A review of current practice in the design and analysis of extremely small stepped-wedge cluster randomized trials.

IF 2.2 3区 医学 Q3 MEDICINE, RESEARCH & EXPERIMENTAL Clinical Trials Pub Date : 2024-10-08 DOI:10.1177/17407745241276137
Guangyu Tong, Pascale Nevins, Mary Ryan, Kendra Davis-Plourde, Yongdong Ouyang, Jules Antoine Pereira Macedo, Can Meng, Xueqi Wang, Agnès Caille, Fan Li, Monica Taljaard
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Abstract

Background/aims: Stepped-wedge cluster randomized trials tend to require fewer clusters than standard parallel-arm designs due to the switches between control and intervention conditions, but there are no recommendations for the minimum number of clusters. Trials randomizing an extremely small number of clusters are not uncommon, but the justification for small numbers of clusters is often unclear and appropriate analysis is often lacking. In addition, stepped-wedge cluster randomized trials are methodologically more complex due to their longitudinal correlation structure, and ignoring the distinct within- and between-period intracluster correlations can underestimate the sample size in small stepped-wedge cluster randomized trials. We conducted a review of published small stepped-wedge cluster randomized trials to understand how and why they are used, and to characterize approaches used in their design and analysis.

Methods: Electronic searches were used to identify primary reports of full-scale stepped-wedge cluster randomized trials published during the period 2016-2022; the subset that randomized two to six clusters was identified. Two reviewers independently extracted information from each report and any available protocol. Disagreements were resolved through discussion.

Results: We identified 61 stepped-wedge cluster randomized trials that randomized two to six clusters: median sample size (Q1-Q3) 1426 (420-7553) participants. Twelve (19.7%) gave some indication that the evaluation was considered a "preliminary" evaluation and 16 (26.2%) recognized the small number of clusters as a limitation. Sixteen (26.2%) provided an explanation for the limited number of clusters: the need to minimize contamination (e.g. by merging adjacent units), limited availability of clusters, and logistical considerations were common explanations. Majority (51, 83.6%) presented sample size or power calculations, but only one assumed distinct within- and between-period intracluster correlations. Few (10, 16.4%) utilized restricted randomization methods; more than half (34, 55.7%) identified baseline imbalances. The most common statistical method for analysis was the generalized linear mixed model (44, 72.1%). Only four trials (6.6%) reported statistical analyses considering small numbers of clusters: one used generalized estimating equations with small-sample correction, two used generalized linear mixed model with small-sample correction, and one used Bayesian analysis. Another eight (13.1%) used fixed-effects regression, the performance of which requires further evaluation under stepped-wedge cluster randomized trials with small numbers of clusters. None used permutation tests or cluster-period level analysis.

Conclusion: Methods appropriate for the design and analysis of small stepped-wedge cluster randomized trials have not been widely adopted in practice. Greater awareness is required that the use of standard sample size calculation methods can provide spuriously low numbers of required clusters. Methods such as generalized estimating equations or generalized linear mixed models with small-sample corrections, Bayesian approaches, and permutation tests may be more appropriate for the analysis of small stepped-wedge cluster randomized trials. Future research is needed to establish best practices for stepped-wedge cluster randomized trials with a small number of clusters.

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对当前设计和分析极小型阶梯楔形分组随机试验实践的回顾。
背景/目的:由于对照和干预条件之间的切换,阶梯楔形分组随机试验所需的分组数往往少于标准的平行臂设计,但目前还没有关于最少分组数的建议。随机分组数量极少的试验并不少见,但分组数量少的理由往往不明确,也往往缺乏适当的分析。此外,阶梯楔形聚类随机试验因其纵向相关结构而在方法学上更为复杂,如果忽略了不同时期内和不同时期间的聚类内相关性,就会低估小型阶梯楔形聚类随机试验的样本量。我们对已发表的小阶梯楔形群组随机试验进行了综述,以了解这些试验的使用方式和原因,以及设计和分析方法的特点:通过电子检索,确定了2016年至2022年期间发表的全面阶梯式楔形分组随机试验的主要报告;确定了对2至6个分组进行随机试验的子集。两名审稿人从每份报告和任何可用的方案中独立提取信息。分歧通过讨论解决:我们确定了61项阶梯式楔形分组随机试验,这些试验随机了2至6个分组:样本量中位数(Q1-Q3)为1426(420-7553)名参与者。有 12 项(19.7%)试验表明该评价是一项 "初步 "评价,有 16 项(26.2%)试验认为分组数量少是一项限制因素。有 16 人(26.2%)对群组数量有限做出了解释:需要尽量减少污染(如通过合并相邻的 单位)、群组数量有限以及后勤方面的考虑是常见的解释。大多数研究(51 项,83.6%)提供了样本量或功率计算结果,但只有一项研究假设了不同时期内和不同时期间的群内相关性。少数研究(10 项,16.4%)采用了限制性随机方法;超过半数研究(34 项,55.7%)确定了基线不平衡。最常见的统计分析方法是广义线性混合模型(44 项,72.1%)。只有四项试验(6.6%)报告了考虑到少量分组的统计分析:一项试验使用了带小样本校正的广义估计方程,两项试验使用了带小样本校正的广义线性混合模型,一项试验使用了贝叶斯分析法。另有 8 项研究(13.1%)使用了固定效应回归法,其性能需要在具有少量聚类的阶梯楔形聚类随机试验中进一步评估。没有一项研究使用了置换检验或群组-时期水平分析:结论:适合设计和分析小型阶梯式分组随机试验的方法在实践中尚未得到广泛采用。需要进一步认识到,使用标准样本量计算方法可能会虚假地提供较低的所需分组数。广义估计方程或带小样本校正的广义线性混合模型、贝叶斯方法和置换检验等方法可能更适合分析小阶梯楔形分组随机试验。今后还需要开展研究,为具有少量分组的阶梯式楔形分组随机试验确立最佳实践。
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来源期刊
Clinical Trials
Clinical Trials 医学-医学:研究与实验
CiteScore
4.10
自引率
3.70%
发文量
82
审稿时长
6-12 weeks
期刊介绍: Clinical Trials is dedicated to advancing knowledge on the design and conduct of clinical trials related research methodologies. Covering the design, conduct, analysis, synthesis and evaluation of key methodologies, the journal remains on the cusp of the latest topics, including ethics, regulation and policy impact.
期刊最新文献
Challenges in conducting efficacy trials for new COVID-19 vaccines in developed countries. Society for Clinical Trials Data Monitoring Committee initiative website: Closing the gap. A comparison of computational algorithms for the Bayesian analysis of clinical trials. Comparison of Bayesian and frequentist monitoring boundaries motivated by the Multiplatform Randomized Clinical Trial. Efficient designs for three-sequence stepped wedge trials with continuous recruitment.
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