thiourea; thiocarbamide

After intraperitoneal administration of 14C-labelled thiourea the radioactivity was located preferentially in the lungs, less in the kidneys and less still in the liver. In the lung most of the radioactivity was bound to a low molecular weight protein in the 100000 × g supernatant.

It was shown in vitro and in vivo that both cyanamide and thiourea are inhibitors of thyroid peroxidase. Doses of thiourea which completely inhibit in vivo protein-bound iodine formation have no irreversible effect on thyroid peroxidase, as measured by guaiacol peroxidation after removal of the thyroids. The data suggest that the primary in vivo and in vitro mode of action of thiourea is the reversible Ioxid-trapping mechanism. The anomalous inhibition of guaiacol peroxidation seen in the presence of thiourea plus iodide derives from the formation of formamide disulfide, followed by its nonenzymic decomposition to cyanamide.

Thiourea, phenylthiourea, and methimazole perfused into rat liver stimulated the biliary efflux of GSSG without affecting the excretion of GSH into either the bile or the caval perfusate. The thiocarbamide moiety appears essential, since perfusion with urea, phenylurea, or N-methylimidazole did not stimulate GSSG release. Hydrogen peroxide is also not an obligatory intermediate, since thiocarbamide-induced GSSG efflux was undiminished in livers from selenium-deficient animals. The response was also not affected by N-benzylimidazole, a potent cytochrome P-450 inhibitor, which suggests that this monooxygenase is not involved. However, the results are consistent with a model based on S-oxygenation of thiocarbamides to formamadine sulfenates catalyzed exclusively by the flavin-containing monooxygenase. The resulting sulfenate is reduced by GSH, yielding GSSG and the parent thiocarbamide. Rapid cellular oxidation of GSH by this mechanism leads to biliary efflux of the disulfide.

In the presence of iodine or iodide and hydrogen peroxide, thiourea is oxidized by the thyroid gland peroxidase to formamidine disulfide, NH2(NH)CSSC(NH)NH2. Presumably, a thio-iodine complex is formed as an unstable intermediate [Davidson 1979]. Formamidine disulfide is also unstable: at pH values above 3.0 it decomposes forming cyanamide, elementary sulfur and thiourea. In vitro, cyanamide inhibits the peroxidation of iodide and the iodination of tyrosine. This explains the thyroid depressant action of thiourea. Autoradiographic studies of the distribution of 35S-labelled thiourea revealed a highly preferential and prolonged storage of the radioactivity in the thyroid gland [Schulman 1950]. Together with the main product, sulfate, protein-bound sulfur was detected [Maloof 1957].

The metabolism of thiourea S35 by the developing fetal rat was studied by measurement of the radioactivity in fluids and tissues, paper chromatographic analysis of the chemical state of the S35, and histologic localization of the S35 by radioautography. Rapid passage of the thiourea from the mother to the fetus occurred. In older embryos, at 12 and 24 hr after the administration of thiourea the amniotic fluid concentration was higher than that in the maternal serum. The fetal serum concentration was lower than that of the maternal serum. The fetal thyroid to fetal serum concentration ratio began increasing on the 17th day, and by the 20th day it was 9.3 as compared with 24 for the mother. The time of appearance of the concentrating ability for thiourea S35 coincides with that for I131. The S35 was predominantly present as thiourea in the serum, amniotic fluid and urine, but some protein-bound material was also found in liver tissues, serum and amniotic fluid. Both fetal and maternal thyroid tissue had increased amounts of S3S as either sulfate or thiosulfate. The radioautographs showed concentration of grains over thyroid cells and colloid at 3 hr, but after 12 and 24 hr most of the activity was over the colloid. Some concentration of S36 was observed in fetal tracheal cartilage and in the tubules of the maternal kidney

The serum levels of triiodothyronine (T3) and thyroxine (T4) were decreased and the thyroid stimulating hormone (TSH) levels were elevated in the TU and TU + VA groups, with the degree of change being significantly greater in the combined treatment group. The induction of P450 isoenzymes by TU was not enhanced by VA supplementation, but uridine diphosphate glucuronosyltransferase (UDP-GT) activity in the liver was significantly increased in the TU + VA group compared to the TU group. Thyroid weights were increased in both the TU and TU + VA groups, this being more pronounced with VA supplementation. Thyroid follicular cell hyperplasias and neoplasias were induced to similar extents in both TU treated groups, but their cell proliferation appeared to be increased by the VA supplementation.

In liver microsomes, it has been shown that flavin-containing monooxygenase (FMO) catalyses the S-oxygenation of thiourea to the reactive electrophilic formamidine sulfenic acid and formamidine sulfinic acid.

Table 1: urinary excretion of dermally applied thiourea by a female rabbit

In the present study it could be shown that water facilitates the percutaneous absorption of thiourea. The concentration of Thiourea in the urine were close to the detection limit.

Table 1: Urinary excretion of dermally applied thiourea by female rabbits

At doses of 500 mg/kg body weight the oxygen consumption decreased and the hemoglobin content increased. At doses of 250 and 125 mg/kg the oxygen consumption changed. Examination of the thyroid gland showed structural changes of the structural gland (decay of the thyroidic parenchym). At a dosis of 50 mg/kg no change in oxygen consumption and structural changes of the thyroid gland.

No weight change was detected during the 8 month obervation period. The changes observed in the thyroid gland that were provoked by thiourea dioxide were stronger than those of thiourea. Necrosis in the parenchym of the thyroid gland could be observed after treatment with thiourea dioxide and thiourea. The effects of thiourea dioxide are stronger than those observed after application of thiourea.