Comparison of Bayesian vs Frequentist Adaptive Trial Design in the Stroke Hyperglycemia Insulin Network Effort Trial

Bayesian adaptive trial design has the potential to create more efficient clinical trials. However, a barrier to the uptake of bayesian adaptive designs for confirmatory trials is limited experience with how they may perform compared with a frequentist design. To compare the performance of a bayesia...

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Bibliographic Details
Published in:JAMA network open 2022-05, Vol.5 (5), p.e2211616-e2211616
Main Authors: Broglio, Kristine, Meurer, William J, Durkalski, Valerie, Pauls, Qi, Connor, Jason, Berry, Donald, Lewis, Roger J, Johnston, Karen C, Barsan, William G
Format: Article
Language:English
Subjects:
Bayes Theorem
Clinical trials
Humans
Hyperglycemia
Hyperglycemia - drug therapy
Insulin
Insulin - therapeutic use
Insulin, Regular, Human
Neurology
Online Only
Original Investigation
Prospective Studies
Stroke
Stroke - drug therapy
United States
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Summary:Bayesian adaptive trial design has the potential to create more efficient clinical trials. However, a barrier to the uptake of bayesian adaptive designs for confirmatory trials is limited experience with how they may perform compared with a frequentist design. To compare the performance of a bayesian and a frequentist adaptive clinical trial design. This prospective cohort study compared 2 trial designs for a completed multicenter acute stroke trial conducted within a National Institutes of Health neurologic emergencies clinical trials network, with individual patient-level data, including the timing and order of enrollments and outcome ascertainment, from 1151 patients with acute stroke and hyperglycemia randomized to receive intensive or standard insulin therapy. The implemented frequentist design had group sequential boundaries for efficacy and futility interim analyses at 90 days after randomization for 500, 700, 900, and 1100 patients. The bayesian alternative used predictive probability of trial success to govern early termination for efficacy and futility with a first interim analysis at 500 randomized patients and subsequent interims after every 100 randomizations. The main outcome was the sample size at end of study, which was defined as the sample size at which each of the studies stopped accrual of patients. Data were collected from 1151 patients. As conducted, the frequentist design passed the futility boundary after 936 participants were randomized. Using the same sequence and timing of randomization and outcome data, the bayesian alternative crossed the futility boundary approximately 3 months earlier after 800 participants were randomized. Both trial designs stopped for futility before reaching the planned maximum sample size. In both cases, the clinical community and patients would benefit from learning the answer to the trial's primary question earlier. The common feature across the 2 designs was frequent interim analyses to stop early for efficacy or for futility. Differences between how these analyses were implemented between the 2 trials resulted in the differences in early stopping.
ISSN:2574-3805
2574-3805
DOI:10.1001/jamanetworkopen.2022.11616