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Abstract

Background Most phase I clinical trials conducted at the M. D. Anderson Cancer Center use the algorithmic 3 + 3 design, despite the availability of more advanced model-based designs such as the continual reassessment method.

Purpose Through simple statistical modeling and computing, we develop a dose-finding design that can be easily understood and implemented by non-statisticians.

Methods We propose a beta/binomial Bayesian model and a probabilistic up-and-down rule that allow all possible dose-assignment actions to be tabulated in a spreadsheet. We have developed an Excel macro (available at http://odin.mdacc. tmc.edu/~yuanj) that generates trial monitoring tables, which contain the dose-assignment actions corresponding to various toxicity outcomes.

Results The new design outperforms the 3 + 3 design and performs comparably to other model-based methods in the literature.

Limitations The proposed method assumes that the observed toxicity is a binary variable and that toxicity increases with dose level.

Conclusion The new dose-finding design enables physicians to readily determine dose assignments for new patients by referencing a trial monitoring table. Clinical Trials 2007; 4: 235—244; http://ctj.sagepub.com

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Dose-finding in phase I clinical trials based on toxicity probability intervals

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