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

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

Localization of artesunate and its derivatives in the pregnant rat and fetus following oral administration and relationship to developmental toxicity

BACKGROUND: The antimalarial drug artesunate affects erythroid cells leading to developmental toxicity and adult reticulocytopenia. We report on a kinetic study in rats and the tissue distribution of radioactivity following oral administration of [³H]‐artesunate to pregnant rats using quantitative whole‐body autoradiography (QWBA). METHODS: Rats were dosed orally with chlorproguanil/dapsone/artesunate (including 11.8 mg/kg artesunate) and plasma concentrations of artesunate and the active metabolite dihydroartemisinin (DHA) were determined. In the QWBA study, 6 rats received 13 mg/kg [³H]‐artesunate on day 18 of gestation. Groups of 2 rats were euthanized at 1, 6, and 24 hours after dosing, rapidly frozen, and sectioned in a cryostat. Sagittal sections were freeze‐dried and placed in contact with imaging plates. Tissue concentrations of radioactivity were quantified. RESULTS: Systemic exposure to DHA was up to 22‐fold higher than the parent compound and was higher in non‐pregnant females than males. In the QWBA study, high concentrations of radioactivity were seen in maternal tissues involved in absorption and excretion, the bone marrow and spleen. Fetal blood and liver levels were 3.8‐ to 8.8‐fold higher than maternal blood levels at all timepoints. CONCLUSIONS: Excluding tissues involved in absorption and excretion, the highest concentrations of radioactivity were observed in tissues involved in hemoglobin synthesis and/or destruction in both the mother and the fetus and likely account for the maternal reticulocytopenia and embryotoxicity. Radioactivity concentrations in the fetal blood were 2.1‐ to 2.8‐fold higher than maternal bone marrow at all timepoints and this difference could contribute to the lower dose threshold for embryotoxicity. Birth Defects Res (Part B) 89:364–375, 2010. © 2010 Wiley‐Liss, Inc.     

Time course of distribution to tissues of 125I-somatomedin A injected into the rat

125I-somatomedin A (SMA) was injected iv into rats. Distribution studies in rats showed concentrations of radioactivity to be high in kidney and plasma, low in brain, and intermediate in other tissues. The concentration of total and trichloracetic acid (TCA) precipitable radioactivity in rat blood and tissues fell at rapid rate. Ninety per cent of the radioactivity was in the urine in 24 hr, and only 15% of urine radioactivity was TCA precipitable. The half-life of the radioactivity in TCA-precipitable fraction from blood and that from tissues were nearly identical (about 6 hr). In both liver and kidney, TCA-precipitable radioactivity was detected in membrane and/or organellar fraction and cytosol fraction. Sephadex G-200 chromatography at neutral PHY AT NEUTRAL PH of plasma after injection of 125I-SMA revealed 3 peaks of radioactivity in higher molecular weight region than purified SMA.     

Zinc transport in rabbit tissues. Some hormonal aspects of the turnover of zinc in female reproductive organs, liver and body fluids

1. To investigate the influence of hormonal conditions upon the kinetics of zinc transport, specific radioactivity of (65)Zn was determined in certain tissues and fluids from unmated or pregnant rabbits during the first half of gestation. 2. Compartmental analysis was used to find the simplest mathematical model that simulated satisfactorily tracer behaviour. Models were fitted to experimental results by a numerical procedure using a computer. 3. The kinetics of zinc exchange in most tissues investigated could adequately be described by a three-compartment model, in which total tissue zinc content was divided into a rapidly exchanging pool, with a turnover time of about 1h, and a slowly exchanging pool, the turnover time of which was in liver 15h, in peak-stage corpus luteum 8h, and in the other tissues 30-70h. 4. In rabbit endometrium zinc transport varied with hormonal conditions, the turnover rate being higher in non-pregnant than pregnant endometrium. 5. Uptake of (65)Zn by uterine fluid was slow, and in the free-lying embryos (blastocysts) slower still, in keeping with uterine fluid acting as carrier of zinc into the unimplanted embryos. 6. In placental tissue zinc transport varied with gestational stage. Foetal placenta exchanged zinc with blood plasma four times faster than maternal placenta. In foetuses zinc turnover time and flux equalled that of the slow zinc compartment in foetal placenta. 7. Corpus luteum on days 5-6 of gestation showed peak specific radioactivity and zinc flux values, which exceeded those of all other tissues. 8. In liver the slow zinc compartment had a higher rate of turnover than corresponding compartments in tissues other than peak-stage corpus luteum, but no hormone-dependent changes were observed. 9. Zinc uptake by erythrocytes was the slowest of all examined.     

Fetal and maternal tissue distribution of the new fluoroquinolone DW-116 in pregnant rats

We investigated maternal and fetal tissue distribution of DW-116, a newly developed fluoroquinolone with a broad antibacterial spectrum against both G(+) and G(-) bacteria, in pregnant rats. After oral administration of [14C]-DW-116 (labeled 1 mg and unlabeled 500 mg/kg) to female rats on the 18th day of gestational, groups of three rats were killed at various time points up to 24 h, and plasma and tissues were collected, processed and analyzed. [14C]-DW-116 was rapidly absorbed, and distributed into the maternal and fetal tissues, and it declined in a biphasic manner with elimination half-lives (t(1/2)) of 10-15 h and mean residence times (MRT(0-24 h)) of 4-9 h. The radioactivity in most tissues of both dams and fetus reached its peak within 1 h and radioactivity levels of up to 10-25% of the peak level were maintained until 24 h after dosing. Among various tissues, the radioactivity in the maternal lungs was the highest (27 times that of plasma) at the C(max). Radioactivity in other tissues including liver, kidney, heart, lung, brain, spleen, mammary gland, placenta, ovary and uterus was higher than that in the maternal plasma (one- to three-fold). The tissue-to-plasma partition coefficient (K(p), AUC(0-24 h,tissue)/AUC(0-24 h,plasma)) of [14C]-DW-116 in maternal tissues was highest in the lung (K(p)=3.7), followed by the spleen (2.2), kidney (2.0), liver (1.8), heart (1.5), placenta (1.3), brain (1.3), ovary (1.1), uterus (1.1), and mammary gland (1.0). The tissue-to-plasma partition coefficient values in fetal tissues were heart (K(p)=2.2), kidney (2.1), liver (1.9), lung (1.6) and brain (1.4). When lactating rats were given a single oral dose of [14C]-DW-116, the radioactivity was rapidly secreted into the milk with K(p) of 1.7 at T(max) (0.5 h). These results indicate that DW-116 or its related metabolite(s) rapidly cross the blood-placenta and blood-milk barrier, extensively distribute into the fetal tissues, and are eliminated from the body in a prolonged manner. This study sheds insights into the maternal and fetal tissue distribution of DW-116 and will be useful for assessing both therapeutic and toxicological relevance of DW-116 in pregnant subjects.     

Evidence for opiate receptor binding in rat small intestine

The influence of ethanol consumption during pregnancy on maternal-fetal transfer of amino acid was studied. Pregnant rats were fed a liquid diet containing 30% ethanol-derived calories from gestation-day 6 to 21; control rats were pair-fed identical diets, except that sucrose substituted isocalorically for ethanol. On gestation-day 21, 2 uCi/100 g body weight of ¹⁴C-alpha-aminoisobutyric acid (¹⁴C-AIB) was injected into the maternal circulation, and 90 minutes later maternal blood and liver, placentas and fetuses were removed for radioactivity measurement. No differences between ethanol-fed and control rats in the distribution of ¹⁴C-AIB in maternal plasma or the uptake of ¹⁴C-AIB by the maternal liver were observed. However, the radioactivities in placenta and fetal tissues suffered a significant 20 to 40% reduction in the ethanol-fed group, suggesting that ethanol feeding during pregnancy impairs placental function.     

Oxidative metabolites of diethylstilbestrol in the fetal Syrian golden hamster

14C-Diethylstilbestrol was administered orally, intraperitoneally, and intrafetally to 15-day pregnant hamsters at a dose of 20 mg/kg body weight, and the radioactivity was determined in the fetus, placenta, and maternal liver after 6 hours. Significant amounts of radioactivity were found in these tissues in every case, indicating maternal-fetal and fetal-maternal transfer of diethylstilbestrol. Part of the radioactivity found in the tissues could not be extracted even after excessive washing. This implied the presence of reactive metabolites. In the fetal and placental extracts, eight oxidative metabolites of diethylstilbestrol were identified by mass fragmentography as hydroxy- and methoxy-derivatives of diethylstilbestrol, pseudodiethylstilbestrol, and dienestrol. The presence of oxidative metabolites in the hamster fetus and the covalent binding to tissue macromolecules are possibly associated with the fetotoxic effects of diethylstilbestrol.     

Transfer and distribution of Niobium-95 in adult,fetal, and newborn rats after injection during pregnancy

Summary Following i.v. injection of Nb-95 into pregnant rats, fetuses and newborns were dissected and measured for radioactivity after several time intervals. At any time only a small quantity of the administered radioactivity was transferred to fetus and newborn and the fetal tissue concentrations were always lower than the maternal ones. The highest ratio (0.6) between fetal and maternal tissue concentrations was found in bone.     

Absorption and fate of labelled canthaxanthin 15, 15'-3H2 in rainbow trout (Salmo gairdneri Rich.)

1. Using one force fed meal, absorption of labelled canthaxanthin 15,15'-3H2 was studied by collecting blood via caudal punction at regular intervals and measuring radioactivity in various tissues and organs of rainbow trout. 2. Canthaxanthin absorption showed a large variability between individuals irrespective of their sex. A rapid increase in the radioactivity linked to canthaxanthin 15,15'-3H2 is observed in the blood followed by a slow decrease. 3. Twenty-four and 72 hours after ingestion of labelled canthaxanthin by rainbow trout, the radioactivity was widely distributed. From the total radioactivity given, most was found 24 hours after the meal in the pyloric caeca, ovary and skin. Seventy-two hours after diet, the radioactivity increased in the muscle, liver and kidney. On the other hand, the percentage of radioactivity of intestine and caeca declined. 4. Data from absorption curve indicates that 0.86% of radioactivity ingested is present in the blood, suggesting that canthaxanthin is not readily transferred from the digestive tract. 5. The metabolic clearance of canthaxanthin (lambda = 0.0246/hr +/- 0.005) which would correspond to a half-life of 28 hours gives a preliminary idea of the digestive and metabolic utilization of canthaxanthin by the rainbow trout.     

Absorption and distribution of [1-14C]dolichol intubated into rats

[1-14C]Dolichol was mixed in vitro with sunflower seed oil and intubated into rats. Radioactivity began to appear in the blood at 3 h and peaked after about 6 h. The absorbed radioactivity was rapidly cleared from the blood. At 7.5 h postintubation two thirds of the radioactivity in the serum was associated with chylomicrons and about one quarter with the high density lipoproteins. At 12 h the proportion of the radioactivity in the chylomicrons had fallen to one third and that in the high density lipoproteins had increased to one half of the total. Less than 0.02% of the dose was found in the tissues after 12 h. Liver and blood each contained about one third of the total, with smaller amounts in the lungs and spleen. The heart, testes, brain, and kidneys contained only traces of radioactivity. After 12 h most of the radioactivity in the tissues and feces was present as [1-14C]dolichol. The radioactive compounds in the urine (about 0.05% of the dose) were more polar than [1-14C]dolichol as determined by thin-layer chromatography.     

Mechanism of dimethylsulfoxide protection against the teratogenicity of secalonic acid D in mice

Dimethylsulfoxide (DMSO) is known to antagonize the teratogenic effects of secalonic acid D (SAD) in mice. To establish the optimum protective dose of DMSO, pregnant CD-1 mice were treated, i.p., with 30 mg/kg of SAD in 5% (w/v) NaHCO3, containing 0, 10, 20, or 30% (v/v) DMSO on day 11 of gestation. Data indicate that at 10% and 20% levels, DMSO affords an apparent dose-related protection against SAD-induced cleft palate, whereas 30% DMSO enhanced fetal resorption with no reduction in the incidence of cleft palate. Ultraviolet spectra and TLC mobility indicated that DMSO at 20% did not directly interact with SAD. Distribution and elimination of 14C-SAD was studied in fetal and maternal tissues from pregnant mice at 24 and 48 hr after exposure to 30 mg/kg of 14C-SAD, i.p., in NaHCO3 (control) or in 20% DMSO. Compared with those not receiving DMSO, maternal exposure to DMSO: 1) significantly reduced (42-75%) radioactivity in fetal heads and bodies, placenta, and maternal tissues other than liver; 2) significantly increased (up to 222%) the radioactivity in maternal liver; and 3) significantly reduced (44-58%) fecal and urinary elimination of SAD-derived radioactivity. These results suggest that the antiteratogenic effect of DMSO against SAD may be at least partly mediated by increased SAD (or its metabolites) retention by maternal liver leading to reduced SAD uptake by the fetus.     

Marked accumulation of valproic acid in embryonic neuroepithelium of the mouse during early organogenesis

Valproic acid, an antiepileptic drug, causes neural tube defects in mice and man. 14C-labeled valproic acid (sodium-salt) was administered to pregnant mice on days 8 and 9 of gestation (period of high sensitivity in regard to formation of neural tube defects in this species). Two dose levels of valproic acid (1 and 400 mg/kg) were used; in each case the total radioactivity administered was the same: 400 microCi/kg or 14.7 MBq/kg. Autoradiography combined with computerized densitometry revealed that in low-dose animals most of the radioactivity was confined to maternal liver and kidney, while at high doses more activity was observed in soft tissues and fluids, including amniotic fluid. In the embryo, the neuroepithelium showed the highest concentration, irrespective of dose and survival interval (30 min, 3 h, and 6 h). Upon administration of the high dose, up to five times more radioactivity (approximately 2,000 times more valproic acid) was recovered in embryonic tissues than after the low dose. It is concluded that high doses of VPA saturate the capacities of metabolism, excretion, and protein binding in the maternal organism, resulting in a higher proportion of the dose reaching the embryo, allowing more of the drug to be accumulated by the target organ, the neuroepithelium.     

Synthesis and in vivo biodisposition of [14C]-quaternary ammonium-melphalan conjugate,a potential cartilage-targeted alkylating drug

For the purpose of developing more selective anticancer drugs that would concentrate in the malignant cartilaginous tumors (chondrosarcomas), and so improve therapeutic index through a reduction of side effects, a quaternary ammonium (QA) conjugate of melphalan was synthesized and labeled with (14)C by linking the QA moiety to nitrogen mustard via an amide bond. Comparative pharmacokinetic study of [(14)C]-melphalan and its [(14)C]-QA conjugate conducted on rats showed that the two compounds were principally excreted by the urinary way. The blood elimination of the QA conjugate was faster than that of the melphalan. In the other hand a higher rate of radioactivity derived of [(14)C]-MQA was found in feces. In the biodisposition for most organs, no striking differences were found between melphalan and its QA conjugate except for cartilages which exhibited more higher radioactivity level. Amounts of radioactivity derived from [(14)C]-QA conjugates measured in cartilaginous tissues until 1 h after injection demonstrate that the introduction of a QA moiety on melphalan allows the molecule to be carried selectively to cartilaginous tissues. As the [(14)C]-QA conjugate is radiolabeled on the chloroethyl alkylating moiety, levels of radioactivity measured in the cartilaginous tissues results from unchanged compound or metabolite having kept the active group.     

Placental barrier to atrial natriuretic peptide in rats

Transplacental passage of 125I-labelled synthetic rat atrial natriuretic peptide (ANP) was investigated in 20-day pregnant rats under pentobarbitone anesthesia. Although significant quantities of radioactivity were detected in the fetal plasma after maternal injections and in the maternal plasma after fetal injections of 125I-labelled synthetic ANP, no fraction of the placentally transferred radioactivity was due to intact ANP. Despite a rapid maternal and fetal metabolism of ANP, both maternal and fetal plasma radioactivity remained relatively stable for at least 3 h and less than 10% of the injected radioactivity was excreted in the maternal urine during a 90-min period. It is concluded that ANP is not transported in either direction across the placenta in rats.     

The dynamics of [3H]-cholesterol incorporation into the liver and aortic tissue of guinea pigs on long-term ethanol administration]

The effect of ethanol administration to guinea pigs (4 g/kg, per os) on the dynamics of [3H]-cholesterol incorporation into the liver and aorta tissues was studied for 3 months. It has been discovered that specific radioactivity of the control animals linearly increased during 24 hours in the blood serum. Ethanol reduced it as compared with the control only 0.5 h after a label has been introduced. Cholesterol renovation in the liver remained unchanged under the prolonged effect of ethanol. In the aorta the ethanol effect was characterized by a decrease of [3H]-cholesterol specific radioactivity 0.5 h after its administration. However, in this case the ratio of aorta/blood serum radioactivity increased. A day after the labelled cholesterol administration to alcoholized animals the radioactivity calculated per 1 mg of cholesterol and per unit of tissue weight and referred to the blood serum radioactivity was lower as compared to the control level.     

Reproduction in mice: The fate of spermatozoa not involved in fertilization

Mechanisms were sought through which the control of preimplantation mouse embryo development by spermatozoa might be effected. A potential route for the transmission of sperm-dependent stimuli to C3HeB/FeJ females was uncovered. It was found that within 24–48 hr after artificial insemination with spermatozoa, in which the DNA had been labeled with tritiated thymidine, a minimum of 9% of the radioactivity was transported across the uterine walls. It was deposited among the maternal tissues in a pattern that differed from the patterns of isotope distribution obtained when either free tritiated thymidine or Escherichia coli cells containing DNA labeled with tritiated thymidine were used instead of labeled sper-matozoa. In sperm-treated animals the ovaries, the adrenals, and a mesenteric lymph node exhibited strikingly large accumulations of radioactivity. The heart, spleen, and uterus manifested lesser accumulations of label, but were higher than liver, kidney, lung, brain, muscle, and intestine. The specific activity of the lymph node was found to decrease during the 12–72-hr period following insemination. This result led to the hypothesis that the lymphatic system could serve as a route for the dissemination, to maternal tissues, of radioactivity originally associated with spermatozoa deposited in the uterus. Heat-inactivated spermatozoa, which have the potential for facilitating the first cleavage of fertilized embryos, exhibited a distribution pattern indistinguishable from untreated spermatozoa. Sperm protein kinase was found to survive the heat inactivation of spermatozoa. This stability was interpreted as being compatible with the kinase functioning as an intermediary in the transmission of sperm-dependent stimuli that control preimplantation embryo development in mice.     

Intestinal absorption and metabolism of retinoyl beta-glucuronide in humans, and of 15-[14C]-retinoyl beta-glucuronide in rats of different vitamin A status

In order to prove the hypothesis that humans and animals with adequate vitamin A status do not absorb and metabolize orally administered all-trans retinoyl β-glucuronide, unlabeled retinoyl glucuronide (0.1 mmol) was orally dosed to fasting well-nourished young men. Neither retinoyl glucuronide nor retinoic acid, a possible metabolite, appeared in the blood within 12 h after ingestion. Next, radiolabeled all-trans 15-[¹⁴C]-retinoyl β-glucuronide was chemically synthesized by a new procedure, and fed orally to rats of different vitamin A status. Analysis of blood and other tissues 5 or 24 h after the dose, showed the presence of radioactivity ( 0.5%) in the blood of vitamin A deficient rats, but not in sufficient rats. Livers of all rats contained small, but detectable amounts (0.3 to 1.1% of the dose) of radioactivity. The accumulation of radioactivity in the liver was highest in deficient rats. Analysis of the retinoids showed that the radioactivity in serum and liver was due to retinoic acid formed from retinoyl glucuronide. Within 24 h after the dose, 31 to 40% of the administered radioactivity was excreted in the feces, and 2 to 4.7% of the dose was excreted in the urine. Results of the present studies show that oral administration of retinoyl β-glucuronide did not give rise to detectable changes in blood retinoyl glucuronide and/or retinoic acid concentrations in humans or rats with adequate vitamin A status.     

Embryonal disposition of salicylate: in vivo-in vitro comparisons

The distribution of salicylate to embryonal compartments for in situ and in vitro rat embryos under equivalent exposure conditions, and salicylate disposition in the in vivo mid-gestation embryo and late gestation fetus, were compared. Pregnant Sprague-Dawley CD rats were exposed to steady-state blood levels of salicylate by infusing 14C-salicylic acid iv for a 24 hour period from gestation day 11.5 to 12.5. Cultured Sprague-Dawley rat embryos (in medium consisting of 100% male rat serum) were exposed to the steady-state 14C-salicylate concentration achieved in maternal serum in vivo for the same 24 hour developmental period. At the end of the exposure period radioactivity in visceral yolk sac, extra-embryonic fluid and embryos, and in maternal tissues, was measured. The distribution of salicylate to embryonal tissues was statistically comparable in vivo and in vitro, although the embryos in vitro accumulated slightly (but not significantly) less of the chemical. There was considerable binding of salicylate by maternal serum and culture medium proteins: less than 20% of the chemical was free at the 40 micrograms/ml concentration used in this experiment. Consequently, the salicylate concentration in embryonal compartments appeared to be quite low when compared to the surrounding serum/medium, but was actually equal to or greater than the concentration of unbound salicylate in serum or culture medium. The proportion of free salicylate in serum increased at concentrations higher than 40 micrograms/ml, resulting in somewhat higher concentrations of salicylate in in vitro embryos and extraembryonic fluid (as compared to medium) when cultured in the presence of 200 or 400 micrograms/ml salicylate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Lack of maternal to fetal transfer of 125I-labelled erythropoietin in sheep.

We administered tracer quantities of biologically active 125I-labelled recombinant human erythropoietin by intravenous bolus injection to seven late gestation pregnant ewes. Maternal and fetal blood was sampled over the subsequent six hours and assayed for erythropoietin-specific radioactivity. Despite the expected increase in maternal plasma immunoprecipitable 125I-labelled erythropoietin radioactivity, fetal plasma levels remained unchanged throughout the study. In addition, erythropoietin receptors were not detected in ovine and human placental tissue. We conclude that biologically active 125I-labelled erythropoietin does not cross the placenta from mother to fetus in measurable quantities in sheep, and likely in humans. Thus, these data indicate the levels of erythropoietin measured in fetal plasma are reflective of fetal, and not maternal, erythropoietin production and elimination.     

Rapid removal to the liver of intravenously injected lipoprotein lipase.

Lipoprotein lipase was purified from bovine milk and labeled with 125I. After intravenous injection to rats the labeled lipase rapidly disappeared from the blood. The initial half-life was about 1 min and more than 70% of the radioactivity was found in the liver at 10 min. 30 min after the injection about 10% of the injected radioactivity was present in acid-soluble form in blood, indicating that the enzyme had been rapidly degraded. Injection of asialofetuin, ribonuclease B or mannan in amounts known to block the hepatic receptors for glycoproteins with exposed galactose, N-acetylglucosamine or mannose residues did not retard the removal of the lipoprotein lipase. Thus, some other, as yet undefined, receptor is implicated. Lipoprotein lipase is known to bind to heparin and some related polysacchrides. Heparin injected before the enzyme delayed its removal and heparin injected after the enzyme caused an immediate increase in blood radioactivity, signifying return from tissues to blood of labeled enzyme. Lipoprotein lipase is present at the endothelium in several extrahepatic tissues and is rapidly turned over. Its presence in blood in appreciable amounts would cause a derangement of lipid transport. The efficient hepatic removal of the enzyme may thus serve an important physiological purpose in keeping the blood levels of this enzyme low.