Difference in metabolic profile of potassium canrenoate and spironolactone in the rat: mutagenic metabolites unique to potassium canrenoate.

The metabolic fates of potassium canrenoate (PC) and spironolactone (SP) were compared for the rat in vivo and in vitro. Approximately 18% of an in vivo dose of SP was metabolized to canrenone (CAN) and related compounds in the rat. In vitro, 20-30% of SP was dethioacetylated to CAN and its metabolites by rat liver 9000 g supernatant (S9). Thus, the major route of SP metabolism is via pathways that retain the sulfur moiety in the molecule. PC was metabolized by rat hepatic S9 to 6 alpha, 7 alpha- and 6 beta, 7 beta-epoxy-CAN. The beta-epoxide was further metabolized to its 3 alpha- and 3 beta-hydroxy derivatives as well as its glutathione (GSH) conjugate. Both 3 alpha- and 3 beta-hydroxy-6 beta, 7 beta-epoxy-CAN were shown to be direct acting mutagens in the mouse lymphoma assay, whereas 6 alpha, 7 alpha- and 6 beta, 7 beta-epoxy-CAN were not. These mutagenic metabolites, their precursor epoxides and their GSH conjugates were not formed from SP under identical conditions. The above findings appear to be due to inhibition of metabolism of CAN formed from SP by SP and/or its S-containing metabolites, since the in vitro metabolism of PC by rat hepatic microsomes was appreciably reduced in the presence of SP. The hypothesized mechanism(s) for this inhibition is that SP and its S-containing metabolites specifically inhibit an isozyme of hepatic cytochrome P-450 or SP is a preferred substrate over PC/CAN for the metabolizing enzymes. Absence of the CAN epoxide pathway in the metabolism of SP provides a possible explanation for the observed differences in the toxicological profiles of the two compounds.

The analysis and source of 1-diphenylmethyl-4-nitrosopiperazine in 1-diphenylmethyl-4-[(6-methyl-2-pyridyl) methyleneamino]piperazine: a case history.

Analytical methods were developed to determine whether there was less than one ppm of II in IV. Purified IV contained a compound with the same GC retention time as authentic II on OV-17 and Silar 10C columns, using a FID or a nitrogen/phosphorus detector. The GC-coupled mass spectra contained major peaks at m/e 251 and 167 and the GC-coupled methane CI spectra gave the quasi-molecular ion, m/e 282. However, the CI selected ion monitor indicated three compounds at m/e 282. The nitrosamine II was separated from IV by HPLC on muBondapak C18. The GC-coupled mass spectra of the HPLC nitrosamine fraction had peaks at m/e 251 and 167 and other peaks for a compound of greater MW than II, although the GC retention times were the same. Evidence for II and a decrease in the detection limit to one ppm was obtained with a TEA interfaced with a HPLC. To determine if II was formed from IV, it was exposed to ozone at -78 degrees C in methylene chloride. The DSC, IR and NMR of the product were coincident with those of the standard of II. In other experiments, IV in methylene chloride was exposed to light and dry air in the presence and absence of methylene blue. The PMR and 13C NMR of the product formed in the presence of methylene blue were the same as that of II. It is postulated that this nitrosamine was formed by a singlet oxygen mechanism.

Spironolactone metabolism in man studied by gas chromatography-mass spectrometry.

Gas chromatography-mass spectrometry was used to identify metabolites of spironolactone in human blood and urine. In three healthy men about 20% of the radioactivity was excreted in the urine within 24 hr after an oral dose of [20-3H]spironolactone (200 mg + 200 muCi). About half of this radioactivity was extracted with chloroform at pH 3 and from this extract four stable metabolites were isolated by use of column and thin-layer chromatography. Two of these were the previously identified metabolites, canrenone (VII; 2.9% of dose) and the 6beta-hydroxy-sulfoxide (X; 1.8% of the dose). The remaining were the new metabolites, 15alpha-hydroxycanrenone (XI; 0.8% of dose) and the 6beta-hydroxy-thiomethyl derivatives (VI; 0.5% of dose). The principal water-soluble urinary metabolite was canrenoate ester glucuronide (XII; 4.5% of dose). In the 24- to 32-hr pooled serum, canrenone (VII) was the principal metabolite in the organic-extractable fraction; VI was present in appreciable amounts but X and XI were present at extremely low levels.