Analysis of vinyl acetate metabolism in rat and human nasal tissues by an in vitro gas uptake technique.

@article{Bogdanffy1998AnalysisOV,
  title={Analysis of vinyl acetate metabolism in rat and human nasal tissues by an in vitro gas uptake technique.},
  author={Matthew S Bogdanffy and Ramesh Sarangapani and Julia S. Kimbell and S. Randall Frame and David R. Plowchalk},
  journal={Toxicological sciences : an official journal of the Society of Toxicology},
  year={1998},
  volume={46 2},
  pages={
          235-46
        }
}
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… 
View on PubMed
doi.org
23 Citations
Highly Influential Citations
1
Background Citations
10
Methods Citations
6

Figures and Tables from this paper

23 Citations

Citation Type

Citation Type

A PBPK Model for Evaluating the Impact of Aldehyde Dehydrogenase Polymorphisms on Comparative Rat and Human Nasal Tissue Acetaldehyde Dosimetry
TLDR
The rat and human acetaldehyde PBPK models developed here can also be used as a bridge between acetaldehyde dose-response and mode-of-action data as well as between similar databases for other acetaldehyde-producing nasal toxicants.
Use of a hybrid computational fluid dynamics and physiologically based inhalation model for interspecies dosimetry comparisons of ester vapors.
TLDR
The results indicate that the CFD-PBPK model can simulate both the low-dose nasal tissue dosimetry associated with irritation and the high-dose systemic tissue Dosimetryassociated with mortality, and suggest that the human olfactory epithelium is protected from vapors of organic esters significantly better than rat olfactories due to substantive differences in nasal anatomy, nasal and systemic metabolism, systemic physiology, and air flow.
COMPARING RESPIRATORY-TRACT AND HEPATIC EXPOSURE-DOSE RELATIONSHIPS FOR METABOLIZED INHALED VAPORS: A PHARMACOKINETIC ANALYSIS
TLDR
A physiologically based pharmacokinetic (PBPK) model is developed that incorporates a multicompartment, unidirectional flow description of the respiratory tract within a whole-body model in order to estimate both respiratory tract and hepatic metabolism and confirms that for soluble vapors the exposure-dose curve for metabolism in respiratory-tract tissue will be shifted dramatically to lower concentrations.
Ethyl acrylate risk assessment with a hybrid computational fluid dynamics and physiologically based nasal dosimetry model.
TLDR
A chronic RfC based on maintaining GSH in the human nasal olfactory epithelium at levels equivalent to the rat NOEL would also provide an adequate margin of safety with respect to AA concentrations in nasal tissues.
PHYSIOLOGICALLY BASED PHARMACOKINETIC MODELING OF STYRENE AND STYRENE OXIDE RESPIRATORY-TRACT DOSIMETRY IN RODENTS AND HUMANS
TLDR
The PBPK model predicts a 10-fold lower SO concentration in the terminal bronchioles in rats compared to mice, consistent with the observed species sensitivity to the development of respiratory-tract neoplasms, and suggests that humans would be expected to be 100-fold less sensitive to ST-inducted lung tumors than mice, based on pharmacokinetic differences.
MODE-OF-ACTION?BASED DOSIMETERS FOR INTERSPECIES EXTRAPOLATION OF VINYL ACETATE INHALATION RISK
TLDR
Reduction in intracellular pH (pHi) is proposed as the dosimeter most closely linked to the earliest stages of vinyl acetate toxicity, and risk assessments that are based on protection of nasal epithelium from intrACEllular acidification will be protective of all subsequent pathological responses related to vinyl acetates exposure.
Dosimetry modeling of inhaled formaldehyde: comparisons of local flux predictions in the rat, monkey, and human nasal passages.
Formaldehyde-induced nasal squamous cell carcinomas in rats and squamous metaplasia in rats and rhesus monkeys occur in specific regions of the nose with species-specific distribution patterns.
Nonlinear responses for chromosome and gene level effects induced by vinyl acetate monomer and its metabolite, acetaldehyde in TK6 cells
TLDR
Cytotoxicity paralleled genotoxicity demonstrating that a small degree of cytotoxicity occurred prior to increases in MN, and established 0.25 mM as a consistent concentration where genotoxic first occurred for both VAM and AA provided VAM is hydrolyzed to AA.
Interspecies Dose Extrapolation for Inhaled Dimethyl Sulfate: A PBPK Model-Based Analysis using Nasal Cavity N7-Methylguanine Adducts
TLDR
A model-based interspecies dose comparison, using N7mG adduct levels in the nasal respiratory tissue as the appropriate dose metrics, predicts a dose rate seven times higher in rats compared to humans.
Evaluation of the Potential Impact of Age- and Gender-Specific Lung Morphology and Ventilation Rate on the Dosimetry of Vapors
TLDR
An approach for using physiologically based pharmacokinetic (PBPK) modeling to compare inhalation dosimetry in the adult and the child of both males and females is demonstrated.
...
1
2
3
...

References

SHOWING 1-10 OF 51 REFERENCES
Physiologically based modeling of vinyl acetate uptake, metabolism, and intracellular pH changes in the rat nasal cavity.
TLDR
A physiologically based pharmacokinetic model was constructed to describe the deposition of VA in the nasal cavity of the rat and provide estimates of regional tissue exposure to VA, AAld, and AA and provides nasal dosimetry estimates needed to develop mechanistically based risk assessment approaches for human exposures to VA vapor.
A physiologically based pharmacokinetic model for nasal uptake and metabolism of nonreactive vapors.
TLDR
A PB-PK model has been developed for nasal nonreactive vapor uptake in the F344 rat which incorporates nasal enzyme distribution as well as nasal airflow patterns in influencing uptake and metabolism of inspired vapors and indicates the need for physiologically relevant models incorporating these factors.
Kinetics of nasal carboxylesterase-mediated metabolism of vinyl acetate.
TLDR
The data demonstrate the high capacity of nasal tissue to metabolize vinyl acetate to acetaldehyde and may explain, in part, Vinyl acetate-induced nonneoplastic nasal lesion distribution, however, the data do not account for the species difference in susceptibility to the carcinogenic effects of vinyl acetates.
Metabolic capacity of nasal tissue interspecies comparisons of xenobiotic-metabolizing enzymes.
Biotransformation enzymes in the rodent nasal mucosa: the value of a histochemical approach.
TLDR
The distribution of carboxylesterase, aldehyde dehydrogenase, cytochromes P-450, epoxide hydrolase, and glutathione S-transferases within the nasal mucosa is reviewed in the context of their contribution to xenobiotic metabolism.
Kinetic analysis of furan biotransformation by F-344 rats in vivo and in vitro.
TLDR
Results suggest that freshly isolated hepatocytes are a valuable in vitro system for predicting chemical pharmacokinetics in vivo, and incorporation of the in vitro hepatocyte kinetic parameters into the PBPK model for furan accurately simulated in vivo pharmacodynamics.
First-pass metabolism of inspired ethyl acetate in the upper respiratory tracts of the F344 rat and Syrian hamster.
  • J. Morris
  • Biology
    Toxicology and applied pharmacology
  • 1990
Nasal cavity enzymes involved in xenobiotic metabolism: effects on the toxicity of inhalants.
TLDR
Research in the next decade promises to provide answers to the many still unanswered questions posed by the presence of the substantial xenobiotic metabolizing capacity of the nasal cavity.
Cytotoxicity and DNA-protein crosslink formation in rat nasal tissues exposed to vinyl acetate are carboxylesterase-mediated.
TLDR
A hypothesis that carboxylesterase-mediated hydrolysis of vinyl acetate is necessary to generate the active intracellular cross-linking agent, acetaldehyde, and the cytotoxic metabolite, acetic acid is supported.
Biochemical quantitation and histochemical localization of carboxylesterase in the nasal passages of the Fischer-344 rat and B6C3F1 mouse.
...
1
2
3
4
5
...