© 1991 Oxford University Press
research-article |
An Optimization Strategy for a Biokinetic Model of Inhaled Radionuclides
Inhalation Toxicology Research Institute P.O. Box 5890, Albuquerque, New Mexico 87185
Received April 30, 1990; accepted October 1, 1990
An Optimization Strategy for a Biokinetic Model of Inhaled Radionuclides. SHYR, L. J., GRIFFITH, W. C, AND BOECKER, B. B. (1991). Fundam. Appl. Toxicol. 16, 423–434. Models for material disposition and dosimetry involve predictions of the biokinetics of the material among compartments representing organs and tissues in the body. Because of a lack of human data for most toxicants, many of the basic data are derived by modeling the results obtained from studies using laboratory animals. Such a biomathematical model is usually developed by adjusting the model parameters to make the model predictions match the measured retention and excretion data visually. The fitting process can be very time-consuming for a complicated model, and visual model selections may be subjective and easily biased by the scale or the data used. Due to the development of computerized optimization methods, manual fitting could benefit from an automated process. However, for a complicated model, an automated process without an optimization strategy will not be efficient, and may not produce fruitful results. In this paper, procedures for, and implementation of, an optimization strategy for a complicated mathematical model is demonstrated by optimizing a biokinetic model for 144Ce in fused aluminosilicate particles inhaled by beagle dogs. The optimized results using SimuSolv were compared to manual fitting results obtained previously using the model simulation software GASP. Also, statistical criteria provided by SimuSolv, such as likelihood function values, were used to help or verify visual model selections.