Metabolism of N'-(4-chloro-o-tolyl)-N,N-dimethylformamidine (chlorphenamidine) and 4'-chloro-o-formotoluidide by rat hepatic microsomal and soluble enzymes

The bradycardic and mydriatic effects of chlordimeform and its demethylated analogs in the rat: antagonism by idazoxan but not by prazosin

Pupillary and cardiac responses to i.v. injections of chlordimeform (CDM, 0.3-10 mg/kg), a formamidine insecticide, and its metabolites demethylchlordimeform (DCDM, 0.03-1 mg/kg) and didemethylchlordimeform (DDCDM, 0.1-3 mg/kg) were studied in rats anesthetized with pentobarbital. Both CDM and DCDM induced a dose-dependent mydriasis and bradycardia and DCDM was 10 times more potent than CDM in causing these effects. In contrast, DDCDM did not induce a mydriasis or bradycardia. The alpha 2-adrenoreceptor antagonist, idazoxan (0.2 mg/kg, i.v.) abolished or reduced CDM- and DCDM-induced mydriasis and bradycardia, whereas the alpha 1-adrenoreceptor antagonist, prazosin (1.5 mg/kg, i.v.) did not change these effects of CDM and DCDM. SKF 525-A (50 mg/kg, i.p.), an inhibitor of enzymatic demethylation, administered 10 min before the first dose of CDM, failed to reduce the effects of CDM. The results suggested: 1) the mydriatic and bradycardic effects of CDM and DCDM are mediated by alpha 2-adrenoreceptors, 2) the monodemethylation of CDM increases its alpha 2-adrenoreceptor agonistic activities, but the didemethylation of CDM abolishes these activities, and 3) CDM can exert alpha 2-adrenoreceptor agonistic activities without undergoing a demethylation process.

Hepatic microsomal N-demethylation of N-methylbenzamidine. N-dealkylation vs N-oxygenation of amidines

The microsomal oxidative N-demethylation of N-methylbenzamidine, a model compound for active substances containing the basic amidine function, was investigated. N-Methylbenzamidine was converted into benzamidine and formaldehyde by aerobic incubation with non-induced microsomal fractions of rabbit liver homogenates and NADPH. The formation of benzamidine in the incubation mixtures under widely differing conditions was assayed using a newly-developed, high-performance, ion pair, reverse-phase partition chromatographic method. Optimal reaction conditions were determined. The benzamidine formation in the incubation mixture followed Michaelis-Menten kinetics and required the presence of molecular oxygen and NADPH. The effects of the inducer phenobarbital, methylcholanthrene, ethanol and N-methylbenzamidine itself on the activity were studied. Neither superoxide anion nor hydrogen peroxide was directly involved in the demethylation reaction. The direct involvement of cytochrome P-450 in this reaction is supported by the observation that the presence of inhibitors of cytochrome P-450, in particular of carbon monoxide, markedly decreased the rate of N-demethylation. This N-demethylation of N-methylbenzamidine proves the hypothesis that benzamidines with hydrogen atoms in the alpha-position to the amidine nitrogen atoms are N-dealkylated instead of N-oxygenated by the microsomal mixed function oxidase system.

Chlorodimeform and its effect on monoamine oxidase activity in the cattle tick, Boophilus microplus

The action of the acaricide, chlorodimeform and its metabolite. N-desmethylchlorodimeform, on the activity monoamine oxidase (MAO) from the cattle tick, Boophilus microplus, were studied. Both compounds were found to be potent in vitro and in vivo inhibitors of the enzyme. However the inhibition of MAO does not seem to be related to the toxic action of the acaricide.

Metabolism of radiolabeled insecticides in insects and related arthropods: a critical study of various techniques

The metabolism of radiolabeled insecticides in insects and acarina is studied largely by coupling radiotracer techniques with analytical methods, such as TLC, paper and column chromatography, gel-permeation chromatography, and enzymatic assays. These techniques in various combinations yield both the identification and quantification of the metabolites. Other analytical methods such as gas chromatography or IR spectrometry may also be used to obtain additional support for identification of metabolites. In the absence of authentic chromatographic standards, however, NMR and mass spectrometry are necessary in the identification of the unknown compound. The quantity of the radiolabeled insecticide administered should be within the toxicological range of the insect. Therefore, the dosage-mortality response of the insect using unlabeled material should be determined. A dose should be selected that keeps insect mortality to a minimum in order to avoid complications in the computation of the balance data. The radiolabeled insecticide is usually applied topically to the insect. Alternately, the material may be administered by dipping in a solution containing the radiolabeled compound or by exposure to filter paper impregnated with radiolabeled material. Administration of the radiolabeled material by the oral route presents several problems. Sterile rearing conditions are mandatory to avoid contamination of treated diet with microorganisms. Some knowledge of the insect's feeding rhythm is desirable so that the labeled diet is given at peak feeding time. Synthetic diets should be adjusted to pH 7.0. These precautions minimize degradation of the insecticide in the diet prior to consumption by the insect. Precise doses of radiolabeled materials may be administered by injection. The technique is mainly useful in metabolism studies of intermediate materials resulting from the biotransformation of the parent compound.