An introduction to the statistical analysis of stepped cluster randomized trials_Chinese Journal of Evidence-Based Medicine

Authors：

DONG Yu ^1,2 , HUANG Shanshan ^1,2 , ZHAO Mengjiao ^1,2 , ZHANG Qiao ^1,2 ,  ZENG Jingchun ³ ,  LU Liming ^1,2

1. Clinical Medical College of Acupuncture Moxibustion and Rehabilitation, Guangzhou University of Chinese Medicine, Guangzhou 510000, P. R. China;
2. South China Research Center for Acupuncture and Moxibustion, Clinical Research and Big Data Laboratory, Guangzhou University of Chinese Medicine, Guangzhou 510000, P. R. China;
3. Department of Rehabilitation, the First Affliated Hospital of Guangzhou University of Chinese Medicine, Guangzhou 510405, P. R. China;

Corresponding author：

ZENG Jingchun, Email: tcm_zjc@126.com; LU Liming, Email: lulimingleon@gzucm.edu.cn

Keywords：

Stepped wedge cluster randomized trials; SW-CRT; Cross-over design; Sample size calculation; Statistic analysis

DOI：

10.7507/1672-2531.202307125

Video：

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Stepped wedge cluster randomized trials (SW-CRT) is a kind of cluster randomized controlled trial mainly applied in the field of public health policy that has emerged in recent years, which has gradually attracted the attention of workers in the field of health and wellness. At present, this trial method is not widely used at home and abroad, and there are various ways of sample size calculation and statistical analysis. This paper describes the principles, categories, and differences between SW-CRT and traditional randomized controlled trials, and outlines sample size calculation and statistical analysis methods. In general, SW-CRT is characterized by clustering, cross-design, and measurement of results at multiple time points. In terms of sample size calculation, it is necessary to distinguish between clusters with the same and different sizes, and commonly used sample size calculation procedures can be implemented in Stata, R, and SAS software, as well as in fixed online websites, including the "Steppedwedge" program, the "swCRTdesign" program, the "Swdpwr" program, the "CRTpowerdist" program, and the "Shiny CRT Calculator" tool and so on. Based on the design characteristics of SW-CRT, the researcher should also consider the confounding factors of time effects and repeated measurements of result. Therefore, the statistical analysis methods are often based on generalized linear mixed model (GLMM) and generalized estimating equations (GEE). However, most of the above models have been proposed based on cross-sectional studies, there is a lack of statistical methods for queue design and SW-CRT with transitional period now, and more comprehensive methodological exploration is still needed in the future.

Citation： DONG Yu, HUANG Shanshan, ZHAO Mengjiao, ZHANG Qiao, ZENG Jingchun, LU Liming. An introduction to the statistical analysis of stepped cluster randomized trials. Chinese Journal of Evidence-Based Medicine, 2024, 24(3): 355-363. doi: 10.7507/1672-2531.202307125 Copy

1.	Hemming K, Lilford R, Girling AJ. Stepped-wedge cluster randomised controlled trials: a generic framework including parallel and multiple-level designs. Stat Med, 2015, 34(2): 181-196.
2.	Hemming K, Haines TP, Chilton PJ, et al. The stepped wedge cluster randomised trial: rationale, design, analysis, and reporting. BMJ, 2015, 350: h391.
3.	Hussey MA, Hughes JP. Design and analysis of stepped wedge cluster randomized trials. Contemp Clin Trials, 2007, 28(2): 182-191.
4.	Copas AJ, Lewis JJ, Thompson JA, et al. Designing a stepped wedge trial: three main designs, carry-over effects and randomisation approaches. Trials, 2015, 16: 352.
5.	Mdege ND, Man MS, Taylor Nee Brown CA, et al. Systematic review of stepped wedge cluster randomized trials shows that design is particularly used to evaluate interventions during routine implementation. J Clin Epidemiol, 2011, 64(9): 936-948.
6.	The Gambia Hepatitis Study Group. The Gambia hepatitis intervention study. Cancer Res, 1987, 47(21): 5782-5787.
7.	Brown CA, Lilford RJ. The stepped wedge trial design: a systematic review. BMC Med Res Methodol, 2006, 6: 54.
8.	Beard E, Lewis JJ, Copas A, et al. Stepped wedge randomised controlled trials: systematic review of studies published between 2010 and 2014. Trials, 2015, 16: 353.
9.	Hemming K, Taljaard M, McKenzie JE, et al. Reporting of stepped wedge cluster randomised trials: extension of the CONSORT 2010 statement with explanation and elaboration. BMJ, 2018, 363: k1614.
10.	Wu Y, Li S, Patel A, et al. Effect of a quality of care improvement initiative in patients with acute coronary syndrome in resource-constrained hospitals in China: a randomized clinical trial. JAMA Cardiol, 2019, 4(5): 418-427.
11.	So WC, Cheng CH, Law WW, et al. Robot dramas may improve joint attention of Chinese-speaking low-functioning children with autism: stepped wedge trials. Disabil Rehabil Assist Technol, 2023, 18(2): 195-204.
12.	Martin J, Taljaard M, Girling A, et al. Systematic review finds major deficiencies in sample size methodology and reporting for stepped-wedge cluster randomised trials. BMJ Open, 2016, 6(2): e010166.
13.	Barker D, McElduff P, D'Este C, et al. Stepped wedge cluster randomised trials: a review of the statistical methodology used and available. BMC Med Res Methodol, 2016, 16: 69.
14.	Thompson J, Davey C, Hayes R, et al. Swpermute: permutation tests for stepped-wedge cluster-randomised trials. Stata J, 2019, 19(4): 803-819.
15.	谢润生, 徐东, 李慧, 等. 医疗卫生领域中实施科学的研究方法. 中国循证医学杂志, 2020, 20(9): 1104-1110.
16.	冯国双. 临床研究中样本量估算的影响因素. 慢性病学杂志, 2022, 23(5): 687-690.
17.	Woertman W, de Hoop E, Moerbeek M, et al. Stepped wedge designs could reduce the required sample size in cluster randomized trials. J Clin Epidemiol, 2013, 66(7): 752-758.
18.	Hemming K, Taljaard M. Sample size calculations for stepped wedge and cluster randomised trials: a unified approach. J Clin Epidemiol, 2016, 69: 137-146.
19.	闫翔宇, 苏鹤轩, 张波, 等. 阶梯整群随机对照试验的样本量和功效计算方法. 现代预防医学, 2019, 46(23): 4229-4232,4246.
20.	Larsen DA, Bennett A, Silumbe K, et al. Population-wide malaria testing and treatment with rapid diagnostic tests and artemether-lumefantrine in southern Zambia: a community randomized step-wedge control trial design. Am J Trop Med Hyg, 2015, 92(5): 913-921.
21.	Kristunas C, Morris T, Gray L. Unequal cluster sizes in stepped-wedge cluster randomised trials: a systematic review. BMJ Open, 2017, 7(11): e017151.
22.	Martin JT, Hemming K, Girling A. The impact of varying cluster size in cross-sectional stepped-wedge cluster randomised trials. BMC Med Res Methodol, 2019, 19(1): 123.
23.	Harrison LJ, Chen T, Wang R. Power calculation for cross-sectional stepped wedge cluster randomized trials with variable cluster sizes. Biometrics, 2020, 76(3): 951-962.
24.	Girling AJ. Relative efficiency of unequal cluster sizes in stepped wedge and other trial designs under longitudinal or cross-sectional sampling. Stat Med, 2018, 37(30): 4652-4664.
25.	Hemming K, Girling A. A menu-driven facility for power and detectable-difference calculations in stepped-wedge cluster-randomized trials. Stata J, 2014, 14(2): 363-380.
26.	Baio G, Copas A, Ambler G, et al. Sample size calculation for a stepped wedge trial. Trials, 2015, 16: 354.
27.	Voldal EC, Hakhu NR, Xia F, et al. swCRTdesign: an R package for stepped wedge trial design and analysis. Comput Methods Programs Biomed, 2020, 196: 105514.
28.	Chen J, Zhou X, Li F, et al. swdpwr: a SAS macro and an R package for power calculations in stepped wedge cluster randomized trials. Comput Methods Programs Biomed, 2022, 213: 106522.
29.	Ouyang Y, Xu L, Karim ME, et al. CRTpowerdist: an R package to calculate attained power and construct the power distribution for cross-sectional stepped-wedge and parallel cluster randomized trials. Comput Methods Programs Biomed, 2021, 208: 106255.
30.	Hemming K, Kasza J, Hooper R, 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.
31.	Twisk JW, Hoogendijk EO, Zwijsen SA, et al. Different methods to analyze stepped wedge trial designs revealed different aspects of intervention effects. J Clin Epidemiol, 2016, 72: 75-83.
32.	司华新, 乔晓霞, 金雅茹, 等. 阶梯设计试验研究方法及报告规范. 中国公共卫生, 2022, 38(4): 503-509.
33.	Due TD, Thorsen T, Kousgaard MB, et al. The effectiveness of a semi-tailored facilitator-based intervention to optimise chronic care management in general practice: a stepped-wedge randomised controlled trial. BMC Fam Pract, 2014, 15: 65.
34.	Grunewaldt KH, Løhaugen GC, Austeng D, et al. Working memory training improves cognitive function in VLBW preschoolers. Pediatrics, 2013, 131(3): e747-e754.
35.	Viera AJ, Garrett JM. Preliminary study of a school-based program to improve hypertension awareness in the community. Fam Med. 2008, 40(4): 264-270.
36.	Skrøvseth SO, Årsand E, Godtliebsen F, et al. Data-driven personalized feedback to patients with type 1 diabetes: a randomized trial. Diabetes Technol Ther, 2015, 17(7): 482-489.
37.	Moulton LH, Golub JE, Durovni B, et al. Statistical design of THRio: a phased implementation clinic-randomized study of a tuberculosis preventive therapy intervention. Clin Trials, 2007, 4(2): 190-199.
38.	Fok CC, Henry D, Allen J. Research designs for intervention research with small samples Ⅱ: stepped wedge and interrupted time-series designs. Prev Sci, 2015, 16(7): 967-977.
39.	Wyman PA, Henry D, Knoblauch S, et al. Designs for testing group-based interventions with limited numbers of social units: the dynamic wait-listed and regression point displacement designs. Prev Sci, 2015, 16(7): 956-966.

1. Hemming K, Lilford R, Girling AJ. Stepped-wedge cluster randomised controlled trials: a generic framework including parallel and multiple-level designs. Stat Med, 2015, 34(2): 181-196.
2. Hemming K, Haines TP, Chilton PJ, et al. The stepped wedge cluster randomised trial: rationale, design, analysis, and reporting. BMJ, 2015, 350: h391.
3. Hussey MA, Hughes JP. Design and analysis of stepped wedge cluster randomized trials. Contemp Clin Trials, 2007, 28(2): 182-191.
4. Copas AJ, Lewis JJ, Thompson JA, et al. Designing a stepped wedge trial: three main designs, carry-over effects and randomisation approaches. Trials, 2015, 16: 352.
5. Mdege ND, Man MS, Taylor Nee Brown CA, et al. Systematic review of stepped wedge cluster randomized trials shows that design is particularly used to evaluate interventions during routine implementation. J Clin Epidemiol, 2011, 64(9): 936-948.
6. The Gambia Hepatitis Study Group. The Gambia hepatitis intervention study. Cancer Res, 1987, 47(21): 5782-5787.
7. Brown CA, Lilford RJ. The stepped wedge trial design: a systematic review. BMC Med Res Methodol, 2006, 6: 54.
8. Beard E, Lewis JJ, Copas A, et al. Stepped wedge randomised controlled trials: systematic review of studies published between 2010 and 2014. Trials, 2015, 16: 353.
9. Hemming K, Taljaard M, McKenzie JE, et al. Reporting of stepped wedge cluster randomised trials: extension of the CONSORT 2010 statement with explanation and elaboration. BMJ, 2018, 363: k1614.
10. Wu Y, Li S, Patel A, et al. Effect of a quality of care improvement initiative in patients with acute coronary syndrome in resource-constrained hospitals in China: a randomized clinical trial. JAMA Cardiol, 2019, 4(5): 418-427.
11. So WC, Cheng CH, Law WW, et al. Robot dramas may improve joint attention of Chinese-speaking low-functioning children with autism: stepped wedge trials. Disabil Rehabil Assist Technol, 2023, 18(2): 195-204.
12. Martin J, Taljaard M, Girling A, et al. Systematic review finds major deficiencies in sample size methodology and reporting for stepped-wedge cluster randomised trials. BMJ Open, 2016, 6(2): e010166.
13. Barker D, McElduff P, D'Este C, et al. Stepped wedge cluster randomised trials: a review of the statistical methodology used and available. BMC Med Res Methodol, 2016, 16: 69.
14. Thompson J, Davey C, Hayes R, et al. Swpermute: permutation tests for stepped-wedge cluster-randomised trials. Stata J, 2019, 19(4): 803-819.
15. 谢润生, 徐东, 李慧, 等. 医疗卫生领域中实施科学的研究方法. 中国循证医学杂志, 2020, 20(9): 1104-1110.
16. 冯国双. 临床研究中样本量估算的影响因素. 慢性病学杂志, 2022, 23(5): 687-690.
17. Woertman W, de Hoop E, Moerbeek M, et al. Stepped wedge designs could reduce the required sample size in cluster randomized trials. J Clin Epidemiol, 2013, 66(7): 752-758.
18. Hemming K, Taljaard M. Sample size calculations for stepped wedge and cluster randomised trials: a unified approach. J Clin Epidemiol, 2016, 69: 137-146.
19. 闫翔宇, 苏鹤轩, 张波, 等. 阶梯整群随机对照试验的样本量和功效计算方法. 现代预防医学, 2019, 46(23): 4229-4232,4246.
20. Larsen DA, Bennett A, Silumbe K, et al. Population-wide malaria testing and treatment with rapid diagnostic tests and artemether-lumefantrine in southern Zambia: a community randomized step-wedge control trial design. Am J Trop Med Hyg, 2015, 92(5): 913-921.
21. Kristunas C, Morris T, Gray L. Unequal cluster sizes in stepped-wedge cluster randomised trials: a systematic review. BMJ Open, 2017, 7(11): e017151.
22. Martin JT, Hemming K, Girling A. The impact of varying cluster size in cross-sectional stepped-wedge cluster randomised trials. BMC Med Res Methodol, 2019, 19(1): 123.
23. Harrison LJ, Chen T, Wang R. Power calculation for cross-sectional stepped wedge cluster randomized trials with variable cluster sizes. Biometrics, 2020, 76(3): 951-962.
24. Girling AJ. Relative efficiency of unequal cluster sizes in stepped wedge and other trial designs under longitudinal or cross-sectional sampling. Stat Med, 2018, 37(30): 4652-4664.
25. Hemming K, Girling A. A menu-driven facility for power and detectable-difference calculations in stepped-wedge cluster-randomized trials. Stata J, 2014, 14(2): 363-380.
26. Baio G, Copas A, Ambler G, et al. Sample size calculation for a stepped wedge trial. Trials, 2015, 16: 354.
27. Voldal EC, Hakhu NR, Xia F, et al. swCRTdesign: an R package for stepped wedge trial design and analysis. Comput Methods Programs Biomed, 2020, 196: 105514.
28. Chen J, Zhou X, Li F, et al. swdpwr: a SAS macro and an R package for power calculations in stepped wedge cluster randomized trials. Comput Methods Programs Biomed, 2022, 213: 106522.
29. Ouyang Y, Xu L, Karim ME, et al. CRTpowerdist: an R package to calculate attained power and construct the power distribution for cross-sectional stepped-wedge and parallel cluster randomized trials. Comput Methods Programs Biomed, 2021, 208: 106255.
30. Hemming K, Kasza J, Hooper R, 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.
31. Twisk JW, Hoogendijk EO, Zwijsen SA, et al. Different methods to analyze stepped wedge trial designs revealed different aspects of intervention effects. J Clin Epidemiol, 2016, 72: 75-83.
32. 司华新, 乔晓霞, 金雅茹, 等. 阶梯设计试验研究方法及报告规范. 中国公共卫生, 2022, 38(4): 503-509.
33. Due TD, Thorsen T, Kousgaard MB, et al. The effectiveness of a semi-tailored facilitator-based intervention to optimise chronic care management in general practice: a stepped-wedge randomised controlled trial. BMC Fam Pract, 2014, 15: 65.
34. Grunewaldt KH, Løhaugen GC, Austeng D, et al. Working memory training improves cognitive function in VLBW preschoolers. Pediatrics, 2013, 131(3): e747-e754.
35. Viera AJ, Garrett JM. Preliminary study of a school-based program to improve hypertension awareness in the community. Fam Med. 2008, 40(4): 264-270.
36. Skrøvseth SO, Årsand E, Godtliebsen F, et al. Data-driven personalized feedback to patients with type 1 diabetes: a randomized trial. Diabetes Technol Ther, 2015, 17(7): 482-489.
37. Moulton LH, Golub JE, Durovni B, et al. Statistical design of THRio: a phased implementation clinic-randomized study of a tuberculosis preventive therapy intervention. Clin Trials, 2007, 4(2): 190-199.
38. Fok CC, Henry D, Allen J. Research designs for intervention research with small samples Ⅱ: stepped wedge and interrupted time-series designs. Prev Sci, 2015, 16(7): 967-977.
39. Wyman PA, Henry D, Knoblauch S, et al. Designs for testing group-based interventions with limited numbers of social units: the dynamic wait-listed and regression point displacement designs. Prev Sci, 2015, 16(7): 956-966.

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