Albert P. Li

Transporters and Drug-Metabolizing Enzymes in Drug Toxicity


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Risk Factors

      Felbamate is an anticonvulsant with a dual mechanism of action both as an agonist of gamma‐aminobutyric acid (GABA) receptors and also an antagonist of N‐methyl‐D‐aspartate receptor (NMDA) receptors [66]. It was approved by FDA in August 1993 for the treatment of seizures associated with Lennox–Gastaut syndrome in children, but was withdrawn within a year in August 1994 due to its association with aplastic anemia [67]. Felbamate was provided a redemption in September 1994 for limited use in patients with refractory epilepsy [68], and with additional warning due to its association with rare incidence of acute liver failure, including cases with fatalities [67,69–71].

      3.4.1 Drug Metabolism and Toxicity

      Association of felbamate administration and aplastic anemia was the key reason for the initial market withdrawal of felbamate [72]. Upon its redemption, felbamate was also known to be associated with idiosyncratic acute liver failures [73].

      3.4.2 Transporters and Toxicity

      Treatment of rats with verapamil, a Pgp inhibitor, was found to increase felbamate brain accumulation, suggesting that felbamate is a substrate for the efflux transporter [82]. However, no difference in felbamate distribution in the central nervous system was observed between wild type and multidrug resistance‐associated protein 2 (MRP2)‐deficient rats [83], suggesting that felbamate is not a substrate for this transporter. There are no reports on transporters for felbamate uptake.

      3.4.3 Risk Factors

      Based on current knowledge, genetic and environmental factors that would enhance the formation of reactive metabolites (CYP3A4 induction), reduction of detoxification (GSH depletion), and increased intracellular accumulation (Pgp inhibition) are potential risk factors for felbamate hepatotoxicity.

      Flucloxacillin, an isoxazolyl penicillin, is a narrow spectrum antibiotic of the penicillin class that has a broad range of uses in the treatment of Gram‐positive bacterial infections of skin and soft tissue [84, 85], lung [86], urinary tract [87], meningitis [88, 89] and is used as a prophylaxis during surgery [90–92]. Flucloxacillin treatment has been associated with severe hepatotoxicity, resulting in liver failure [93, 94]. A genome wide association study (GWAS) showed an association of flucloxacillin‐induced liver toxicity with the HLA‐B*5701 genotype [95–97].

      3.5.1 Drug Metabolism and Toxicity

      3.5.2 Transporters and Toxicity

      The membrane transporter MRP2 has been found to mediate the binding of flucloxacillin proteins localized in bile canaliculi regions [104] which has been hypothesized to be one of the determinants of its hepatotoxicity.

      3.5.3 Risk Factors

      The association of flucloxacillin‐induced liver toxicity with the HLA‐B*5701 genotype [95–97] represents the most successful application of GWAS in the identification of an at‐risk population based on genotype. Unfortunately, the association cannot be extended to other DILI drugs. Based on the metabolism of flucloxacillin to the cytotoxic metabolite 5‐hydroxymethyl flucloxacillin, patient populations with enhanced CYP3A4, CYP3A7, and CYP2C9 activities due to environmental and genetic factors, may be at risk of its hepatotoxicity. The findings with MRP2‐mediation of the localization of flucloxacillin in biliary cells suggest that increased MRP2 activity may also be a risk factor.

      3.6.1 Drug Metabolism and Toxicity

      in vitro studies suggest that the hepatotoxicity of nefazodone is associated with metabolic activation of the parent drug to highly reactive and toxic metabolites. Human liver microsome studies show that nefazodone undergoes hydroxylation and sulfydryl conjugation occurred on the 3‐chlorophenylpiperazine‐ring. This leads to the initial formation of p‐hydroxynefazodone