Benzofuranyl ureas with potent cardiovascular teratogenicity in rats

Studies of embryo-fetal development in rats were conducted with two 5-lipoxygenase inhibitors. SB-202235 (1,000 mg/kg/day) or SB-210661 (50, 100, or 500 mg/kg/day) was administered orally by gavage to female rats on days 6-17 postcoitus (pc) or days 7-16 pc. SB-202235 (1,000 mg/kg/day) and SB-210661 (100 mg/kg/day) reduced maternal body weight gain for the treatment period by 16% and 21%, respectively, relative to controls. SB-202235 (1,000 mg/kg/day) or SB-210661 (50 or 100 mg/kg/day), did not affect numbers of resorptions, dead or live fetuses/litter, but 500 mg/kg/day of SB-210661 caused 100% embryo lethality. SB-202235 (1,000 mg/kg/day) and SB-210661 (50 and 100 mg/kg/day) reduced fetal body weight by 15-30% and produced extensive cardiovascular malformations, as well as diaphragmatic hernias. SB-210661 also caused thymic abnormalities and cryptorchidism. Cardiovascular defects included abnormalities in aorticopulmonary septation, the aortic arch, pulmonary trunk, and ventricular septal defects are discussed relative to comparable human syndromes of cardiovascular malformation.     

Sensitive periods for developmental toxicity of orally administered artesunate in the rat

BACKGROUND: Artesunate has been reported to cause embryolethality and malformations when administered orally to rats during organogenesis. The purpose of this study was to determine the most sensitive period(s) for the induction of these effects in order to provide clues about possible mechanisms and to identify a short treatment regimen for further studies. METHODS: Pregnant rats were orally administered artesunate (10, 17 or 30 mg/kg/day) on single or multiple days of gestation. Cesarean sections and fetal evaluations were conducted on Day 21 postcoitum (pc). RESULTS: Embryolethality, cardiovascular malformations and a syndrome of skeletal defects were observed after single doses on days 10 to 14 pc, while no developmental effects were observed before (day 9 pc) or after (days 16 or 17 pc) that period. The most sensitive day for embryo lethality was day 11 pc, where lethality occurred with a very steep dose response (postimplantation loss was ～15% at 10 mg/kg and 100% at 17 mg/kg/day). The most sensitive day for the induction of malformations was day 10 pc. Malformations tended to occur in partially resorbed litters and included cardiovascular defects and bent and misshapen long bones and scapulae. CONCLUSIONS: The sensitive window for developmental toxicity of artesunate in the rat was identified as days 10 to 14 pc. Single oral doses produced embryolethality and similar cardiovascular and skeletal malformations as previously reported in longer term dosing experiments. These single dose treatment regimens could be useful to further investigate the mechanistic basis for artesunate‐induced developmental toxicity. Birth Defects Research (Part B) 2008. © 2008 Wiley‐Liss, Inc.     

Sensitive Windows of Skeletal Development in Rabbits Determined by Hydroxyurea Exposure at Different Times throughout Gestation

The critical periods of axial skeletal development in rats and mice have been well characterized, however the timing of skeletal development in rabbits is not as well known. It is important to have a more precise understanding of this timing of axial skeletal development in rabbits due to the common use of this species in standard nonclinical studies to assess embryo–fetal developmental toxicity. Hydroxyurea, a teratogen known to induce a variety of fetal skeletal malformations, was administered to New Zealand White rabbits as a single dose (500 mg/kg) on individual days during gestation (gestation day,GD 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, or 19) and fetal external, visceral, and skeletal morphology was examined following cesarean sections on GD 29. A wide range of fetal skeletal effects was observed following hydroxyurea treatment, with a progression of malformations from anterior to posterior structures over time, as well as from proximal to distal structures over time. The sensitive window of axial skeletal development was determined to be GD 8 to 13, while disruption of appendicular and cranio‐facial skeletal development occurred primarily from GD 11 to 16 and GD 11 to 12, respectively. The results of this study provide a better understanding of the critical developmental window for different segments of the rabbit skeleton, which will aid in the design of window studies to investigate teratogenicity in rabbits.     

Developmental toxicity of pentostatin (2'-deoxycoformycin) in rats and rabbits

The developmental toxicity of the potent adenosine deaminase (ADA) inhibitor, pentostatin (2'-deoxycoformycin), was investigated in pregnant rats and rabbits administered daily iv doses during organogenesis. Rats received 0, 0.01, 0.10, or 0.75 mg/kg on gestation days 6-15 and rabbits received 0, 0.005, 0.01, or 0.02 mg/kg on gestation days 6-18 and maternal and fetal parameters were evaluated on gestation day 21 (rats) or 30 (rabbits). Live fetuses were examined for external, visceral, and skeletal malformations and variations. In rats, maternal body weight gain and food consumption were significantly suppressed at doses of 0.10 and 0.75 mg/kg during the treatment period but returned to control levels during posttreatment. Increased postimplantation loss and decreased numbers of live fetuses, litter size, and fetal body weight were observed at 0.75 mg/kg. A statistically significant increase in the incidence of vertebral malformations occurred at 0.75 mg/kg. The incidence of certain skeletal variations (extra presacral vertebrae, extra ribs, hypoplastic vertebrae) was also increased at 0.75 mg/kg. Ossification of cervical centra was reduced at 0.75 mg/kg compared with controls. In rabbits, marked maternal toxicity (death, body weight loss, and decreased food consumption) and reproductive toxicity (abortion and premature delivery) occurred in all pentostatin-treated groups. However, there were no significant effects on number of live fetuses, pre- or postimplantation loss, litter size, or fetal body weights in the animals with live litters. There was also no apparent increase in the incidence of malformations or variations in the live fetuses of pentostatin-treated rabbits. Thus, these studies demonstrate developmental toxicity of pentostatin in rats and rabbits, and teratogenicity in rats, at maternally toxic doses.     

Susceptible period of nitrous oxide teratogenicity in Sprague-Dawley rats

The susceptible period of nitrous oxide (N2O) teratogenicity was studied in 170 Sprague-Dawley rats. Seven groups of 20 timed-pregnant rats were exposed to 60% N2O for 24 hours on each of days 6-12 of gestation; a control group of 30 timed-pregnant rats was exposed to air on day 9. On day 20 of gestation, dams were killed and reproductive indices were determined; their fetuses were subsequently examined for external, skeletal, and visceral abnormalities. There were no differences among the groups in the number of implantations and live fetuses, mean fetal weight, and sex ratio. The incidence of fetal wastage was higher than control in N2O-treated groups exposed on days 8 and 11 of gestation. Skeletal malformations of the ribs and vertebrae were increased following exposure on day 9 of gestation. However, the specific minor anomaly, cervical rib, was increased only following exposure on day 8 of gestation. The incidences of right-sided aortic arch and left-sided umbilical artery, abnormalities indicative of altered laterality, were increased following exposure on day 8 of gestation. Nitrous oxide administration during organogenesis causes several reproductive defects by mechanisms which remain to be determined.     

Teratogenic effects of nigericin, a carboxylic ionophore

Nigericin (Na+ salt) was given intraperitoneally at doses of 5.0 or 7.0 mg/kg on one of gestation days 7-12 to pregnant CD-1 mice. Additional mice were injected ip with 2.5 mg/kg on day 11 or 12 only. Injections on single gestation days reduced fetal growth and increased prenatal deaths. Additional signs of toxicity to the conceptus included treatment-related extra ribs and delayed ossification. Treatment was also associated with gross and skeletal malformations, such as median facial cleft, exencephaly, encephalocele, fused ribs, and anomalous vertebrae and exoccipitals. With the possible exception of the 5.0 mg/kg dose given on gestation day 8, nigericin doses associated with gross or skeletal malformations also resulted in observable maternal toxicity.     

Malformations in rat fetuses induced by trypan blue

Malformations of fetuses obtained from Wistar rat dams treated with trypan blue during gestation were studied. Fetuses were examined on day 20 of gestation. One hundred and twenty-seven fetuses showed abnormalities of the external features, skeleton and internal organs, separately or in combination. External malformations were found in 108 fetuses. The most frequent external malformation was anomaly of tail. Spina bifida, club foot, exencephaly and anal atresia were also observed frequently. Skeletal malformations were detected in 48 fetuses. Deformity of vertebrae in the lumbar, sacral and/or caudal regions was found in 46 fetuses. Internal malformations were observed in 27 fetuses. Anomaly of heart and/or great vessels, hydrocephaly and micro- or anophthalmia were observed frequently. About 90% of the fetuses with skeletal malformations also showed some external malformations. In contrast, about 48% of the fetuses with internal malformations also had some external malformations. These results suggest that, for teratological study, internal examination is more important in detecting malformations of fetuses than skeletal examination.     

Artesunate-induced depletion of embryonic erythroblasts precedes embryolethality and teratogenicity in vivo

BACKGROUND: Artesunate (ART), an artemisinin antimalarial, is embryolethal and teratogenic in rats, with the most sensitive days being 10 and 11 postcoitum (pc), respectively (Clark et al.: Birth Defects Res B 71:380-394, 2004; White et al.: Birth Defects Res A 70:265, 2004). METHODS: In this study, pregnant rats were administered a single oral dose of 17 mg/kg ART on Days 10-11 pc and conceptuses were evaluated through Day 14 pc. RESULTS: Paling of visceral yolk sacs was observed within 3-6 hr after treatment. Within 24 hr, marked paling and embryonic erythroblast depletion were observed macroscopically, which preceded malformations and embryo death, and persisted through Day 14 pc. Histologically, embryonic erythroblasts were reduced and cells showed signs of necrosis within 24 hr, were maximally depleted by 48 hr, and had partially rebounded within 3-4 days after treatment (Days 13 and 14 pc). Iron accumulation was evident in treated erythroblasts as early as 6 hr after treatment, suggesting impairment of heme synthesis. Heart abnormalities (swollen or collapsed chambers) were observed within 24 hr in approximately 25-60% of embryos and within 48 hr in 100% of embryos, correlating with histologic signs of cardiac myopathy (thinned and underdeveloped heart walls and enlarged chambers). Delays in limb and tail development occurred by Day 13 pc. Embryos were viable through Day 13 pc, but approximately 77% of embryos had died by Day 14 pc, presumably due to hypoxia and/or cardiac abnormalities. CONCLUSIONS: In summary, embryonic erythroblasts are the primary target of ART toxicity in the rat embryo after in vivo treatment, preceding embryolethality and malformations.     

Axial skeletal malformations induced by acetazolamide in rabbits.

In order to evaluate the teratogenic potential of acetazolamide in rabbits, three groups of 18 artificially inseminated females were treated orally with 50, 100, or 150 mg/kg/day of acetazolamide on days 6-18 of gestation. These doses induced maternal acidosis and electrolyte changes, consistent with those reported in rats and considered to be a result of carbonic anhydrase inhibition, as well as reductions in maternal body weight gain. At cesarean sections, average fetal body weights in the acetazolamide groups were dose-dependently decreased compared with controls. There were no effects of acetazolamide on embryonic survival or external morphology of live fetuses. In the fetal skeletal examination, thoracic and lumbar vertebral malformations occurred in 0.7%, 3.9%, and 6.1% of fetuses in the 50, 100, and 150 mg/kg/day groups, respectively, compared with none in the control group. In addition, missing vertebra was seen in a small number of fetuses in the 100 and 150 mg/kg/day groups. These axial skeletal malformations were, in some cases, associated with costal malformations. These results indicate that acetazolamide at maternotoxic doses can produce axial skeletal malformations in the rabbit.     

Stage-specific skeletal and visceral defects of the I(Kr)-blocker almokalant: further evidence for teratogenicity via a hypoxia-related mechanism.

BACKGROUND: As a class effect, potent I(Kr)-blockers have been shown to induce stage-specific external malformations. The aim of this study was to investigate whether I(Kr)-blockers also induce stage-specific visceral and skeletal defects and to further elucidate a proposed arrhythmia-hypoxia hypothesis. METHODS: Single oral doses of the selective I(Kr)-blocker almokalant (ALM) 25-150 micromol/kg, 7-14 dams/group, were given to Sprague-Dawley rats on gestation days (GD) 10-14, and the fetuses were examined for malformations on GD 21. One group was pretreated with the spin-trapping agent, alpha-phenyl-N-t-butylnitrone (PBN), given intraperitoneally 1 hr before ALM on GD 11. RESULTS: Cardiac ventricular septum defects and vascular malformations were observed after dosing on GD 10-11 and, to a lesser degree, on GD 12-13. Urogenital defects, absence/malposition of the postcaval lung lobe, and attenuated diaphragm were observed mainly on GD 10-11. Skeletal examination showed a high incidence of vertebral abnormalities on thoracic level on GD 10, on lower thoracic to caudal level on GD 11, and sternebral defects were observed all days. On GD 13 brachy-, oligo-, and syndactyly of the forepaw were induced, and of the hindpaw on GD 14. PBN reduced the incidence of both visceral and skeletal defects. CONCLUSIONS: The stage specificity of observed visceral and skeletal defects correlates well with what has been reported in the literature after temporary interruption of oxygen supply during the same stages of development. The protective effect by PBN present further evidence that the teratogenicity of potent I(Kr)-blockers is related to induction of hypoxia- reoxygenation injury due to embryonic cardiac arrhythmia.     

Teratogenicity of zinc deficiency in the rat: study of the fetal skeleton

Zinc deficiency (ZD) is teratogenic in rats, and fetal skeletal defects are prominent. This study identifies fetal skeletal malformations that affect calcified and non-calcified bone tissue as a result of gestational zinc deficiency in rats, and it assesses the effect of maternal ZD in fetal bone calcification. Pregnant Sprague-Dawley rats (180-250 g) were fed 1) a control diet (76.4 micrograms Zn/g diet) ad libitum (group C), 2) a zinc-deficient diet (0 microgram/g) ad libitum (group ZD), or 3) the control diet pair-fed to the ZD rats (group PF). On day 21 of gestation, laparotomies were performed. Fetuses were weighed, examined for external malformations, and stained in toto with a double-staining technique for the study of skeletal malformations. Maternal and fetal tissues were used for Zn, Mg, Ca, and P determinations. Gross external malformations were present in 97% of the ZD fetuses. No external malformations were found in fetuses from groups C and PF. Ninety-one percent of cleared ZD fetuses had multiple skeletal malformations, whereas only 3% of the fetuses of group PF had skeletal defects; no skeletal malformations were found in fetuses from group C. Some of the skeletal malformations described in the ZD fetuses, mainly affecting non-calcified bone, were not mentioned in previous reports, thus stressing the importance of using double-staining techniques. Examination of stained fetuses and counting of ossification centers revealed important calcification defects in ZD fetuses. These effects were confirmed by lower Ca and P concentrations in fetal bone with alteration of the Ca:P ratio.     

Asymmetry of skeletal effects of Dominant hemimelia

BACKGROUND: Dominant hemimelia (Dh) is a dominant mutation that arose spontaneously in mice; Dh animals exhibit reduced numbers of lumbar vertebrae and preaxial hindlimb defects. Absence of spleen occurs in both Dh/+ and Dh/Dh animals. This study was undertaken to characterize asymmetry of skeletal defects in the Dh mouse, specifically hindlimb asymmetries in association with axial defects. METHODS: A total of 29 Dh/+ and 100 +/+ fetuses (gestational day [GD] 18) were identified by phenotype and linked DNA and their skeletons were analyzed. RESULTS: The results revealed an asymmetry of hindlimb skeletal defects in Dh/+ animals. In +/+ fetuses, the left and right tibia were symmetrical with 99.0% of the animals possessing 6 lumbar vertebrae. However, Dh/+ fetuses showed asymmetry in length of left and right tibia and a reduction to 5 lumbar vertebrae in 86.2% of animals. There was a range from mild to severe asymmetry as evidenced by direct comparison of the length of the left to the right tibia of each animal. Tibial shortening was greater on the left than the right in 65.5% of Dh/+ fetuses; only 20.7% had symmetrical tibia. Oligodactyly, defined as absence of the first or second toe, was similarly more frequent on the left. CONCLUSIONS: Asymmetry is characteristic of many human limb malformations, although analysis of the molecular basis is difficult. Therefore, Dh/+ mice, which exhibit reduced numbers of lumbar vertebrae, asymmetric hindlimb defects, and complete absence of spleen, provide an important model for studying the relationship between axial patterning and asymmetric skeletal defects.     

Assessment of adult skeletons to detect prenatal exposure to acetazolamide in mice

A skeletal variant assay system (SVAS) consisting of a group of 88 spontaneously occurring qualitative variations of the adult mouse skeleton was applied to CD-1 animals that had been exposed in utero to 0, 200, or 1,000 mg/kg/day of the sodium salt of acetazolamide dissolved in distilled water, presented by SC injection of the dam during day 8 or days 9-11 of gestation. Two separate series of experiments were performed, and skeletons were examined at postnatal 62 +/- 2 days. Variation occurred in 62 and 67 characters in the two series. Frequencies of occurrence differed from untreated (UNTD) and vehicle-treated (VEH) values of substantial numbers of variants in a dose related manner for both series in both treatment regimes as did the number of variants which showed significantly different frequencies (P less than .01) in comparisons of experimental with either UNTD or VEH. At the high doses 12 and 16 variants occurred with significantly different frequencies from UNTD in day 8 treatments in the two series, and 15 and 19 variants differed in the days 9-11 treated group. Contrasting high-dose animals with appropriate vehicle controls revealed differences in 13 and 12 variants in day 8 treatment groups and in 18 and 15 variants in days 9-11 groups. Agreement between the two series was good, especially in the D9-11 treatments. Several variants differed significantly from both UNTD and VEH in both series of experiments. Among these were a number which appeared more or less specific to acetazolamide exposure. They include: day 8 treatments--accessory parietal, frontal extension, and 27 presacral vertebrae; day 9-11 treatments--sacral fusions in dorsal processes and vertebral bodies, and caudal fusions and malformations; both sets of treatments--lumbar fusions, and fusions of the transverse processes of the sacral vertebrae. Other importantly affected variants, also seen in exposure to other compounds include: day 8 treatments--abnormal metoptic roots; day 9-11 treatments--accessory mental foramen, foramina transversaria imperfecta of the atlas, arch foramen of the fifth cervical (C) vertebra, malformed sternebrae, fossa olecrani perforata, and fewer than 30 caudal vertebrae; both treatment regimes--parted frontals, accessory transverse foramina in C3-C6, reduced articular processes on the thoracic vertebrae, and 14 ribs. By all criteria applied, the SVAS is able to detect prenatal exposure to acetazolamide in adult skeletons even in the absence of any gross morphological abnormalities.     

Possible mechanism of congenital malformations induced by exposure of mouse preimplantation embryos to mitomycin C

ICR mice were treated intraperitoneally with mitomycin C at 5 mg/kg on day 3 of gestation. On day 18 of gestation, fetuses of treated dams were inspected for external, skeletal and visceral malformations. At 6 or 12 hr after mitomycin C treatment, the blastocysts were obtained from the uteri of treated dams and the degenerated cells within inner cell mass (ICM) and trophectoderm (TE) tissues were examined microscopically. On day 5, 8, 11, or 18 of gestation, the uteri of treated dams were obtained and those including embryos/fetuses and placentae were examined histologically. Finally, on each of gestational days 5-14, the blood of the treated dams was collected and the hematological parameters determined. Pre- and postimplantation losses in the dams treated with mitomycin C were significantly increased; increased frequency of abdominal wall defects and lumbar ribs in term fetuses, decreased fetal weight, and increased placental weight were noted as well. No significant increase in visceral malformations was found in term fetuses treated with mitomycin C. Frequency of degenerated cells within ICM and TE of blastocysts from dams treated with mitomycin C was significantly increased as compared with the controls. In dams treated with mitomycin C, decidua developed insufficiently and the trophoblast giant cell layer was not separated from the uterine lumen by maternal components; hemorrhage from the denuded trophoblast giant cell layer into the uterine lumen was noted. The number of erythrocytes, as well as hemoglobin concentration, hematocrit, and the percentage of reticulocytes in blood of dams treated with mitomycin C were significantly lower from days 6-12 of gestation, as compared with controls. The results of the present study showed that an increase in number of degenerated cells within blastocysts results in preimplantation loss and both maternal and embryonic hypoxia during major organogenesis results in postimplantation loss and congenital fetal malformations.     

Methanol exposure during gastrulation causes holoprosencephaly, facial dysgenesis, and cervical vertebral malformations in C57BL/6J mice

BACKGROUND: Exposure of pregnant outbred CD-1 mice to methanol during the period of gastrulation results in exencephaly, cleft palate, and cervical vertebra malformations [Rogers and Mole, Teratology 55: 364, 1997], while inbred C57BL/6J mice are sensitive to the teratogenicity of ethanol. C57BL/6J fetuses exhibit the holoprosencephaly spectrum of malformations after maternal exposure to ethanol during gastrulation, but the sensitivity of C57BL/6J mice to methanol-induced teratogenesis has not been previously described. METHODS: Pregnant C57BL/6J mice were administered two i.p. injections totaling 3.4 or 4.9 g/kg methanol or distilled water four hrs apart on gestation day 'GD' 7. On GD 17, litters were examined for numbers of live, dead and resorbed conceptuses, fetuses were weighed as a litter and examined externally, and all fetuses were double stained for skeletal analysis. RESULTS: No maternal intoxication was apparent, but the high dosage level caused a transient deficit in maternal weight gain. The number of live fetuses per litter was reduced at both dosages of methanol, and fetal weight was lower in the high dosage group. Craniofacial defects were observed in 55.8% of fetuses in the low dosage group and 91.0% of fetuses in the high dosage group, including micro/anophthalmia, holoprosencephaly, facial clefts and gross facial angenesis. Skeletal malformations, particularly of the cervical vertebrae, were observed at both dosages of methanol, and were similar to those previously reported in the CD-1 mouse following methanol exposure. CONCLUSIONS: The types of craniofacial malformations induced in the C57BL/6J mouse by methanol indicate that methanol and ethanol have common targets and may have common modes of action.     

Cardiopathic effects of dichloroacetate in the fetal Long-Evans rat.

Dichloroacetic acid (DCA) is a by-product of the chlorine disinfection of water and may occur in treated water at levels exceeding 100 micrograms/L. Previous studies revealed teratogenic effects, particularly heart malformations, at high doses (900-2,400 mg/kg given on days 6-15 of pregnancy). In a series of three studies, groups of 7-10 Long-Evans rats were dosed with 1,900 mg/kg of DCA on days 6-8, 9-11, or 12-15; with 2,400 mg/kg on days 10, 11, 12, or 13; and with 3,500 mg/kg on days 9, 10, 11, 12, or 13, in an attempt to determine the most sensitive period and further characterize the heart defect. In a fourth study, six dams were treated with 1,900 mg/kg of DCA days 6-15 of pregnancy, and 56 fetuses were harvested for light microscopy of the heart. Eight control fetuses from four litters were also examined. No heart malformations were seen in the groups treated with 1,900 mg/kg DCA days 6-8 but were present in the group treated on days 9-11 and 12-15, with the higher incidence occurring on days 12-15. Single doses of 2,400 mg/kg DCA given on days 10, 11, 12, or 13 resulted in a much lower incidence of cardiac malformations, which occurred only on days 10 and 12. The high dose of DCA (3,500 mg/kg) did not increase the incidence of heart defects but showed that dosing on day 9 as well as on days 10 and 12 would produce the defect. The defects seen were characterized as high interventricular septal defects (H-IVSD). Light microscopy showed that the defect was caudal to the semilunar valves, with the anterior right wall of the aorta communicating with the right ventricle. Another aspect of the defect is at the level of the semilunar valves, with the right cusp or sinus of Valsalva in communication with the right ventricle. The defects are discussed more fully and methods for further study suggested.     

Effects of boric acid on axial skeletal development in rats

Prenatal exposure to elevated levels of boric acid (BA) causes reduced incidences of supernumerary ribs and shortening/absence of the 13th rib in multiple laboratory species. To explore this further, Sprague-Dawley rats received 500 mg/kg b.i.d. on gestation days (gd) 5–9, 6–9, 6–10, or on single days between gd 6 and 11 (plug day = gd 0); gd-21 fetuses were stained for skeletal examination. Following multiday exposures, malformations of the axial skeleton involved the head, sternum, ribs, and vertebrae. Shortening/absence of the 13th rib was seen particularly in the gd 5–9 and 6–10 exposure groups. Although most groups exposed on single days were generally unaffected, about 90% of the gd-9 exposed fetuses had only six cervical vertebrae; the deficient region was usually C3-C5. In contrast, gd-10 treatment caused agenesis of a thoracic/lumbar vertebra in over 60% of the fetuses; the deficient region was usually T11. For 13-ribbed fetuses, the length of rib 13 was shortened compared to controls. Postnatal assessment suggested increased mortality for gd-10 exposed pups. Embryos in culture showed reduced development when exposed to BA for 48 h. These findings demonstrate the critical periods for axial development in the rat and provide an experimental model for the study of homeotic shifts. The information in this document has been funded wholly by the US Environmental Protection Agency. It has been subjected to review by the National Health and Environmental Effects Research Laboratory and approved for publication. Approval does not signify that the contents reflect the views of the Agency, nor does mention of trade names or commercial products constitute endorsement or recommendation for use.     

A reproductive screening test of goldenseal

BACKGROUND: Goldenseal (Hydrastis canadensis L) is a multi-purpose herb (Hobbs, 1990: Pharm Hist 32:79-82) widely used for its antibiotic properties. It is traditionally contraindicated in pregnancy based on in vivo data but this contraindication has not been confirmed by conventional studies that have been peer reviewed. METHODS: Female rats were dosed by gavage using 65 times the human dose of goldenseal daily on either gestation days (GD) 1-8 or GD 8-15. Controls received an equivalent dose of ethanol. On GD 20, fetuses were weighed and examined for signs of external, internal, or skeletal malformations. Rat fetuses were also explanted on GD 10.5 and cultured with decreasing concentrations of goldenseal for 26 hr. Embryos were examined for growth retardation and malformations. RESULTS: There was no increase in pre- or post-implantation losses. There was no increase in fetal body weight in fetuses exposed to goldenseal. There was no difference in incidence of external or internal malformations. Goldenseal induced toxicity when GD10.5 embryos were cultured for 26 hr in rat serum to which extract was added. CONCLUSIONS: It is likely that poor absorption of goldenseal from the small intestine could explain the discrepancy between the in vivo and in vitro results. It is unlikely that serum concentration from oral treatment could attain the LOEL achieved in vitro. The contrasting results highlight the continuing importance of in vivo work and the necessity of pharmacokinetic data when interpreting in vitro data. The data suggest that goldenseal, at the prescribed human dose, is unlikely to be absorbed to an extent to be unsafe to use in pregnancy despite the apparent cytotoxic effects in vitro. However, these results indicate that pharmacokinetic studies are required to confirm this conclusion.