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. 2023 Apr 22;23(1):97.
doi: 10.1186/s12874-023-01925-5.

Hierarchical network meta-analysis models for synthesis of evidence from randomised and non-randomised studies

Humaira Hussein  1 Keith R Abrams  2   3 Laura J Gray  1 Sumayya Anwer  4 Sofia Dias  4 Sylwia Bujkiewicz  5
Affiliations

Hierarchical network meta-analysis models for synthesis of evidence from randomised and non-randomised studies

Humaira Hussein et al. BMC Med Res Methodol. .

Abstract

Background: With the increased interest in the inclusion of non-randomised data in network meta-analyses (NMAs) of randomised controlled trials (RCTs), analysts need to consider the implications of the differences in study designs as such data can be prone to increased bias due to the lack of randomisation and unmeasured confounding. This study aims to explore and extend a number of NMA models that account for the differences in the study designs, assessing their impact on the effect estimates and uncertainty.

Methods: Bayesian random-effects meta-analytic models, including naïve pooling and hierarchical models differentiating between the study designs, were extended to allow for the treatment class effect and accounting for bias, with further extensions allowing for bias terms to vary depending on the treatment class. Models were applied to an illustrative example in type 2 diabetes; using data from a systematic review of RCTs and non-randomised studies of two classes of glucose-lowering medications: sodium-glucose co-transporter 2 inhibitors and glucagon-like peptide-1 receptor agonists.

Results: Across all methods, the estimated mean differences in glycated haemoglobin after 24 and 52 weeks remained similar with the inclusion of observational data. The uncertainty around these estimates reduced when conducting naïve pooling, compared to NMA of RCT data alone, and remained similar when applying hierarchical model allowing for class effect. However, the uncertainty around these effect estimates increased when fitting hierarchical models allowing for the differences in study design. The impact on uncertainty varied between treatments when applying the bias adjustment models. Hierarchical models and bias adjustment models all provided a better fit in comparison to the naïve-pooling method.

Conclusions: Hierarchical and bias adjustment NMA models accounting for study design may be more appropriate when conducting a NMA of RCTs and observational studies. The degree of uncertainty around the effectiveness estimates varied depending on the method but use of hierarchical models accounting for the study design resulted in increased uncertainty. Inclusion of non-randomised data may, however, result in inferences that are more generalisable and the models accounting for the differences in the study design allow for more detailed and appropriate modelling of complex data, preventing overly optimistic conclusions.

Keywords: Bias adjustment; Evidence synthesis; Hierarchical models; Real world evidence.

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Conflict of interest statement

KRA is a member of the National Institute for Health and Care Excellence (NICE) Diagnostics Advisory Committee, the NICE Decision and Technical Support Units, and is a National Institute for Health Research (NIHR) Senior Investigator Emeritus [NF-SI-0512-10159]. He has served as a paid consultant, providing unrelated methodological and strategic advice, to the pharmaceutical and life sciences industry generally, as well as to DHSC/NICE, and has received unrelated research funding from Association of the British Pharmaceutical Industry (ABPI), European Federation of Pharmaceutical Industries & Associations (EFPIA), Pfizer, Sanofi and Swiss Precision Diagnostics/Clearblue. He has also received course fees from the Association of the British Pharmaceutical Industry (ABPI) and is a Partner and Director of Visible Analytics Limited, a health technology assessment consultancy company.

SD has received course fees from the ABPI.

SB is a member of the NICE Decision Support Unit. She has served as a paid consultant, providing methodological advice, to NICE, Roche, RTI Health Solutions and IQVIA, received payments for educational events from Roche and has received research funding from European Federation of Pharmaceutical Industries & Associations (EEPIA) and Johnson & Johnson.

All other authors have no competing interest to declare.

Figures

Fig. 1
Fig. 1
Network plots for the network meta-analysis of HbA1c (%) at 24 weeks and 52 weeks. Nodes represent treatments with sizes of the nodes proportional to the number of participants and the lines represent the direct comparisons between any two treatments with the width of the line proportional to the number of studies per contrast
Fig. 2
Fig. 2
Network meta-analysis forest plots for analysis of HbA1c at 24 and 52 weeks using the naive pooling method. Note that for some of the treatments evidence was available only from either RCTs or from the non-randomised studies (denoted by OBS)
See this image and copyright information in PMC

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