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Auteurs principaux: Stefan Embacher, Andrea Berghold, Kirsten Maertens, Sereina A. Herzog
Format: Artículo Open Access
Publié: Wiley 2025
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Accès en ligne:https://onlinelibrary.wiley.com/doi/10.1002/sim.70293
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author Stefan Embacher
Andrea Berghold
Kirsten Maertens
Sereina A. Herzog
author_facet Stefan Embacher
Andrea Berghold
Kirsten Maertens
Sereina A. Herzog
Stefan Embacher
Andrea Berghold
Kirsten Maertens
Sereina A. Herzog
collection Wiley Open Access
contents A Practical Framework to Design Immunization Studies Based on the Beta Distribution Stefan Embacher Andrea Berghold Kirsten Maertens Sereina A. Herzog Statistics in Medicine ABSTRACT An optimally designed experiment reaches results quicker, at a lower cost, or with fewer observations and is therefore crucial in maximizing resource efficiency in research. In immunization studies, the primary goal is often to characterize antibody kinetics—the change in antibody concentration over time. However, nonlinear models for antibody kinetics present substantial challenges for study design, particularly the need to provide information on the parameters of interest. We propose a novel framework to facilitate the design of immunization studies using simple, understandable information. We assume that the mean antibody concentration follows the structural form of the beta density until reaching a plateau. Using the time and height of the maximum and the time and height of the plateau, we can uniquely determine the antibody kinetics curve. Optimal sampling schedules are determined using D‐optimality, with D‐efficiency used to compare designs. In a robustness analysis across 12 scenarios, we analyzed the framework's sensitivity to misspecification in the initial information. When misspecifying one parameter at a time, the median D‐efficiencies exceeded 0.95 and the first quartiles were greater than or equal to 0.9 for all parameters, highlighting the robustness of the framework. Misspecification in the height of the plateau and time of the maximum affected the D‐efficiency the most. The great advantage of the framework is that we only need intuitive information from the medical professionals to design an immunization study, in which determining the antibody kinetics is the main goal. 10.1002/sim.70293 http://creativecommons.org/licenses/by/4.0/
doi_str_mv 10.1002/sim.70293
format Artículo Open Access
id wiley_oa_10_1002_sim_70293
institution Wiley Open Access
license_str_mv http://creativecommons.org/licenses/by/4.0/
publishDate 2025
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spellingShingle A Practical Framework to Design Immunization Studies Based on the Beta Distribution
Stefan Embacher
Andrea Berghold
Kirsten Maertens
Sereina A. Herzog
Statistics in Medicine
A Practical Framework to Design Immunization Studies Based on the Beta Distribution Stefan Embacher Andrea Berghold Kirsten Maertens Sereina A. Herzog Statistics in Medicine ABSTRACT An optimally designed experiment reaches results quicker, at a lower cost, or with fewer observations and is therefore crucial in maximizing resource efficiency in research. In immunization studies, the primary goal is often to characterize antibody kinetics—the change in antibody concentration over time. However, nonlinear models for antibody kinetics present substantial challenges for study design, particularly the need to provide information on the parameters of interest. We propose a novel framework to facilitate the design of immunization studies using simple, understandable information. We assume that the mean antibody concentration follows the structural form of the beta density until reaching a plateau. Using the time and height of the maximum and the time and height of the plateau, we can uniquely determine the antibody kinetics curve. Optimal sampling schedules are determined using D‐optimality, with D‐efficiency used to compare designs. In a robustness analysis across 12 scenarios, we analyzed the framework's sensitivity to misspecification in the initial information. When misspecifying one parameter at a time, the median D‐efficiencies exceeded 0.95 and the first quartiles were greater than or equal to 0.9 for all parameters, highlighting the robustness of the framework. Misspecification in the height of the plateau and time of the maximum affected the D‐efficiency the most. The great advantage of the framework is that we only need intuitive information from the medical professionals to design an immunization study, in which determining the antibody kinetics is the main goal. 10.1002/sim.70293 http://creativecommons.org/licenses/by/4.0/
title A Practical Framework to Design Immunization Studies Based on the Beta Distribution
topic Statistics in Medicine
url https://onlinelibrary.wiley.com/doi/10.1002/sim.70293