ascorbic-acid and 4-chloroaniline

Irradiation with u.v. light of aerobic aqueous media containing both rabbit liver microsomal fraction and 4-chloroaniline results in N-oxidation of the arylamine. The reaction is severely blocked by exhaustive extraction with organic solvents of the microsomal membranes to remove lipids. Further, scavengers of OH. and O2.-impair the photochemical process. These findings suggest that the observed phenomenon may be closely associated with light-induced lipid peroxidation. Indeed, N-oxidation of 4-chloroaniline is fully preserved when either phospholipid liposomes or dispersed linoleic acid substitute for intact microsomal fraction. Co-oxidation of the amine substrate occurs during iron/ascorbate-promoted lipid peroxidation also, but H2O2 or free OH. radicals do not appear to be involved. Cumene hydroperoxide-sustained rabbit liver microsomal turnover of the amine generates N-oxy product via O2-dependent and -independent pathways; propagation of lipid peroxidation is presumed to govern the former route. Lipid hydroperoxides, either exogenously added to rabbit liver microsomal suspensions or enzymically formed from arachidonic acid in ram seminal-vesicle microsomal preparations, support N-oxidation of 4-chloroaniline. The significance, in arylamine activation, of lipid peroxidation in certain extrahepatic tissues exhibiting but low mono-oxygenase activity is discussed.

Topics: Aniline Compounds; Animals; Ascorbic Acid; Benzene Derivatives; Female; In Vitro Techniques; Light; Lipid Metabolism; Lipid Peroxides; Liposomes; Male; Microsomes, Liver; Oxidation-Reduction; Rabbits

The influences of methylene blue (MB), thionine, ascorbic acid (ASA), sodium thiosulfate (STS), N-(2-mercaptopropionyl)-glycine (MPG) and reduced glutathione (GSH) on methemoglobin-(MHb)-emia and sulf-hemoglobin (SHb)-emia induced by 4-chloroaniline (4-Cl-A) i.p. were studied. Preventive or therapeutic effect on MHb-emia and preventive effect on SHb-emia in mice: MHb formation was inhibited by MB i.p. whether it was administered simultaneously with or after 4-Cl-A, but SHb formation was increased. Similar effects were seen with thionine. Both compounds proved to have MHb and SHb forming activities. STS or MPG, if administered i.p. simultaneously with 4-Cl-A, inhibited formation of MHb, but exerted no effect on delayed SHb formation. However, if administered i.p. or i.v. 120 minutes after 4-Cl-A when the peak of MHb formation had passed, there was a preventive effect on delayed SHb formation. GSH inhibited MHb formation and prevented SHb formation only when it was administered i.v. 120 minutes after 4-Cl-A. ASA did not inhibit MHb formation when it was administered either i.p. or i.v., but showed a preventive effect on SHb formation, if administered 120 minutes after 4-Cl-A. Combined i.v. administration of the corresponding doses to the clinical ones of MB and ASA 120 minutes after 4-Cl-A showed a therapeutic effect on MHb-emia and a preventive effect on SHb-emia. However, at higher dose levels, MB masked the preventive effect of ASA on SHb-emia. Therapeutic effect on SHb-emia in mice and rats: None of MB, STS, GSH and ASA proved to have any therapeutic effects for established SHb-emia. On the basis of these results, significance of clinical usage of drugs in the treatment of chemically induced MHb-emia and SHb-emia is discussed.

Topics: Aniline Compounds; Animals; Ascorbic Acid; Ergothioneine; Glutathione; Male; Methemoglobinemia; Methylene Blue; Mice; Rats; Sulfhemoglobinemia; Thiosulfates; Tiopronin