A unified framework for benchmark dose estimation applied to mixed models and model averaging

Christian Ritz; Daniel Gerhard; Ludwig A. Hothorn

doi:10.1080/19466315.2012.757559

A unified framework for benchmark dose estimation applied to mixed models and model averaging

Christian Ritz, Daniel Gerhard, Ludwig A. Hothorn

Department of Chemistry

12 Citations (Scopus)

Abstract

This article develops a framework for benchmark dose estimation that allows intrinsically nonlinear dose-response models to be used for continuous data in much the same way as is already possible for quantal data. This means that the same dose-response model equations may be applied to both continuous and quantal data, facilitating benchmark dose estimation in general for a wide range of candidate models commonly used in toxicology. Moreover, the proposed framework provides a convenient means for extending benchmark dose concepts through the use of model averaging and random effects modeling for hierarchical data structures, reflecting increasingly common types of assay data. We illustrate the usefulness of the methodology by means of a cytotoxicology example where the sensitivity of two types of assays are evaluated and compared. By means of a simulation study, we show that the proposed framework provides slightly conservative, yet useful, estimates of benchmark dose lower limit under realistic scenarios.

Original language	English
Journal	Statistics in Biopharmaceutical Research
Volume	5
Issue number	1
Pages (from-to)	79-90
Number of pages	12
ISSN	1946-6315
DOIs	https://doi.org/10.1080/19466315.2012.757559
Publication status	Published - 2013

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10.1080/19466315.2012.757559

Cite this

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AB - This article develops a framework for benchmark dose estimation that allows intrinsically nonlinear dose-response models to be used for continuous data in much the same way as is already possible for quantal data. This means that the same dose-response model equations may be applied to both continuous and quantal data, facilitating benchmark dose estimation in general for a wide range of candidate models commonly used in toxicology. Moreover, the proposed framework provides a convenient means for extending benchmark dose concepts through the use of model averaging and random effects modeling for hierarchical data structures, reflecting increasingly common types of assay data. We illustrate the usefulness of the methodology by means of a cytotoxicology example where the sensitivity of two types of assays are evaluated and compared. By means of a simulation study, we show that the proposed framework provides slightly conservative, yet useful, estimates of benchmark dose lower limit under realistic scenarios.

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