Abstract
Renal xenobiotic metabolism can result in production of electrophiles or free radicals that may covalently bind macromolecules or initiate lipid peroxidation. The mechanisms of renal xenobiotic metabolism may vary in different anatomical regions. Kidney cortex contains a cytochrome P-450 system while medulla contains a prostaglandin endoperoxidase. Recently cysteine conjugated-lyase has been implicated in production of reactive intermediates. Metabolic activation may be amplified by accumulation of xenobiotics within renal cells due to tubular concentrating and/or secretory mechanisms. Additionally, renal xenobiotic detoxicification can occur by conjugation with glucuronide, sulfate or glutathione.
Publication types
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Research Support, Non-U.S. Gov't
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Review
MeSH terms
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Acetaminophen / metabolism
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Acetaminophen / toxicity
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Animals
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Antifungal Agents / metabolism
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Antifungal Agents / toxicity
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Antinematodal Agents / metabolism
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Antinematodal Agents / toxicity
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Biotransformation*
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Bromobenzenes / metabolism
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Bromobenzenes / toxicity
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Butadienes / metabolism
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Butadienes / toxicity
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Carbon Tetrachloride / metabolism
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Carbon Tetrachloride / toxicity
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Cephaloridine / metabolism
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Cephaloridine / toxicity
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Chloroform / metabolism
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Chloroform / toxicity
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Ethylene Dibromide / metabolism
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Ethylene Dibromide / toxicity
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Female
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Humans
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Inactivation, Metabolic
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Kidney / drug effects
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Kidney / metabolism*
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Kidney Diseases / chemically induced*
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Lethal Dose 50
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Male
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Organophosphates / metabolism
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Organophosphates / toxicity
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Propane / analogs & derivatives
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Propane / metabolism
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Propane / toxicity
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Rats
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Terpenes / metabolism
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Terpenes / toxicity
Substances
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Antifungal Agents
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Antinematodal Agents
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Bromobenzenes
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Butadienes
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Organophosphates
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Terpenes
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tris(2,3-dibromopropyl)phosphate
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Ethylene Dibromide
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Acetaminophen
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Chloroform
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1,2-dibromo-3-chloropropane
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Carbon Tetrachloride
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bromobenzene
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hexachlorobutadiene
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Cephaloridine
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Propane
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4-ipomeanol