z-logo
Premium
Bayesian enhancement two‐stage design for single‐arm phase II clinical trials with binary and time‐to‐event endpoints
Author(s) -
Shi Haolun,
Yin Guosheng
Publication year - 2018
Publication title -
biometrics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.298
H-Index - 130
eISSN - 1541-0420
pISSN - 0006-341X
DOI - 10.1111/biom.12864
Subject(s) - event (particle physics) , binary number , bayesian probability , stage (stratigraphy) , clinical endpoint , phase (matter) , single stage , computer science , mathematics , clinical trial , medicine , statistics , physics , biology , arithmetic , engineering , quantum mechanics , paleontology , aerospace engineering
Summary Simon's two‐stage design is one of the most commonly used methods in phase II clinical trials with binary endpoints. The design tests the null hypothesis that the response rate is less than an uninteresting level, versus the alternative hypothesis that the response rate is greater than a desirable target level. From a Bayesian perspective, we compute the posterior probabilities of the null and alternative hypotheses given that a promising result is declared in Simon's design. Our study reveals that because the frequentist hypothesis testing framework places its focus on the null hypothesis, a potentially efficacious treatment identified by rejecting the null under Simon's design could have only less than 10% posterior probability of attaining the desirable target level. Due to the indifference region between the null and alternative, rejecting the null does not necessarily mean that the drug achieves the desirable response level. To clarify such ambiguity, we propose a Bayesian enhancement two‐stage (BET) design, which guarantees a high posterior probability of the response rate reaching the target level, while allowing for early termination and sample size saving in case that the drug's response rate is smaller than the clinically uninteresting level. Moreover, the BET design can be naturally adapted to accommodate survival endpoints. We conduct extensive simulation studies to examine the empirical performance of our design and present two trial examples as applications.

This content is not available in your region!

Continue researching here.

Having issues? You can contact us here