Biologically Motivated Computational Modeling of Formaldehyde Carcinogenicity in the F344 Rat

doi:10.1093/toxsci/kfg182

ToxSci Advance Access originally published online on July 11, 2003

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Toxicological Sciences 75, 432-447 (2003)
Copyright © 2003 by the Society of Toxicology

RISK ASSESSMENT

Biologically Motivated Computational Modeling of Formaldehyde Carcinogenicity in the F344 Rat

Rory B. Conolly¹, Julia S. Kimbell, Derek Janszen², Paul M. Schlosser, Darin Kalisak, Julian Preston³ and Frederick J. Miller

CIIT Centers for Health Research, 6 Davis Drive, Research Triangle Park, North Carolina 27709

ABSTRACT

Formaldehyde inhalation at 6 ppm and above causes nasal squamouscell carcinoma (SCC) in F344 rats. The human health implicationsof this effect are of significant interest since human exposureto environmental formaldehyde is widespread, though at lowerconcentrations than those that cause cancer in rats. In thisarticle, which is part of a larger effort to predict the humancancer risks of inhaled formaldehyde, we describe biologicallymotivated quantitative modeling of the exposure-tumor responsecontinuum in the rat. An anatomically realistic, three-dimensionalfluid dynamics model of the F344 rat nasal airways was usedto predict site-specific flux of formaldehyde from inhaled airinto tissue, since both SCC and preneoplastic lesions developin a characteristic site-specific pattern. Flux into tissuewas used as a dose metric for two modes of action, direct mutagenicityand cytolethality-regenerative cellular proliferation (CRCP),which in turn were linked to key parameters of a two-stage clonalgrowth model. The direct mutagenicity mode of action was representedby a low dose linear dose-response model of DNA-protein cross-link(DPX) formation. An empirical J-shaped dose-response model anda threshold model fit to the empirical data were used for CRCP.In the clonal growth model, the probability of mutation percell generation was a function of the tissue concentration ofDPX while the rate of cell division was calculated from theCRCP data. Maximum likelihood methods were used to estimateparameter values. Survivor (a nontumor outcome) and tumor datafor controls from the National Toxicology Program database andfrom two formaldehyde inhalation bioassays were used for likelihoodcalculations. The J-shaped dose-response for CRCP provided abetter description of the SCC data than did the threshold model.Sensitivity analyses indicated that the rodent tumor responseis due to the CRCP mode of action, with the directly mutagenicpathway having little, if any, influence. When evaluated inlight of modeling and database uncertainties, particularly thespecification of the clonal growth model and the dose-responsedata for CRCP, this work provides suggestive though not definitiveevidence for a J-shaped dose-response for formaldehyde-mediatednasal SCC in the F344 rat.

Key Words: formaldehyde; F344 rat; squamous cell carcinoma; dose-response; clonal growth; DNA-protein cross-links; regenerative cellular proliferation; computational modeling; risk assessment.

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