Sage Journals: Discover world-class research

Abstract

Background:

Sample size calculations for longitudinal cluster randomised trials, such as crossover and stepped-wedge trials, require estimates of the assumed correlation structure. This includes both within-period intra-cluster correlations, which importantly differ from conventional intra-cluster correlations by their dependence on period, and also cluster autocorrelation coefficients to model correlation decay. There are limited resources to inform these estimates. In this article, we provide a repository of correlation estimates from a bank of real-world clustered datasets. These are provided under several assumed correlation structures, namely exchangeable, block-exchangeable and discrete-time decay correlation structures.

Methods:

Longitudinal studies with clustered outcomes were collected to form the CLustered OUtcome Dataset bank. Forty-four available continuous outcomes from 29 datasets were obtained and analysed using each correlation structure. Patterns of within-period intra-cluster correlation coefficient and cluster autocorrelation coefficients were explored by study characteristics.

Results:

The median within-period intra-cluster correlation coefficient for the discrete-time decay model was 0.05 (interquartile range: 0.02–0.09) with a median cluster autocorrelation of 0.73 (interquartile range: 0.19–0.91). The within-period intra-cluster correlation coefficients were similar for the exchangeable, block-exchangeable and discrete-time decay correlation structures. Within-period intra-cluster correlation coefficients and cluster autocorrelations were found to vary with the number of participants per cluster-period, the period-length, type of cluster (primary care, secondary care, community or school) and country income status (high-income country or low- and middle-income country). The within-period intra-cluster correlation coefficients tended to decrease with increasing period-length and slightly decrease with increasing cluster-period sizes, while the cluster autocorrelations tended to move closer to 1 with increasing cluster-period size. Using the CLustered OUtcome Dataset bank, an RShiny app has been developed for determining plausible values of correlation coefficients for use in sample size calculations.

Discussion:

This study provides a repository of intra-cluster correlations and cluster autocorrelations for longitudinal cluster trials. This can help inform sample size calculations for future longitudinal cluster randomised trials.

Keywords

Intra-cluster correlation coefficient within-period correlation between-period correlation cluster autocorrelation discrete-time decay cluster randomised trial sample size

Get full access to this article

View all access options for this article.

References

Eldridge

Kerry

. A practical guide to cluster randomised trials in health services research. London: John Wiley & Sons, 2012.

Hemming

Kasza

Hooper

, et al. A tutorial on sample size calculation for multiple-period cluster randomized parallel, cross-over and stepped-wedge trials using the Shiny CRT Calculator. Int J Epidemiol 2020; 49(3): 979–995.

Hemming

Haines

Chilton

, et al. The stepped wedge cluster randomised trial: rationale, design, analysis, and reporting. BMJ 2015; 350: h391.

Grantham

Kasza

Heritier

, et al. How many times should a cluster randomized crossover trial cross over? Stat Med 2019; 38: 5021–5033.

Arnup

Forbes

Kahan

, et al. Appropriate statistical methods were infrequently used in cluster-randomized crossover trials. J Clin Epidemiol 2016; 74: 40–50.

Teerenstra

Eldridge

Graff

, et al. A simple sample size formula for analysis of covariance in cluster randomized trials. Stat Med 2012; 31: 2169–2178.

Hussey

Hughes

. Design and analysis of stepped wedge cluster randomized trials. Contemp Clin Trials 2007; 28: 182–191.

Hooper

Teerenstra

de Hoop

, et al. Sample size calculation for stepped wedge and other longitudinal cluster randomised trials. Stat Med 2016; 35: 4718–4728.

Girling

Hemming

. Statistical efficiency and optimal design for stepped cluster studies under linear mixed effects models. Stat Med 2016; 35: 2149–2166.

10.

Kasza

Hemming

Hooper

, et al. Impact of non-uniform correlation structure on sample size and power in multiple-period cluster randomised trials. Stat Methods Med Res 2019; 28(3): 703–716.

11.

Feldman

McKinlay

. Cohort versus cross-sectional design in large field trials: precision, sample size, and a unifying model. Stat Med 1994; 13: 61–78.

12.

Adams

Gulliford

Ukoumunne

, et al. Patterns of intra-cluster correlation from primary care research to inform study design and analysis. J Clin Epidemiol 2004; 57(8): 785–794.

13.

Campbell

Fayers

Grimshaw

. Determinants of the intracluster correlation coefficient in cluster randomized trials: the case of implementation research. Clin Trials 2005; 2(2): 99–107.

14.

Lajos

Haddad

Tedesco

, et al. Intracluster correlation coefficients for the Brazilian Multicenter Study on Preterm Birth (EMIP): methodological and practical implications. BMC Med Res Methodol 2014; 14: 54.

15.

Pagel

Prost

Lewycka

, et al. Intracluster correlation coefficients and coefficients of variation for perinatal outcomes from five cluster-randomised controlled trials in low and middle-income countries: results and methodological implications. Trials 2011; 12: 151.

16.

Thompson

Fernald

Mold

. Intraclass correlation coefficients typical of cluster-randomized studies: estimates from the Robert Wood Johnson Prescription for Health projects. Ann Fam Med 2012; 10(3): 235–240.

17.

Martin

Girling

Nirantharakumar

, et al. Intra-cluster and inter-period correlation coefficients for cross-sectional cluster randomised controlled trials for type-2 diabetes in UK primary care. Trials 2016; 17: 402.

18.

Chang

Cheng

Allaire

, et al. Shiny: web application framework for R, R package version 1.1. 0, 2018, https://cran.r-project.org/web/packages/shiny/index.html

19.

Hughes

Hemming

, et al. Mixed-effects models for the design and analysis of stepped wedge cluster randomized trials: an overview. Stat Methods Med Res 2021; 30(2): 612–639.

20.

Kasza

Hooper

Copas

, et al. Sample size and power calculations for open cohort longitudinal cluster randomized trials. Stat Med 2020; 39(13): 1871–1883.

21.

Mason

Wood

Freemantle

. Designing evaluations of interventions to change professional practice. J Health Serv Res Policy 1999; 4(2): 106–111.

22.

The World Bank. World Bank country and lending groups, https://datahelpdesk.worldbank.org/knowledgebase/articles/906519-world-bank-country-and-lending-groups (accessed 23 September 2020).

23.

Ballard

Corbett

Orrell

, et al. Impact of person-centred care training and person-centred activities on quality of life, agitation, and antipsychotic use in people with dementia living in nursing homes: a cluster-randomised controlled trial. PLoS Med 2018; 15(2): e1002500.

24.

Blair

Raver

. Closing the achievement gap through modification of neurocognitive and neuroendocrine function: results from a cluster randomized controlled trial of an innovative approach to the education of children in kindergarten. PLoS One 2014; 9(11): e112393.

25.

Llaurado

Tarro

Morina

, et al. EdAl-2 (Educacio en Alimentacio) programme: reproducibility of a cluster randomised, interventional, primary-school-based study to induce healthier lifestyle activities in children. BMJ Open 2014; 4: e005496.

26.

Ogedegbe

Plange-Rhule

Gyamfi

, et al. Health insurance coverage with or without a nurse-led task shifting strategy for hypertension control: a pragmatic cluster randomized trial in Ghana. PLoS Med 2018; 15(5): e1002561.

27.

Rockers

Zanolini

Banda

, et al. Two-year impact of community-based health screening and parenting groups on child development in Zambia: follow-up to a cluster-randomized controlled trial. PLoS Med 2018; 15(4): e1002555.

28.

Tannenbaum

Agnew

Benedetti

, et al. Effectiveness of continence promotion for older women via community organisations: a cluster randomised trial. BMJ Open 2013; 3(12): e004135.

29.

Chibanda

Weiss

Verhey

, et al. Effect of a primary care-based psychological intervention on symptoms of common mental disorders in Zimbabwe: a randomized clinical trial. JAMA 2016; 316: 2618–2626.

30.

Cresswell

Ganaba

Sarrassat

, et al. The effect of the Alive & Thrive initiative on exclusive breastfeeding in rural Burkina Faso: a repeated cross-sectional cluster randomised controlled trial. Lancet Glob Health 2019; 7: e357–e365.

31.

Andrew

Attanasio

Fitzsimons

, et al. Impacts 2 years after a scalable early childhood development intervention to increase psychosocial stimulation in the home: a follow-up of a cluster randomised controlled trial in Colombia. PLoS Med 2018; 15(4): e1002556.

32.

Fairall

Folb

Timmerman

, et al. Educational outreach with an integrated clinical tool for nurse-led non-communicable chronic disease management in primary care in south africa: a pragmatic cluster randomised controlled trial. PLoS Med 2016; 13(11): e1002178.

33.

Grijalva-Eternod

Jelle

Haghparast-Bidgoli

, et al. A cash-based intervention and the risk of acute malnutrition in children aged 6-59 months living in internally displaced persons camps in Mogadishu, Somalia: a non-randomised cluster trial. PLoS Med 2018; 15(10): e1002684.

34.

Haines

Bowles

Mitchell

, et al. Impact of disinvestment from weekend allied health services across acute medical and surgical wards: 2 stepped-wedge cluster randomised controlled trials. PLoS Med 2017; 14(10): e1002412.

35.

Lombard

Harrison

Kozica

, et al. Preventing weight gain in women in rural communities: a cluster randomised controlled trial. PLoS Med 2016; 13(1): e1001941.

36.

Menon

Nguyen

Saha

, et al. Impacts on breastfeeding practices of at-scale strategies that combine intensive interpersonal counseling, mass media, and community mobilization: results of cluster-randomized program evaluations in Bangladesh and Viet Nam. PLoS Med 2016; 13(10): e1002159.

37.

Merom

Mathieu

Cerin

, et al. Social dancing and incidence of falls in older adults: a cluster randomised controlled trial. PLoS Med 2016; 13(8): e1002112.

38.

Nickless

Voysey

Geddes

, et al. Mixed effects approach to the analysis of the stepped wedge cluster randomised trial-Investigating the confounding effect of time through simulation. PLoS ONE 2018; 13(12): e0208876.

39.

Thankappan

Sathish

Tapp

, et al. A peer-support lifestyle intervention for preventing type 2 diabetes in India: a cluster-randomized controlled trial of the Kerala Diabetes Prevention Program. PLoS Med 2018; 15(6): e1002575.

40.

Perra

. Cluster randomised trial of the ready to learn programme for children starting school 2010-2013. Colchester: UK Data Service, 2019.

41.

Thiruganasambandamoorthy

Kwong

Wells

, et al. Development of the Canadian Syncope Risk Score to predict serious adverse events after emergency department assessment of syncope. CMAJ 2016; 188: E289–E298.

42.

Liddy

Hogg

Singh

, et al. A real-world stepped wedge cluster randomized trial of practice facilitation to improve cardiovascular care. Implement Sci 2015; 10: 150.

43.

Stow

Hart

Higlett

, et al. Development and implementation of a high-quality clinical database: the Australian and New Zealand intensive care society adult patient database. J Crit Care 2006; 21(2): 133–141.

44.

Tirlea

Truby

Haines

. Pragmatic, randomized controlled trials of the girls on the go! Program to improve self-esteem in girls. Am J Health Promot 2016; 30(4): 231–241.

45.

Turner

Kelly

Clarke

, et al. A tiered multidisciplinary approach to the psychosocial care of adult cancer patients integrated into routine care: the PROMPT study (a cluster-randomised controlled trial). Support Care Cancer 2017; 25(1): 17–26.

46.

Grantham

Kasza

Heritier

, et al. Accounting for a decaying correlation structure in cluster randomized trials with continuous recruitment. Stat Med 2019; 38: 1918–1934.

47.

Donner

. An empirical study of cluster randomization. Int J Epidemiol 1982; 11(3): 283–286.

48.

Gulliford

Ukoumunne

Chinn

. Components of variance and intraclass correlations for the design of community-based surveys and intervention studies: data from the Health Survey for England 1994. Am J Epidemiol 1999; 149: 876–883.

49.

Hooper

Bourke

. Cluster randomised trials with repeated cross sections: alternatives to parallel group designs. BMJ 2015; 350: h2925.

50.

Hooper

Copas

. Stepped wedge trials with continuous recruitment require new ways of thinking. J Clin Epidemiol 2019; 116: 161–166.

51.

Forbes

Turner

, et al. Power and sample size requirements for GEE analyses of cluster randomized crossover trials. Stat Med 2019; 38: 636–649.

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

0.75 MB

Intra-cluster correlations from the CLustered OUtcome Dataset bank to inform the design of longitudinal cluster trials

Abstract

Background:

Methods:

Results:

Discussion:

Keywords

Get full access to this article

References

Supplementary Material