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Literature DB >> 612436

Dechloriation mechanisms of chlorinated olefins.

Abstract

The dechlorination of chlorinated hydrocarbons has been examined in detail. The reaction is catalyzed by cytochrome P-450 and occurs optimally in the presence of oxygen although some dechlorination may occur under anaerobic conditions. Halothane has been shown to undergo an oxidative dechlorination and a reductive defluorination. Enzymatic attack of chlorinated olefins and hydrocarbons is not on the carbon--halogen bond. Oxidative dechlorination of hydrocarbons is apparently initiated by an attack on the carbon atom and the halogen is then released from the oxidized carbon. The chlorinated olefins, on the other hand, are not easily dechlorinated enzymatically. The chlorines migrate readily across the double bond, therefore, cyclic chloronium ions must occur as intermediates. It is not clear at this time if epoxides are also intermediates in this conversion.

Entities: Chemical

Mesh：

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Year: 1977 PMID： 612436 PMCID： PMC1475340 DOI： 10.1289/ehp.7721121

Source DB: PubMed Journal: Environ Health Perspect ISSN： 0091-6765 Impact factor: 9.031

19 in total

1. THE METABOLISM OF 36C1-LABELLED TRICHLOROETHYLENE AND TETRACHLOROETHYLENE IN THE RAT.

Authors: J W DANIEL
Journal: Biochem Pharmacol Date: 1963-08 Impact factor: 5.858

2. Reduction of carbon tetrachloride in vivo and reduction of carbon tetrachloride and chloroform in vitro by tissues and tissue constituents.

Authors: T C BUTLER
Journal: J Pharmacol Exp Ther Date: 1961-12 Impact factor: 4.030

3. Anaerobic release of fluoride from halothane. Relationship to the binding of halothane metabolites to hepatic cellular constituents.

Authors: R A Van Dyke; A J Gandolf
Journal: Drug Metab Dispos Date: 1976 Jan-Feb Impact factor: 3.922

Dechloriation mechanisms of chlorinated olefins.

1. THE METABOLISM OF 36C1-LABELLED TRICHLOROETHYLENE AND TETRACHLOROETHYLENE IN THE RAT.

2. Reduction of carbon tetrachloride in vivo and reduction of carbon tetrachloride and chloroform in vitro by tissues and tissue constituents.

3. Anaerobic release of fluoride from halothane. Relationship to the binding of halothane metabolites to hepatic cellular constituents.

4. Metabolism of trichloroethylene in liver microsomes. I. Characteristics of the reaction.

5. Enzymatic dechlorination. Dechlorination of chloroethanes and propanes in vitro.

6. Dechlorination of chloroethane with a reconstituted liver microsomal system.

7. Metabolism of dihalomethanes to carbon monoxide. I. In vivo studies.

8. Metabolism of haloforms to carbon monoxide. I. In vitro studies.

9. Metabolism of halogenated ethylenes.

10. Metabolism and mutagenicity of halogenated olefins--a comparison of structure and activity.

1. In vivo suppression of 1,1,1-trichloroethane metabolism by co-administered tetrachloroethylene: an inhalation study.

2. Enzymatic formation of an olefin in the metabolism of 1,1,2,2-tetrachloroethane: an in vitro study.

3. Metabolism and Bioactivation of Fluorochloridone, a Novel Selective Herbicide, in Vivo and in Vitro.

4. Haloethylene-related compounds of industrial, environmental, and medical significance.

Review 5. Metabolism and toxicity of hydrochlorofluorocarbons: current knowledge and needs for the future.

6. Evaluation of the genotoxicity potential and chronic inhalation toxicity of 1,1-dichloro-1-fluoroethane (HCFC-141b).