Animal evaluation of technetium-99m triamide mercaptide complexes as potential renal imaging agents.

Technetium-99m mercaptoacetylglycylglycylglycine (MAG3), a [99mTc]triamide mercaptide (N3S) compound has been synthesized in an attempt to obviate the stereochemistry problems associated with the diamide dimercaptide (N2S2) ligands. Because initial studies have been promising, the terminal glycine on the MAG3 compound has been varied to create a new series of N3S compounds. Twelve new N3S complexes were initially screened in mice and the more promising complexes, 99mTc mercaptoacetylgylcylglycyl-glycine [( 99mTc]MAG3), 99mTc mercaptoacetylgylcylglycyl-L-alanine [( 99mTc]MAG2-Ala), and both complexes of 99mTc mercaptoeacetylglycylglycyl-L-asparagine [( 99mTc]MAG2-Asn) and 99mTc mercaptoacetylglycylglycyl-L-glutamine [( 99mTc]MAG2-Gln), were further evaluated in rats utilizing constant infusion blood clearances, extraction efficiencies and protein binding assays. The renal excretion of all these complexes compared favorably with simultaneously administered [131I]OIH and [125I]iothalamate. The triamide mercaptide complexes represent a new ligand class for 99mTc, which may provide a variety of complexes for the evaluation of renal tubular function.

Formation of dimethyl selenide and trimethylselenonium from selenobetaine in the rat.

The 24-h respiratory excretion of dimethyl selenide (DMSe) and urinary excretion of trimethylselenonium (TMSe) were studied in adult male rats injected with 2 mg Se/kg as selenobetaine [(CH3)2Se+CH2COOH] or its methyl ester, labeled with 75Se and 14C. The DMSe was trapped by means of 20% benzyl chloride in xylene. TMSe was measured by cation exchange high performance liquid chromatography. There was extensive respiratory excretion of DMSe from selenobetaine methyl ester (about 50% of the dose) and from selenobetaine (about 25%). About 12% of the dose was converted to TMSe for both compounds. When the Se-methyl carbons were labeled with 14C and the selenium with 75Se, doubly labeled DMSe and TMSe were formed; the 14C/75Se ratio in DMSe formed from selenobetaine methyl ester was almost unchanged from that administered, and the ratio in TMSe was only slightly lower than in DMSe. In contrast to its ester, doubly labeled selenobetaine yielded DMSe having a lower 14C/75Se ratio (approximately one-half of that administered) and a further decrease was observed between DMSe and TMSe. These data indicate that the (CH3)2Se moiety in selenobetaine methyl ester undergoes facile release to form DMSe, which is directly methylated to form TMSe. Selenobetaine, however, appears to lose a methyl group prior to scission of the Se-CH2COOH bond. The results with selenobetaine also suggest that TMSe generated metabolically is not inert, and can undergo demethylation followed by remethylation; confirmatory evidence for this metabolic instability is provided by the exhalation of [75Se]DMSe after the direct administration of [75Se]TMSe. When [75Se]selenobetaine or its ester was given with the methylene carbon in the acetic acid moiety labeled with 14C, only 75Se was present in the DMSe and TMSe, indicating that TMSe did not arise by decarboxylation of selenobetaine. It is concluded that both selenobetaine and its methyl ester are readily converted to DMSe and TMSe by pathways that do not involve decarboxylation or the formation of hydrogen selenide as an intermediate, and DMSe is a direct precursor of TMSe.

Biochemistry of metalocenes. The organ distribution of hydroxyacetyl [103Ru]ruthenocene and its glucuronide in mice.

Hydroxyacetyl [103Ru]ruthenocene and its o-glucuronide were prepared in vitro by incubation of acetyl [103Ru]ruthenocene with rat-liver homogenate, NADPH, and UDP-glucuronate. The factors affecting hydroxylation and glucuronidation in vitro were optimized for acetylruthenocene. Hydroxyacetyl [103Ru]ruthenocene glucuronide showed no affinity for the adrenal glands, but after i.v. administration of hy droxyacetyl [103Ru]ruthenocene there was a distinct accumulation of Ru-103 in adrenals, similar to that found after administration of acetyl [103Ru]ruthenocene.

Dimethylselenide and dimethyltelluride formation by a strain of Penicillium.

A strain of Penicillium which produced dimethylselenide from inorganic selenium compounds was isolated from raw sewage. Sulfate and methionine enhanced growth of the fungus and its production of dimethylselenide in media containing selenite. In solutions containing selenate, methionine inhibited dimethylselenide formation while stimulating proliferation of the fungus. Dimethylselenide was also generated from inorganic selenide. Alkylation did not appear to be a significant mechanism of selenium detoxication by this organism. Dimethyltelluride was also produced by the organism from several tellurium compounds, but this product was synthesized only in the presence of both tellurium and selenium. The yields of dimethylselenide and dimethyltelluride varied with the relative concentrations of selenium and tellurium in the medium.

Osmiophilic polymer generation: catalysis by transition metal compounds in ultrastructural cytochemistry.

A transition metal compound that is bound in tissues by any appropriate cytochemical reaction may catalyze the generation of an insoluble osmiophilic polymer from organic monomers such as 3,3'-diaminobenzidine. When the polymers are treated with osmium tetroxide, electron-opaque, insoluble osmium blacks (coordination polymers of osmium) are formed at the sites of the particular macromolecule or enzyme permitting its light, and electron, microscopic localization. This approach represents a distinct advantage over earlier cytochemical methods because the shorter incubation time needed here results in less artifactual deposition of metal ions, and less tendency to crystallize the reaction product. In addition, the shorter incubation times permit longer fixation of tissues and hence less artifact due to enzyme diffusion.