An overview of optimal designs under a given budget in cluster randomized trials with a binary outcome

Abstract

Cluster randomized trial design may raise financial concerns because the cost to recruit an additional cluster is much higher than to enroll an additional subject in subject-level randomized trials. Therefore, it is desirable to develop an optimal design. For local optimal designs, optimization means the minimum variance of the estimated treatment effect under the total budget. The local optimal design derived from the variance needs the input of an association parameter $ρ$ in terms of a “working” correlation structure $R (ρ)$ in the generalized estimating equation models. When the range of $ρ$ instead of an exact value is available, the parameter space is defined as the range of $ρ$ and the design space is defined as enrollment feasibility, for example, the number of clusters or cluster size. For any value $ρ$ within the range, the optimal design and relative efficiency for each design in the design space is obtained. Then, for each design in the design space, the minimum relative efficiency within the parameter space is calculated. MaxiMin design is the optimal design that maximizes the minimum relative efficiency among all designs in the design space. Our contributions are threefold. First, for three common measures (risk difference, risk ratio, and odds ratio), we summarize all available local optimal designs and MaxiMin designs utilizing generalized estimating equation models when the group allocation proportion is predetermined for two-level and three-level parallel cluster randomized trials. We then propose the local optimal designs and MaxiMin designs using the same models when the group allocation proportion is undecided. Second, for partially nested designs, we develop the optimal designs for three common measures under the setting of equal number of subjects per cluster and exchangeable working correlation structure in the intervention group. Third, we create three new Statistical Analysis System (SAS) macros and update two existing SAS macros for all the optimal designs. We provide two examples to illustrate our methods.

Keywords

Cluster randomized trial generalized estimating equation local optimal design MaxiMin design partially nested design two-level parallel CRTs three-level parallel CRTs

Get full access to this article

View all access options for this article.

References

Campbell

Mollison

Steen

, et al. Analysis of cluster randomized trials in primary care: a practical approach. Fam Pract 2000; 17: 192–196.

Gulliford

van Staa

McDermott

, et al. Cluster randomized trials utilizing primary care electronic health records: methodological issues in design, conduct, and analysis (eCRT study). Trials 2014; 15: 220.

Kalfon

Mimoz

Loundou

, et al. Reduction of self-perceived discomforts in critically ill patients in French intensive care units: study protocol for a cluster-randomized controlled trial. Trials 2016; 17: 87.

Mehring

Haag

Linde

, et al. Effects of a web-based intervention for stress reduction in primary care: a cluster randomized controlled trial. J Med Internet Res 2016; 18: e27.

Yamagata

Makino

Iseki

, et al. Effect of behavior modification on outcome in early- to moderate-stage chronic kidney disease: a cluster-randomized trial. PLoS one 2016; 11: e0151422.

Brownson

Colditz

Proctor

. Dissemination and implementation research in health: translating science to practice. Oxford, England: Oxford University Press, 2018, pp.385–400.

James

Richardson

Wang

, et al. Systems intervention to promote colon cancer screening in safety net settings: protocol for a community-based participatory randomized controlled trial. Implement Sci 2013; 8: 58.

Gravenstein

Dahal

Gozalo

, et al. A cluster randomized controlled trial comparing relative effectiveness of two licensed influenza vaccines in US nursing homes: design and rationale. Clin Trials 2016; 13: 264–274.

Thombs

Kwakkenbos

Carrier

, et al. Protocol for a partially nested randomised controlled trial to evaluate the effectiveness of the scleroderma patient-centered intervention network COVID-19 home-isolation activities together (SPIN-CHAT) program to reduce anxiety among at-risk scleroderma patients. J Psychosom Res 2020; 135: 110132.

10.

Moerbeek

Van Breukelen

Berger

. Design issues for experiments in multilevel populations. J Educ Behav Stat 2000; 25: 271–284.

11.

Heo

Leon

. Statistical power and sample size requirements for three level hierarchical cluster randomized trials. Biometrics 2008; 64: 1256–1262.

12.

Teerenstra

Moerbeek

van Achterberg

, et al. Sample size calculations for 3-level cluster randomized trials. Clin Trials 2008; 5: 486–495.

13.

Fazzari

Kim

Heo

. Sample size determination for three-level randomized clinical trials with randomization at the first or second level. J Biopharm Stat 2014; 24: 579–599.

14.

Hedges

Borenstein

. Conditional optimal design in three- and four-level experiments. J Educ Behav Stat 2014; 39: 257–281.

15.

Cunningham

Johnson

. Design effects for sample size computation in three-level designs. Stat Methods Med Res 2016; 25: 505–519.

16.

Liang

K-Y

Zeger

. Longitudinal data analysis using generalized linear models. Biometrika 1986; 73: 13–22.

17.

Raudenbush

. Statistical analysis and optimal design for cluster randomized trials. Psychol Methods 1997; 2: 173–185.

18.

Van Breukelen

Candel

. Efficient design of cluster randomized and multicentre trials with unknown intraclass correlation. Stat Methods Med Res 2015; 24: 540–556.

19.

Liu

Colditz

. Optimal design of longitudinal data analysis using generalized estimating equation models. Biom J 2017; 59: 315–330.

20.

Teerenstra

Preisser

, et al. Sample size considerations for GEE analyses of three-level cluster randomized trials. Biometrics 2010; 66: 1230–1237.

21.

Liu

Colditz

. Optimal designs in three-level cluster randomized trials with a binary outcome. Stat Med 2019; 38: 3733–3746.

22.

Roberts

Batistatou

Roberts

. Design and analysis of trials with a partially nested design and a binary outcome measure. Stat Med 2016; 35: 1616–1636.

23.

Moerbeek

Wong

. Sample size formulae for trials comparing group and individual treatments in a multilevel model. Stat Med 2008; 27: 2850–2864.

24.

Liu

Colditz

. Relative efficiency of unequal versus equal cluster sizes in cluster randomized trials using generalized estimating equation models. Biom J 2018; 60: 616–638.

25.

Wong

Crespi

. Maximin optimal designs for cluster randomized trials. Biometrics 2017; 73: 916–926.

26.

van Breukelen

GJP

Candel

MJJM

. Maximin design of cluster randomized trials with heterogeneous costs and variances. Biom J 2021; 63: 1444–1463.

27.

Neuhaus

Segal

. Design effects for binary regression models fitted to dependent data. Stat Med 1993; 12: 1259–1268.

28.

Scott

Holt

. The effect of two-stage sampling on ordinary least squares methods. J Am Stat Assoc 1982; 77: 848–854.

29.

Turner

Preisser

. Sample size determination for GEE analyses of stepped wedge cluster randomized trials. Biometrics 2018; 74: 1450–1458.

30.

Thombs

Kwakkenbos

Levis

, et al. Effects of a multi-faceted education and support programme on anxiety symptoms among people with systemic sclerosis and anxiety during COVID-19 (SPIN-CHAT): a two-arm parallel, partially nested, randomised, controlled trial. The Lancet Rheumatology 2021; 3: e427–ee37.

31.

van Breukelen

GJP

Candel

. Efficient design of cluster randomized trials with treatment-dependent costs and treatment-dependent unknown variances. Stat Med 2018; 37: 3027–3046.

32.

Durovni

Saraceni

Moulton

, et al. Effect of improved tuberculosis screening and isoniazid preventive therapy on incidence of tuberculosis and death in patients with HIV in clinics in Rio de Janeiro, Brazil: a stepped wedge, cluster-randomised trial. Lancet Infect Dis 2013; 13: 852–858.

33.

Fuller

Michie

Savage

, et al. The feedback intervention trial (FIT)—improving hand-hygiene compliance in UK healthcare workers: a stepped wedge cluster randomised controlled trial. PLoS ONE 2012; 7: e41617.

34.

Haugen

Søfteland

Almeland

, et al. Effect of the world health organization checklist on patient outcomes: a stepped wedge cluster randomized controlled trial. Ann Surg 2015; 261: 821–828.

35.

Holle

Halek

Mayer

, et al. The influence of understanding diagnostics on perceived stress of nurses caring for nursing home residents with dementia. Pflege 2011; 24: 303–316.

36.

Hulscher

Laurant

Grol

. Process evaluation on quality improvement interventions. Qual Saf Health Care 2003; 12: 40–46.

37.

Killam

Tambatamba

Chintu

, et al. Antiretroviral therapy in antenatal care to increase treatment initiation in HIV-infected pregnant women: a stepped-wedge evaluation. AIDS 2010; 24: 85–91.

38.

Mhurchu C

Turley

Gorton

, et al. Effects of a free school breakfast programme on school attendance, achievement, psychosocial function, and nutrition: a stepped wedge cluster randomised trial. BMC Public Health 2010; 10: 738.

39.

Zhan

van den Heuvel

Doornbos

, et al. Strengths and weaknesses of a stepped wedge cluster randomized design: its application in a colorectal cancer follow-up study. J Clin Epidemiol 2014; 67: 454–461.

40.

Copas

Lewis

Thompson

, et al. Designing a stepped wedge trial: three main designs, carry-over effects and randomisation approaches. Trials 2015; 16: 352.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.01 MB

0.02 MB

0.01 MB