.57 g and 1.66 +/- 0.02 g, respectively). No significant differences were observed between the two male F(1) treatment groups, for total F(2) litter weight or the number of pups born per F(2) litter. Although Diet 2 F(1) males weighed significantly less (P<0.05) at weaning and at pairing, final body weights at sacrifice (84 d) were not different (P>0.05) from the Diet 1 males.     

Neurobehavioural responses to hypergravity environment in the CD-1 mouse

Behavioural responses of CD-1 mice exposed to 2 g hypergravity (HG; 60 or 120 min) were investigated during adolescence and at adulthood. To characterise motion sickness (MS), pica behaviour, a reliable MS index measured through kaolin consumption, and spontaneous activity were evaluated before, during and after HG exposure. Short- and/or long-lasting effects on emotional responses, exploratory behaviour and spatial learning performances were also investigated and brain levels of nerve growth factor (NGF) and brain derived neurotrophic factor (BDNF) assessed. An increased pica behaviour during post rotational days and a reduction in spontaneous activity during rotation indicated a mild sickness associated with HG, and susceptibility to MS was sex and age related. Short- and long-lasting effects of exposure were also observed, rotated mice showing altered emotional/anxiety behavioural profiles and impaired spatial learning performances. Moreover, central NGF levels were markedly increased after rotation, while minor changes were observed in BDNF levels.     

Effects of ethanol on the primitive streak stage mouse embryo

Recent studies of mouse models have suggested that malformations associated with the fetal alcohol syndrome (FAS) are caused by the effects of ethanol on early embryos during gastrulation and neurulation. A study of Xenopus laevis embryos showed that exposure of gastrula stage amphibian embryos to ethanol inhibits migration of the mesodermal cells, causes formation of small neural plates, and subsequently causes hypoplastic craniofacial malformations in tadpoles. We now report effects of ethanol on the primitive streak stage mouse embryos. An ethanol solution (25%) was injected intraperitonealy twice into mice of 6.5-7.0 days of pregnancy at a dose of 0.015 ml/gm of body weight. Histological and morphometric examinations of 7.5-day embryos, 20 hr after the second injection, showed that the epiblast layer was disorganized and shrunk with formation of many blebs. In addition, formation of the mesodermal cell layer was retarded in the ethanol-treated embryos, suggesting that exposure of gastrula stage embryos to ethanol causes similar abnormalities in mouse and Xenopus embryos. These results suggest that the inhibition of the morphogenetic movements during gastrulation may be the primary effect of ethanol in causing major craniofacial malformations of FAS.     

Adverse effects on female development and reproduction in CD-1 mice following neonatal exposure to the phytoestrogen genistein at environmentally relevant doses

Outbred female CD-1 mice were treated with genistein (Gen), the primary phytoestrogen in soy, by s.c. injections on Neonatal Days 1-5 at doses of 0.5, 5, or 50 mg/kg per day (Gen-0.5, Gen-5, and Gen-50). The day of vaginal opening was observed in mice treated with Gen and compared with controls, and although there were some differences, they were not statistically significant. Gen-treated mice had prolonged estrous cycles with a dose- and age-related increase in severity of abnormal cycles. Females treated with Gen-0.5 or Gen-5 bred to control males at 2, 4, and 6 mo showed statistically significant decreases in the number of live pups over time with increasing dose; at 6 mo, 60% of the females in the Gen-0.5 group and 40% in the Gen-5 group delivered live pups compared with 100% of controls. Mice treated with Gen-50 did not deliver live pups. At 2 mo, >60% of the mice treated with Gen-50 were fertile as determined by uterine implantation sites, but pregnancy was not maintained; pregnancy loss was characterized by fewer, smaller implantation sites and increased reabsorptions. Mice treated with lower doses of Gen had increased numbers of corpora lutea compared with controls, while mice treated with the highest dose had decreased numbers; however, superovulation with eCG/hCG yielded similar numbers of oocytes as controls. Serum levels of progesterone, estradiol, and testosterone were similar between Gen-treated and control mice when measured before puberty and during pregnancy. In summary, neonatal treatment with Gen caused abnormal estrous cycles, altered ovarian function, early reproductive senescence, and subfertility/infertility at environmentally relevant doses.     

Effects of sodium valproate and oxygen on the CD-1 mouse fetus

This study reports the effects of valproic acid (VA) on the CD-1 mouse fetus when the drug is administered continuously via osmotic minipumps at human therapeutic drug plasma levels. Two VA-filled Alzet osmotic minipumps were implanted subcutaneously on gestation day 5 for continuous exposure of a total daily dosage of 850 mg/kg on gestation days 5-12. Dams were then exposed continuously to either normoxic (21% oxygen), hyperoxic (50% oxygen), or hypoxic (12% oxygen) controlled environments during gestation days 5-12, in order to determine if hyperoxic maternal conditions offered a protective environment for the fetus, and conversely, if hypoxia exacerbated teratogenicity. Dams were sacrificed on gestation day 18, and litter and fetal data were collected. It was determined in separate groups under normoxic conditions that the osmotic minipump system maintained VA plasma levels corresponding to human therapeutic levels. Sodium valproate was found to induce developmental toxicity in the CD-1 mouse fetus at human therapeutic drug plasma levels. Fetal weights were reduced, and the number of resorptions, deaths, and hematomas was increased. While hypoxia exacerbated the toxic effect on the fetus, hyperoxia failed to ameliorate the outcome.     

Teratogenic effects of valproic acid and diphenylhydantoin on mouse embryos in culture

Teratogenic effects of the anticonvulsant drugs valproic acid (VPA) and diphenylhydantoin (DPH) on the development of mouse embryos during early organogenesis were studied using the whole embryo culture technique. Embryos with one to seven somites were exposed in vitro to 50-375 micrograms/ml VPA or 15-135 micrograms/ml DPH for up to 42 hours and compared to control embryos cultured in 80% rat serum without either drug. For both VPA- and DPH-treated embryos, a dose-dependent increase in the frequency of abnormal embryos and a decrease in viability were found. VPA and DPH produced a similar pattern of defects. Drug-induced anomalies included open neural tubes in the cranial regions, abnormal body curvature, craniofacial deformities, and yolk sac defects. Ultrastructural changes were noted in the neuroepithelium of exencephalic VPA-treated embryos. Growth and development were retarded in embryos exposed to greater than 35 micrograms/ml DPH or greater than 50 micrograms/ml VPA as indicated by the decrease in protein and DNA content and the reduction in somite number, crown-rump length, and yolk sac diameter. On a molar basis DPH was potentially more teratogenic than VPA, which correlates with the higher lipid solubility of DPH. With VPA, susceptibility to the drug depended on the developmental stage; e.g., at 150 micrograms/ml VPA the frequency of malformations was 70% in embryos with one to four somites as compared to 35% in embryos with five to seven somites.     

Effect of maternal diabetes and ethanol interactions on embryo development in the mouse

The aim of this study was to determine the possible fetal effects of interaction between maternal diabetes and acute doses of alcohol. Pregnant TO mice were made diabetic by a single injection of streptozotocin (STZ) on gestation day (GD) 2. Single dose of 0.003 or 0.03 ml/g body weight of fresh ethanol (25% v/v of absolute alcohol in normal saline) was injected into groups of diabetic and nondiabetic animals on GD 7 or 8. One group of diabetic animals had a daily dose of 6–8 IU of insulin subcutaneously. Fetuses were collected on GD 18. There was a significant increase in the incidence of implantation failure in the diabetes plus ethanol groups and insulin control group. Ethanol injection on GD 7 accentuated diabetes-related embryonic resorption and intrauterine growth retardation (IUGR). This effect was less marked in the diabetic group treated with ethanol on GD 8. Diabetes alone produced a greater incidence of IUGR than ethanol alone. Midfacial hypoplasia and minor anomalies were found more frequently in the combination treatment groups. Holoprosencephaly and thymus hypoplasia observed in diabetic groups were found to be reduced in frequency in the diabetes plus ethanol groups, suggesting an antagonistic type of ethanol--diabetes interaction, stage-dependently. Since severely malformed embryos are known to be resorbed/killed in utero in mice, this reduction might reflect the magnitude of early death of severely malformed embryos. These data suggest that the interaction effects are possibly related to alterations in fundamental developmental processes of early embryos. (Mol Cell Biochem 261: 43–56, 2004)     

Effect of maternal diabetes and ethanol interactions on embryo development in the mouse

The aim of this study was to determine the possible fetal effects of interaction between maternal diabetes and acute doses of alcohol. Pregnant TO mice were made diabetic by a single injection of streptozotocin (STZ) on gestation day (GD) 2. Single dose of 0.003 or 0.03 ml/g body weight of fresh ethanol (25% v/v of absolute alcohol in normal saline) was injected into groups of diabetic and nondiabetic animals on GD 7 or 8. One group of diabetic animals had a daily dose of 6-8 IU of insulin subcutaneously. Fetuses were collected on GD 18. There was a significant increase in the incidence of implantation failure in the diabetes plus ethanol groups and insulin control group. Ethanol injection on GD 7 accentuated diabetes-related embryonic resorption and intrauterine growth retardation (IUGR). This effect was less marked in the diabetic group treated with ethanol on GD 8. Diabetes alone produced a greater incidence of IUGR than ethanol alone. Midfacial hypoplasia and minor anomalies were found more frequently in the combination treatment groups. Holoprosencephaly and thymus hypoplasia observed in diabetic groups were found to be reduced in frequency in the diabetes plus ethanol groups, suggesting an antagonistic type of ethanol-diabetes interaction, stage-dependently. Since severely malformed embryos are known to be resorbed/killed in utero in mice, this reduction might reflect the magnitude of early death of severely malformed embryos. These data suggest that the interaction effects are possibly related to alterations in fundamental developmental processes of early embryos.     

Teratogenic effects of maternal biotin deficiency on mouse embryos examined at midgestation

Pregnant mice were fed a basal diet that not only did not contain biotin, but also contained the spray-dried egg white including avidin that caused the biotin deficiency. The effects of maternal biotin deficiency on craniofacial and limb development in embryos were examined at two stages of midgestation. On day 12.6 of gestation, male and female embryos weighted less and digit development was retarded in the biotin-deficient group. On day 15.6 of gestation (dg), the embryos also weighted less and external malformations, such as micrognathia (94.8%), micromelia (41.4%), and exencephaly (11.4%), were observed. The inhibition of palatal and digit formation by biotin deficiency at midgestation is responsible for later formation of cleft palate and micromelia. On dg 12.6 the liver biotin level of biotin-deficient dams was reduced to 20% of control values. Interestingly, the biotin content of the whole embryonic body was about ninefold greater than liver biotin levels in their dams.