Optimal designs for health risk assessments using fractional polynomial models

Optimal designs for health risk assessments using fractional polynomial models

Fractional polynomials (FP) have been shown to be more flexible than polynomial models for fitting data from an univariate regression model with a continuous outcome but design issues for FP models have lagged. We focus on FPs with a single variable and construct D -optimal designs for estimating mo...

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Veröffentlicht in:Stochastic environmental research and risk assessment 2022-09, Vol.36 (9), p.2695-2710
Hauptverfasser: Casero-Alonso, Víctor, López–Fidalgo, Jesús, Wong, Weng Kee
Format: Artikel
Sprache:eng
Schlagworte:
Aquatic Pollution
Chemistry and Earth Sciences
Computational Intelligence
Computer Science
Design
Design optimization
Earth and Environmental Science
Earth Sciences
Environment
Environmental research
Epidemiology
Health risk assessment
Health risks
Magnesium
Math. Appl. in Environmental Science
Original Paper
Physics
Polynomials
Probability Theory and Stochastic Processes
Regression models
Risk assessment
Software
Songbirds
Statistical analysis
Statistical inference
Statistics for Engineering
Testosterone
Waste Water Technology
Water Management
Water Pollution Control
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Zusammenfassung:Fractional polynomials (FP) have been shown to be more flexible than polynomial models for fitting data from an univariate regression model with a continuous outcome but design issues for FP models have lagged. We focus on FPs with a single variable and construct D -optimal designs for estimating model parameters and I -optimal designs for prediction over a user-specified region of the design space. Some analytic results are given, along with a discussion on model uncertainty. In addition, we provide an applet to facilitate users find tailor made optimal designs for their problems. As applications, we construct optimal designs for three studies that used FPs to model risk assessments of (a) testosterone levels from magnesium accumulation in certain areas of the brains in songbirds, (b) rats subject to exposure of different chemicals, and (c) hormetic effects due to small toxic exposure. In each case, we elaborate the benefits of having an optimal design in terms of cost and quality of the statistical inference.
ISSN:1436-3240
1436-3259
DOI:10.1007/s00477-021-02155-1