Main Title |
Regional respiratory tract absorption of inhaled reactive gases / |
Author |
Miller, F. J. ;
Overton, J. H. ;
Kimbell, J. S. ;
Russell, M. L.
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Other Authors |
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CORP Author |
Health Effects Research Lab., Research Triangle Park, NC. Environmental Toxicology Div. ;Chemical Industry Inst. of Toxicology, Research Triangle Park, NC. ;Duke Univ. Medical Center, Durham, NC. Center for Extrapolation Modelling. |
Publisher |
United States Environmental Protection Agency, Office of Research and Development, Health Effects Research Laboratory, |
Year Published |
1992 |
Report Number |
EPA/600/A-92/179 |
Stock Number |
PB92-217140 |
Additional Subjects |
Respiratory system ;
Toxic substances ;
Gases ;
Absorption ;
Species diversity ;
Humans ;
Laboratory animals ;
Dosimetry ;
Ozone ;
Formaldehyde ;
Nitrogen dioxide ;
Anatomical models ;
Chemical reactions ;
Solubility ;
Reprints
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Holdings |
Library |
Call Number |
Additional Info |
Location |
Last Modified |
Checkout Status |
NTIS |
PB92-217140 |
Some EPA libraries have a fiche copy filed under the call number shown. |
|
07/26/2022 |
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Collation |
88 pages ; 28 cm |
Abstract |
Highly reactive gases present unique problems due to the number of factors which must be taken into account to determine regional respiratory tract uptake. The authors reviewed some of the physical, chemical, and biological factors that affect dose and that must be understood to interpret toxicological data, to evaluate experimental dosimetry studies, and to develop dosimetry models. Selected dosimetry experiments involving laboratory animals and humans were discussed, showing the variability and uptake according to animal species and respiratory tract region for various reactive gases. New experimental dosimetry approaches, such as those involving isotope ratio mass spectroscopy and cyclotron generation reactive gases, were discussed that offer great promise for improving our ability to study regional respiratory tract absorption of reactive gases. Various dosimetry modeling applications were discussed which demonstrate: the importance of airflow patterns for site-specific dosimetry in the upper respiratory tract, the influence of the anatomical model used to make inter- and intraspecies dosimetric comparisons, the influence of tracheobronchial path length on predicted dose curves, and the implications of ventilatory unit structure and volume on dosimetry and response. Collectively, these examples illustrate important aspects of regional respiratory tract absorption of inhaled reactive gases. Given the complex nature of extent and pattern of injury in the respiratory tract from exposure to reactive gases, understanding interspecies differences in the absorption of reactive gases will continue to be an important area for study. |
Notes |
Includes bibliographical references. Microfiche. |