Modulation of macrophage functioning abrogates the acute hepatotoxicity of acetaminophen

Abstract Acetaminophen is a mild analgesic and antipyretic agent that is safe and effective when taken in therapeutic doses. Ingestion of overdoses, however, may lead to acute liver failure accompanied by centrilobular degeneration and necrosis. Although the toxicity of acetaminophen is generally thought to be caused by direct interaction of its reactive metabolites with cellular macromolecules, recent studies have suggested that nonparenchymal cells also may contribute to tissue injury indirectly through the release of cytotoxic mediators. We analyzed the potential role of hepatic macrophages in acetaminophen hepatotoxicity by examining the effects of modulating the activity of these cells on tissue injury. Treatment of male Long Evans Hooded rats with acetaminophen (800 mg/kg) was found to induce extensive centrilobular hepatic necrosis. Pretreatment of the rats with either dextran sulfate or gadolinium chloride, two inhibitors of hepatic macrophage functioning, completely blocked hepatic necrosis, as well as increases in serum transaminase levels induced by acetaminophen. Interestingly, treatment of rats with the macrophage activator, lipopolysaccharide (LPS), also reduced tissue injury induced by acetaminophen. To exclude the possibility that the effects of gadolinium chloride, dextran sulfate, or LPS were due to alterations in acetaminophen metabolism, we analyzed the effects of these agents on various pharmacokinetic properties of this analgesic. Dextran sulfate and gadolinium chloride had no effect on the half‐life of a low dose of acetaminophen (20 mg/kg), or on the activity of any of its individual pathways of metabolism, including the formation of acetaminophenmercapturic acid. LPS treatment of rats caused a general depression of acetaminophen metabolism involving all of the known pathways of metabolic clearance, resulting in a decrease in the blood half‐life of the drug. However, the fraction of the dose converted to the toxic metabolite (NAPQI) was not different from that observed in rats given acetaminophen alone. Collectively, these data indicate that the protection afforded the animals by pretreatment with macrophage modulators was not due to suppression of the formation of NAPQI and hence support the hypothesis that macrophages may contribute directly to acetaminophen hepatotoxicity by an independent mechanism. (H EPATOLOGY 1995; 21:1045–1050.)