Simulation Modeling of the Tissue Disposition of Formaldehyde to Predict Nasal DNA-Protein Cross-Links in Fischer 344 Rats, Rhesus Monkeys, and Humans

Autor:	Patrick D. Lilly, Rory B. Conolly, Julia S. Kimbell
Rok vydání:	2000
Předmět:	Pathology medicine.medical_specialty Time Factors Metabolic Clearance Rate Health Toxicology and Mutagenesis Formaldehyde Physiology Mucous membrane of nose Tissue disposition Risk Assessment chemistry.chemical_compound Olfactory mucosa Predictive Value of Tests medicine Animals Humans Tissue Distribution Respiratory system Carcinogen Inhalation exposure Inhalation Exposure Dose-Response Relationship Drug Inhalation Chemistry Public Health Environmental and Occupational Health Macaca mulatta Rats Inbred F344 Rats DNA-Binding Proteins Nasal Mucosa medicine.anatomical_structure Models Animal Carcinogens DNA Damage
Zdroj:	Environmental Health Perspectives. 108:919-924
ISSN:	0091-6765
DOI:	10.1289/ehp.00108s5919
Popis:	Formaldehyde inhalation causes formation of DNA-protein cross-links (DPX) in the nasal mucosa of Fischer 344 (F344) rats and rhesus monkeys. DPX are considered to be part of the mechanism by which cytotoxic and carcinogenic effects of formaldehyde in laboratory animals are exerted, and DPX data have been used as a measure of tissue dose in cancer risk assessments for formaldehyde. Accurate prediction of DPX concentrations in humans is therefore desirable. The goal of this work was to increase confidence in the prediction of human DPX by refining earlier models of formaldehyde disposition and DPX kinetics in the nasal mucosa. Anatomically accurate, computational fluid dynamics models of the nasal airways of F344 rats, rhesus monkeys, and humans were used to predict the regional flux of formaldehyde to the respiratory and olfactory mucosa. A previously developed model of the tissue disposition of formaldehyde and of DPX kinetics was implemented in the graphical simulation tool SIMULINK and linked to the regional flux predictions. Statistical optimization was used to identify parameter values, and good simulations of the data were obtained. The parameter estimates for rats and monkeys were used to guide allometric scale-up to the human case. The relative levels of nasal mucosal DPX in rats, rhesus monkeys, and humans for a given inhaled concentration of formaldehyde were predicted by the model to vary with concentration. This modeling approach reduces uncertainty in the prediction of human nasal mucosal DPX resulting from formaldehyde inhalation.
Databáze:	OpenAIRE
Externí odkaz:	https://explore.openaire.eu/search/publication?articleId=doi_dedup___::1dbd6c5e372d50a22222d403ada264ad https://doi.org/10.1289/ehp.00108s5919 Zobrazit plný text záznamu