To develop novel nonallergenic pyrazolone analgesics, we synthesized a series of compounds in which position 1 of the pyrazolone ring was substituted in place of the original methyl group in order to block the formation of allergenic metabolites via N-dealkylation. These pyrazolone analogues were found to show as potent an antipyretic and analgesic effect as antipyrine (AT). In an examination of allergenicity, AT induced a typical skin reaction in guinea pigs, whereas the pyrazolone analogues were inactive. When AT was administered (po) to rats, norantipyrine (NORA) as an active metabolite was detected in the urine, whereas similar administration of the pyrazolone analogues did not afford NORA. We conclude that these novel pyrazolone analogues were nonallergenic because they were not converted to allergenic metabolites in vivo. Because these compounds retain the antipyretic and analgesic activities of AT, they are considered to be promising candidates for nonallergenic antipyretic analgesics.
The conversion of lignoceric acid to cerebronic acid, ceramides, cerebrosides, and glutamic acid is catalyzed by a rat brain particulate preparation. The heat-stable factor, prepared from calf cerebellum, together with the heat-labile factor, a pyridine nucleotide, and Mg2+ are essential to all of these metabolic pathways. Our previous work showed that the heat-stable factor is composed of at least two components, HSF-1 and HSF-2, and identified HSF-2 as D-glucose-6-phosphate. In the current investigation, HSF-1 was further purified and found to be N-acetyl-L-aspartic acid. In addition, it was discovered that a third component, HSF-3, is also required for heat-stable factor activity. A reconstituted system composed of N-acetylaspartic acid, glucose-6-phosphate, and HSF-3 fully replaced the heat-stable factor essential for the conversion of lignoceric acid to cerebronic acid and glutamic acid. The reconstituted heat-stable factor did not show the initial time lag always observed with the crude heat-stable factor.
1. p-Aminophenol, a minor metabolite of phenacetin, is a potent nephrotoxic agent. 2. We have examined the binding of p-aminophenol to glutathione (GSH), a model amino acid, in the presence of horseradish peroxidase, which catalyses one electron oxidation. 3. The reaction product was purified by preparative h.p.l.c., and its structure was determined by FAB mass spectrometry and 1H-n.m.r. to be a p-aminophenol-GSH conjugate. The conjugate was formed between the ortho carbon of the amino group of p-aminophenol and the SH group of GSH. 4. It was confirmed by h.p.l.c. and 1H-n.m.r. that formation of the conjugate was catalysed in vitro by rat liver microsomes and cumene hydroperoxide.
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