Optimal design of cluster randomized crossover trials with a continuous outcome: Optimal number of time periods and treatment switches under a fixed number of clusters or fixed budget

• Published in: Behavior research methods Vol. 56; no. 8; pp. 8820 - 8830
• Main Author: Moerbeek, Mirjam
• Format: Journal Article
• Language: English
• Published: New York Springer US 01.12.2024; Springer Nature B.V
• Subjects: Behavioral Science and Psychology; Budgets - methods; Cluster Analysis; Cognitive Psychology; Cross-Over Studies; Cross-Sectional Studies; Design optimization; Humans; Original Manuscript; Psychology; Randomized Controlled Trials as Topic - economics; Randomized Controlled Trials as Topic - methods; Research Design; Time Factors; Crossover design; Treatment switches; Relative efficiency; Cluster randomized trial; Budgetary constraint; Optimal design
• ISSN: 1554-3528; 1554-351X; 1554-3528
• DOI: 10.3758/s13428-024-02505-1

In the cluster randomized crossover trial, a sequence of treatment conditions, rather than just one treatment condition, is assigned to each cluster. This contribution studies the optimal number of time periods in studies with a treatment switch at the end of each time period, and the optimal number of treatment switches in a trial with a fixed number of time periods. This is done for trials with a fixed number of clusters, and for trials in which the costs per cluster, subject, and treatment switch are taken into account using a budgetary constraint. The focus is on trials with a cross-sectional design where a continuous outcome variable is measured at the end of each time period. An exponential decay correlation structure is used to model dependencies among subjects within the same cluster. A linear multilevel mixed model is used to estimate the treatment effect and its associated variance. The optimal design minimizes this variance. Matrix algebra is used to identify the optimal design and other highly efficient designs. For a fixed number of clusters, a design with the maximum number of time periods is optimal and treatment switches should occur at each time period. However, when a budgetary constraint is taken into account, the optimal design may have fewer time periods and fewer treatment switches. The Shiny app was developed to facilitate the use of the methodology in this contribution.