Alveolar retention and clearance of insoluble particles in rats simulated by a new physiology-oriented compartmental kinetics model
Abstract
A physiology-oriented compartmental kinetics model of alveolar retention of inhaled insoluble particulate matter in rat lungs was proposed in a recent paper, and the retention patterns obtained with the model for a hypothetical set of input data appeared to simulate phenomena which were observed in inhalation studies with Fischer 344 rats. The present paper represents the results of applying the new model for simulations of the actual experimental retention data of five different inhalation studies with Fischer 344 rats exposed to three different materials. The experimental data showed that model adjustments had to be made in order to account for clearance effects that appeared to be influenced by the age of the animals. After these adjustments were made and an appropriate set of values for the model parameters describing the respective exposure conditions was used, the model was constrained to represent the empirical data of all of the studies by one unique set of parameter values. Changes in particular values of this set were considered to be acceptable only if they reflected changes of relevant properties of the inhaled particulate matter. The final simulations did not completely comply with this self-imposed criterion. However, the degree of compliance and the simulationmore »
- Authors:
-
- Fraunhofer-Institute of Toxicology and Aerosol Research, Hannover (West Germany)
- Publication Date:
- OSTI Identifier:
- 6319188
- Resource Type:
- Journal Article
- Journal Name:
- Fundamental and Applied Toxicology; (USA)
- Additional Journal Information:
- Journal Volume: 15:2; Journal ID: ISSN 0272-0590
- Country of Publication:
- United States
- Language:
- English
- Subject:
- 63 RADIATION, THERMAL, AND OTHER ENVIRON. POLLUTANT EFFECTS ON LIVING ORGS. AND BIOL. MAT.; PARTICULATES; RETENTION; RESPIRATORY SYSTEM; DYNAMIC FUNCTION STUDIES; AUTOMOBILES; BIOLOGICAL MODELS; EXHAUST GASES; INHALATION; LUNGS; MACROPHAGES; RATS; SIMULATION; ANIMAL CELLS; ANIMALS; BODY; CONNECTIVE TISSUE CELLS; FLUIDS; GASEOUS WASTES; GASES; INTAKE; MAMMALS; ORGANS; PARTICLES; PHAGOCYTES; RODENTS; SOMATIC CELLS; VEHICLES; VERTEBRATES; WASTES; 560300* - Chemicals Metabolism & Toxicology
Citation Formats
Stoeber, W M, Morrow, P E, and Morawietz, G. Alveolar retention and clearance of insoluble particles in rats simulated by a new physiology-oriented compartmental kinetics model. United States: N. p., 1990.
Web. doi:10.1016/0272-0590(90)90059-S.
Stoeber, W M, Morrow, P E, & Morawietz, G. Alveolar retention and clearance of insoluble particles in rats simulated by a new physiology-oriented compartmental kinetics model. United States. https://doi.org/10.1016/0272-0590(90)90059-S
Stoeber, W M, Morrow, P E, and Morawietz, G. 1990.
"Alveolar retention and clearance of insoluble particles in rats simulated by a new physiology-oriented compartmental kinetics model". United States. https://doi.org/10.1016/0272-0590(90)90059-S.
@article{osti_6319188,
title = {Alveolar retention and clearance of insoluble particles in rats simulated by a new physiology-oriented compartmental kinetics model},
author = {Stoeber, W M and Morrow, P E and Morawietz, G},
abstractNote = {A physiology-oriented compartmental kinetics model of alveolar retention of inhaled insoluble particulate matter in rat lungs was proposed in a recent paper, and the retention patterns obtained with the model for a hypothetical set of input data appeared to simulate phenomena which were observed in inhalation studies with Fischer 344 rats. The present paper represents the results of applying the new model for simulations of the actual experimental retention data of five different inhalation studies with Fischer 344 rats exposed to three different materials. The experimental data showed that model adjustments had to be made in order to account for clearance effects that appeared to be influenced by the age of the animals. After these adjustments were made and an appropriate set of values for the model parameters describing the respective exposure conditions was used, the model was constrained to represent the empirical data of all of the studies by one unique set of parameter values. Changes in particular values of this set were considered to be acceptable only if they reflected changes of relevant properties of the inhaled particulate matter. The final simulations did not completely comply with this self-imposed criterion. However, the degree of compliance and the simulation quality achieved with a minimum of parameter variations seem to be unprecedented in retention modeling. The results of the study encourage attempts for further refining the present model.},
doi = {10.1016/0272-0590(90)90059-S},
url = {https://www.osti.gov/biblio/6319188},
journal = {Fundamental and Applied Toxicology; (USA)},
issn = {0272-0590},
number = ,
volume = 15:2,
place = {United States},
year = {Wed Aug 01 00:00:00 EDT 1990},
month = {Wed Aug 01 00:00:00 EDT 1990}
}