The Impact of Cytochrome P450 2E1‐Dependent Metabolic Variance on a Risk‐Relevant Pharmacokinetic Outcome in Humans

Risk assessments include assumptions about sensitive subpopulations, such as the fraction of the general population that is sensitive and the extent that biochemical or physiological attributes influence sensitivity. Uncertainty factors (UF) account for both pharmacokinetic (PK) and pharmacodynamic (PD) components, allowing the inclusion of risk-relevant information to replace default assumptions about PK and PD variance (uncertainty). Large numbers of human organ donor samples and recent advances in methods to extrapolate in vitro enzyme expression and activity data to the intact human enable the investigation of the impact of PK variability on human susceptibility. The hepatotoxicity of trichloroethylene (TCE) is mediated by acid metabolites formed by cytochrome P450 2E1 (CYP2E1) oxidation, and differences in the CYP2E1 expression are hypothesized to affect susceptibility to TCE's liver injury. This study was designed specifically to examine the contribution of statistically quantified variance in enzyme content and activity on the risk of hepatotoxic injury among adult humans. We combined data sets describing (1) the microsomal protein content of human liver, (2) the CYP2E1 content of human liver microsomal protein, and (3) the in vitro Vmax for TCE oxidation by humans. The 5th and 95th percentiles of the resulting distribution (TCE oxidized per minute per gram liver) differed by approximately sixfold. These values were converted to mg TCE oxidized/h/kg body mass and incorporated in a human PBPK model. Simulations of 8-hour inhalation exposure to 50 ppm and oral exposure to 5 micro g TCE/L in 2 L drinking water showed that the amount of TCE oxidized in the liver differs by 2% or less under extreme values of CYP2E1 expression and activity (here, selected as the 5th and 95th percentiles of the resulting distribution). This indicates that differences in enzyme expression and TCE oxidation among the central 90% of the adult human population account for approximately 2% of the difference in production of the risk-relevant PK outcome for TCE-mediated liver injury. Integration of in vitro metabolism information into physiological models may reduce the uncertainties associated with risk contributions of differences in enzyme expression and the UF that represent PK variability.

[1]  R J Bull,et al.  Mode of action of liver tumor induction by trichloroethylene and its metabolites, trichloroacetate and dichloroacetate. , 2000, Environmental health perspectives.

[2]  L. Teuschler,et al.  Variance of Microsomal Protein and Cytochrome P450 2E1 and 3A Forms in Adult Human Liver , 2003, Toxicology mechanisms and methods.

[3]  J B Houston,et al.  Scaling factors to relate drug metabolic clearance in hepatic microsomes, isolated hepatocytes, and the intact liver: studies with induced livers involving diazepam. , 1997, Drug metabolism and disposition: the biological fate of chemicals.

[4]  Burton H. Singer,et al.  Recursive partitioning in the health sciences , 1999 .

[5]  S. Ohmori,et al.  Metabolism of trichloroethylene. , 1980, Biochemical pharmacology.

[6]  T. Kronbach,et al.  Debrisoquine/sparteine-type polymorphism of drug oxidation. Purification and characterization of two functionally different human liver cytochrome P-450 isozymes involved in impaired hydroxylation of the prototype substrate bufuralol. , 1986, The Journal of biological chemistry.

[7]  J W Fisher,et al.  Physiologically based pharmacokinetic models for trichloroethylene and its oxidative metabolites. , 2000, Environmental health perspectives.

[8]  J W Fisher,et al.  In vitro to in vivo extrapolation for trichloroethylene metabolism in humans. , 1998, Toxicology and applied pharmacology.

[9]  H. Yamazaki,et al.  Interindividual variations in human liver cytochrome P-450 enzymes involved in the oxidation of drugs, carcinogens and toxic chemicals: studies with liver microsomes of 30 Japanese and 30 Caucasians. , 1994, The Journal of pharmacology and experimental therapeutics.

[10]  P. A. P. Moran,et al.  An introduction to probability theory , 1968 .

[11]  M L Gargas,et al.  Kinetic analysis of furan biotransformation by F-344 rats in vivo and in vitro. , 1993, Toxicology and applied pharmacology.

[12]  K. Iyer,et al.  Characterization of Phase I and Phase II hepatic drug metabolism activities in a panel of human liver preparations. , 1999, Chemico-biological interactions.

[13]  S. Okuyama,et al.  Ethanol-induced enhancement of trichloroethylene metabolism and hepatotoxicity: difference from the effect of phenobarbital. , 1988, Toxicology and applied pharmacology.

[14]  A M Jarabek,et al.  Understanding mechanisms of inhaled toxicants: implications for replacing default factors with chemical-specific data. , 1995, Toxicology letters.

[15]  G. L. Kedderis,et al.  Prediction of furan pharmacokinetics from hepatocyte studies: comparison of bioactivation and hepatic dosimetry in rats, mice, and humans. , 1996, Toxicology and applied pharmacology.

[16]  J B Houston,et al.  Prediction of hepatic clearance from microsomes, hepatocytes, and liver slices. , 1997, Drug metabolism reviews.

[17]  D. Northrop Fitting enzyme-kinetic data to V/K. , 1983, Analytical biochemistry.

[18]  M. Gargas,et al.  In Vivoandin VitroStudies of Perchloroethylene Metabolism for Physiologically Based Pharmacokinetic Modeling in Rats, Mice, and Humans , 1996 .

[19]  G. L. Kedderis,et al.  Incorporating human interindividual biotransformation variance in health risk assessment. , 2002, The Science of the total environment.

[20]  H J Clewell,et al.  Evaluating noncancer effects of trichloroethylene: dosimetry, mode of action, and risk assessment. , 2000, Environmental health perspectives.

[21]  S. Kežić,et al.  Study on the cytochrome P-450- and glutathione-dependent biotransformation of trichloroethylene in humans , 2001, International archives of occupational and environmental health.

[22]  J. Lipscomb,et al.  Interindividual variance of cytochrome P450 forms in human hepatic microsomes: correlation of individual forms with xenobiotic metabolism and implications in risk assessment. , 2000, Regulatory toxicology and pharmacology : RTP.

[23]  J. Lipscomb,et al.  Cytochrome P450-dependent metabolism of trichloroethylene: interindividual differences in humans. , 1997, Toxicology and applied pharmacology.

[24]  M E Andersen,et al.  A biologically based risk assessment for vinyl acetate-induced cancer and noncancer inhalation toxicity. , 1999, Toxicological sciences : an official journal of the Society of Toxicology.

[25]  G. L. Kedderis Extrapolation of in vitro enzyme induction data to humans in vivo. , 1997, Chemico-biological interactions.

[26]  B C Allen,et al.  Pharmacokinetic modeling of trichloroethylene and trichloroacetic acid in humans. , 1993, Risk analysis : an official publication of the Society for Risk Analysis.

[27]  Annie M. Jarabek,et al.  Interspecies extrapolation based on mechanistic determinants of chemical disposition , 1995 .