Ramesh Sarangapani

Analysis of Vinyl Acetate Metabolism in Rat and Human Nasal Tissues by an in Vitro Gas Uptake Technique

Physiologically based pharmacokinetic (PBPK) models require estimates of catalytic rate constants controlling the metabolism of xenobiotics. Usually, these constants are derived from whole tissue homogenates wherein cellular architecture and enzyme compartmentation are destroyed. Since the nasal cavity epithelium is composed of a heterogeneous cell population measurement of xenobiotic metabolizing enzymes using homogenates could yield artifactual results. In this article a method for measuring rates of metabolism of vinyl acetate, a metabolism-dependent carcinogen, is presented that uses whole-tissue samples and PBPK modeling techniques to estimate metabolic kinetic parameters in tissue compartments. The kinetic parameter estimates were compared to those derived from homogenate experiments using two methods of tissue normalization. When the in vitro gas uptake constants were compared to homogenate-derived values, using a normalization procedure that does not account for tissue architecture, there was poor agreement. Homogenate-derived values from rat nasal tissue were 3- to 23-fold higher than those derived using the in vitro gas uptake method. When the normalization procedure for the rat homogenate-derived values took into account tissue architecture, a good agreement was observed. Carboxylesterase activity in homogenates of human nasal tissues was undetectable. Using the in vitro gas uptake technique, however, carboxylesterase activity was detected. Rat respiratory carboxylesterase and aldehyde dehydrogenase activities were about three and two times higher than those of humans, respectively. Activities of the rat olfactory enzymes were about equivalent to those of humans. K(m) values did not differ between species. The results suggest that the in vitro gas uptake technique is useful for deriving enzyme kinetic constants where effects of tissue architecture are preserved. Furthermore, the results suggest that caution should be exercised when scaling homogenate-derived values to whole-organ estimates, especially in organs of cellular heterogeneity.

MODE-OF-ACTION?BASED DOSIMETERS FOR INTERSPECIES EXTRAPOLATION OF VINYL ACETATE INHALATION RISK

Vinyl acetate is used in the manufacture of many polymers. The Clean Air Act Amendments of 1990 require that an inhalation risk assessment be conducted to assess risks to human health from ambient exposures. Vinyl acetate is a nasal carcinogen in rats and induces olfactory degeneration in rats and mice. Because of the many unique aspects of the rodent nasal cavity compared to that of humans, conventional means for extrapolating dosimetry between species are not appropriate. Physiologically based pharmacokinetic (PBPK) and pharmacodynamic (PD) modeling can address many of these unique aspects. A PBPK/PD model has been developed for vinyl acetate, but the choice of appropriate dosimeter(s) to use for interspecies extrapolation depends on a hypothesis regarding mode of action. This article summarizes the key studies that formulate a mode of action hypothesis for vinyl acetate. Dose-response relationships for vinyl acetate-induced nonneoplastic and neoplastic responses are highly nonlinear, suggesting complex kinetic processes. Carboxylesterase-dependent metabolism of vinyl acetate forms acetic acid, a potent cytotoxicant, and acetaldehyde, a weak clastogen. Cell death, proposed to be the result of intracellular acidification, results in restorative cell proliferation. In conjunction with sufficient genetic damage, induced by spontaneous mutation and acetaldehyde-induced DNA?protein cross-links (DPX), olfactory degeneration progresses to a state of elevated proliferation and eventually, at high vinyl acetate concentrations, to neoplastic transformation. Thus, reduction in intracellular pH (pHi) is proposed as the dosimeter most closely linked to the earliest stages of vinyl acetate toxicity. Consequently, risk assessments that are based on protection of nasal epithelium from intracellular acidification will be protective of all subsequent pathological responses related to vinyl acetate exposure. Proposing a reasonable mode of action is an important step in any risk assessment and is critical to the choice of dosimeter(s) to be used for interspecies dosimetry extrapolation.Vinyl acetate is used in the manufacture of many polymers. The Clean Air Act Amendments of 1990 require that an inhalation risk assessment be conducted to assess risks to human health from ambient exposures. Vinyl acetate is a nasal carcinogen in rats and induces olfactory degeneration in rats and mice. Because of the many unique aspects of the rodent nasal cavity compared to that of humans, conventional means for extrapolating dosimetry between species are not appropriate. Physiologically based pharmacokinetic (PBPK) and pharmacodynamic (PD) modeling can address many of these unique aspects. A PBPK/PD model has been developed for vinyl acetate, but the choice of appropriate dosimeter(s) to use for interspecies extrapolation depends on a hypothesis regarding mode of action. This article summarizes the key studies that formulate a mode of action hypothesis for vinyl acetate. Dose-response relationships for vinyl acetate-induced nonneoplastic and neoplastic responses are highly nonlinear, suggesting complex kinetic processes. Carboxylesterase-dependent metabolism of vinyl acetate forms acetic acid, a potent cytotoxicant, and acetaldehyde, a weak clastogen. Cell death, proposed to be the result of intracellular acidification, results in restorative cell proliferation. In conjunction with sufficient genetic damage, induced by spontaneous mutation and acetaldehyde-induced DNA-protein cross-links (DPX), olfactory degeneration progresses to a state of elevated proliferation and eventually, at high vinyl acetate concentrations, to neoplastic transformation. Thus, reduction in intracellular pH (pHi) is proposed as the dosimeter most closely linked to the earliest stages of vinyl acetate toxicity. Consequently, risk assessments that are based on protection of nasal epithelium from intracellular acidification will be protective of all subsequent pathological responses related to vinyl acetate exposure. Proposing a reasonable mode of action is an important step in any risk assessment and is critical to the choice of dosimeter(s) to be used for interspecies dosimetry extrapolation.

Clearance concepts applied to the metabolism of inhaled vapors in tissues lining the nasal cavity.

Some inhaled vapors are metabolized by tissues in the nasal cavity or carried away in nasal venous blood after diffusing from the lumen through the nasal epithelial tissues. These processes remove chemical from the airstream. Clearance (volume/time) is the volumetric airflow from which chemical would have to be completely removed to account for the net loss. We present here a steady-state analysis of a series of physiologically based clearance-extraction (PBCE) models for nasal clearance of inhaled vapors, consisting of one, two, three, or four subcompartments. A two-compartment model is the simplest representation of tissues in the nasal cavity, with an air and a tissue compartment. The three-compartment model had air, mucus, and tissue phases. The four-compartment model included both epithelial and submucosal tissues in addition to the air and mucus compartments. For the two-, three-, and four-compartment models, the airstream clearance (Cl(sys)) equation has a common form. Cl(sys) = Cl(tot)H(m:a)PA(gas)Q divided by Cl(tot)H(m:a)(Q + PA(gas)) + PA(gas)Q. In this equation, Cl(tot) is the total tissue clearance, PA(gas) is the gas-phase diffusional clearance, Q is the airflow, and H(muc:a) is the mucus air partition coefficient. Cl(tot) varies in complexity for the different models since it encompasses tissue diffusion, tissue clearance due to metabolism, and blood flow. A physiologically based clearance-extraction (PBCE) model for the whole nose with three nasal tissue regions, each containing a four-compartment tissue stack, was used to simulate nasal uptake of three vapors-acetone, methyl methacrylate (MMA), and vinyl acetate (VA)-to show the dependence of clearance on different parameters for specific compounds. Acetone is not metabolized in the nose, MMA is metabolized at a moderate rate by nasal tissues, and VA is metabolized at a high rate in mucus and tissues. Equations derived from steady-state analyses show the importance of the specific biochemical and physiological parameters for clearance of each of these chemicals and permit calculation of airstream clearance from simple algebraic relationships.

PHYSIOLOGICALLY BASED CLEARANCE/EXTRACTION MODELS FOR COMPOUNDS METABOLIZED IN THE NOSE: An Example with Methyl Methacrylate

Airstream clearance (with units of volume/time) is the volumetric flow from which chemical would have to be completely removed to account for the net loss in the nose. Extraction is the proportion of airflow from which the chemical is completely removed. Over the past several years we have developed physiologically based clearance-extraction (PBCE) models for the nose to assess the physiological, biochemical, and anatomical factors that control airstream clearance. A generic clearance equation was derived for single airway/tissue compartments that had a separate air region and either one, two, or three underlying tissue regions. For all of these structures, airstream clearance (Cl(sys)) has a common form-Equation (1)-related to tissue clearance (Cltot), gas-phase diffusional clearance (PAgas), airflow (Q), and the mucus air partition coefficient (Hmuc:a). Clsys = CltotHm:aPAgasQ/CltotHm:a(Q + PAgas) + PAgasQ. A physiologically based clearance-extraction (PBCE) model for the whole nose combined three separate nasal tissue regions, each with a four-compartment tissue stack (air, mucus, epithelial tissue, and submucosal region). A steady-state solution of the PBCE model successfully described literature results on the steady-state extraction of methyl methacrylate (MMA) and several other metabolized vapors. Model-derived tissue dosimetry estimates, that is, the amount of MMA metabolized in the target epithelial compartment of the olfactory region, for rats and humans provide dosimetric adjustment factors (DAFs) required in calculating a human reference concentration (RfC) from rodent studies. Depending on the assignment of esterase activities to sustentacular and submucosal regions, the DAFs from the PBCE model varied between 1.6 and 8.0, compared to the default value of 0.145. From the experience with MMA, a minimal data set could be defined for building the PBCE model. It consists of mucus:air and blood:air partition coefficients, metabolic constants for enzymatic hydrolysis in nasal tissues from rat and human tissues, immunohistochemistry of the distribution of these activities in rats and human olfactory tissues, and extraction studies in anesthetized rats to assess the total nasal metabolism of the test compound.Airstream clearance (with units of volume/time) is the volumetric flow from which chemical would have to be completely removed to account for the net loss in the nose. Extraction is the proportion of airflow from which the chemical is completely removed. Over the past several years we have developed physiologically based clearance-extraction (PBCE) models for the nose to assess the physiological, biochemical, and anatomical factors that control airstream clearance. A generic clearance equation was derived for single airway/tissue compartments that had a separate air region and either one, two, or three underlying tissue regions. For all of these structures, airstream clearance (Clsys) has a common form-Equation (1)-related to tissue clearance (Cltot), gas-phase diffusional clearance (PAgas), airflow (Q), and the mucus air partition coefficient (Hmuc:a). Clsys = (CltotHm:aPAgasQ) / (CltotHm:a(Q+PAgas) + PAgasQ) A physiologically based clearance-extraction (PBCE) model for the whole nose combined three separate nasal tissue regions, each with a four-compartment tissue stack (air, mucus, epithelial tissue, and submucosal region). A steady-state solution of the PBCE model successfully described literature results on the steady-state extraction of methyl methacrylate (MMA) and several other metabolized vapors. Model-derived tissue dosimetry estimates, that is, the amount of MMA metabolized in the target epithelial compartment of the olfactory region, for rats and humans provide dosimetric adjustment factors (DAFs) required in calculating a human reference concentration (RfC) from rodent studies. Depending on the assignment of esterase activities to sustentacular and submucosal regions, the DAFs from the PBCE model varied between 1.6 and 8.0, compared to the default value of 0.145. From the experience with MMA, a minimal data set could be defined for building the PBCE model. It consists of mucus:air and blood:air partition coefficients, metabolic constants for enzymatic hydrolysis in nasal tissues from rat and human tissues, immunohistochemistry of the distribution of these activities in rats and human olfactory tissues, and extraction studies in anesthetized rats to assess the total nasal metabolism of the test compound.

HIGH-AFFINITY NASAL EXTRACTION OF VINYL ACETATE VAPOR IS CARBOXYLESTERASE DEPENDENT

Vinyl acetate induces nasal tumors in rats, but not mice. Species differences in airflow patterns, physiology, and biochemistry complicate extrapolation of nasal dosimetry from rats to humans. Physiologically based pharmacokinetic modeling of vinyl acetate dosimetry in rats suggested the presence of a saturable metabolic removal pathway in rat nasal mucus. We explored the possibility that this pathway is either a cytochrome P-450 2E1 (CYP2E1) or high-affinity carboxylesterase. Nasal extraction of vinyl acetate vapor (150 ppm) was measured in the surgically isolated nasal cavity of anesthetized rats. Vinyl acetate (150 ppm) was extracted with 73% efficiency in controls. Pretreatment of rats with the CYP2E1 inhibitor diallyl sulfide (DAS) had no effect on extraction, despite significantly reducing CYP2E1 activity. Pretreatment with bis(p-nitrophenyl) phosphate (BNPP), a carboxylesterase inhibitor, reduced extraction to approximately 41%. Acetaldehyde production was similarly unaffected by DAS but was reduced to 55% of control by BNPP. Rat nasal mucus carboxylesterase activity had a K(m) value (32 microM) similar, within a factor of 2, to the value predicted by the physiologically based model, although V(max) was significantly lower than the model prediction. Histochemical observations support the inference that the high-affinity carboxylesterase is bound to the luminal plasma membrane of nasal tissue and is not readily released by nasal lavage, providing an explanation for the low V(max) of the lavage enzyme. This high-affinity isoenzyme could be important in the removal of odorants from the sensory cell-rich nasal olfactory epithelium.