Type I Error Rates of Multi-arm Multi-stage Clinical Trials: Strong Control and Impact of Intermediate Outcomes

Overview

Journal Trials

Publisher Biomed Central

Specialties General Medicine
Pharmacology

Date 2016 Jul 3

PMID 27369182

Citations 13

Authors

Daniel J Bratton

Mahesh K B Parmar

Patrick P J Phillips

Babak Choodari-Oskooei

Affiliations

Soon will be listed here.

Abstract

Background: The multi-arm multi-stage (MAMS) design described by Royston et al. [Stat Med. 2003;22(14):2239-56 and Trials. 2011;12:81] can accelerate treatment evaluation by comparing multiple treatments with a control in a single trial and stopping recruitment to arms not showing sufficient promise during the course of the study. To increase efficiency further, interim assessments can be based on an intermediate outcome (I) that is observed earlier than the definitive outcome (D) of the study. Two measures of type I error rate are often of interest in a MAMS trial. Pairwise type I error rate (PWER) is the probability of recommending an ineffective treatment at the end of the study regardless of other experimental arms in the trial. Familywise type I error rate (FWER) is the probability of recommending at least one ineffective treatment and is often of greater interest in a study with more than one experimental arm.

Methods: We demonstrate how to calculate the PWER and FWER when the I and D outcomes in a MAMS design differ. We explore how each measure varies with respect to the underlying treatment effect on I and show how to control the type I error rate under any scenario. We conclude by applying the methods to estimate the maximum type I error rate of an ongoing MAMS study and show how the design might have looked had it controlled the FWER under any scenario.

Results: The PWER and FWER converge to their maximum values as the effectiveness of the experimental arms on I increases. We show that both measures can be controlled under any scenario by setting the pairwise significance level in the final stage of the study to the target level. In an example, controlling the FWER is shown to increase considerably the size of the trial although it remains substantially more efficient than evaluating each new treatment in separate trials.

Conclusions: The proposed methods allow the PWER and FWER to be controlled in various MAMS designs, potentially increasing the uptake of the MAMS design in practice. The methods are also applicable in cases where the I and D outcomes are identical.

Citing Articles

A Preplanned Multi-Stage Platform Trial for Discovering Multiple Superior Treatments With Control of FWER and Power.

Greenstreet P, Jaki T, Bedding A, Mozgunov P Biom J. 2024; 67(1):e70025.

PMID: 39711026 PMC: 11664203. DOI: 10.1002/bimj.70025.

Bayesian Optimal Designs for Multi-Arm Multi-Stage Phase II Randomized Clinical Trials with Multiple Endpoints.

Mulier G, Chevret S, Lin R, Biard L Stat Biopharm Res. 2024; 16(3):315-325.

PMID: 39301054 PMC: 11412438. DOI: 10.1080/19466315.2024.2344543.

A comparison of alternative ranking methods in two-stage clinical trials with multiple interventions: An application to the anxiolysis for laceration repair in children trial.

Tran N, McGrory A, Poonai N, Heath A Clin Trials. 2024; :17407745241251812.

PMID: 38771021 PMC: 11528845. DOI: 10.1177/17407745241251812.

Recent innovations in adaptive trial designs: A review of design opportunities in translational research.

Kaizer A, Belli H, Ma Z, Nicklawsky A, Roberts S, Wild J J Clin Transl Sci. 2023; 7(1):e125.

PMID: 37313381 PMC: 10260347. DOI: 10.1017/cts.2023.537.

Combining factorial and multi-arm multi-stage platform designs to evaluate multiple interventions efficiently.

White I, Choodari-Oskooei B, Sydes M, Kahan B, McCabe L, Turkova A Clin Trials. 2022; 19(4):432-441.

PMID: 35579066 PMC: 9373200. DOI: 10.1177/17407745221093577.

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