Value of Information Methods to Design a Clinical Trial in a Small Population to Optimise a Health Economic Utility Function

Overview

Journal BMC Med Res Methodol

Publisher Biomed Central

Specialties General Medicine
Health Services

Date 2018 Feb 10

PMID 29422021

Citations 8

Authors

Michael Pearce

Siew Wan Hee

Jason Madan

Martin Posch

Simon Day

Frank Miller

Sarah Zohar

Nigel Stallard

Affiliations

Soon will be listed here.

Abstract

Background: Most confirmatory randomised controlled clinical trials (RCTs) are designed with specified power, usually 80% or 90%, for a hypothesis test conducted at a given significance level, usually 2.5% for a one-sided test. Approval of the experimental treatment by regulatory agencies is then based on the result of such a significance test with other information to balance the risk of adverse events against the benefit of the treatment to future patients. In the setting of a rare disease, recruiting sufficient patients to achieve conventional error rates for clinically reasonable effect sizes may be infeasible, suggesting that the decision-making process should reflect the size of the target population.

Methods: We considered the use of a decision-theoretic value of information (VOI) method to obtain the optimal sample size and significance level for confirmatory RCTs in a range of settings. We assume the decision maker represents society. For simplicity we assume the primary endpoint to be normally distributed with unknown mean following some normal prior distribution representing information on the anticipated effectiveness of the therapy available before the trial. The method is illustrated by an application in an RCT in haemophilia A. We explicitly specify the utility in terms of improvement in primary outcome and compare this with the costs of treating patients, both financial and in terms of potential harm, during the trial and in the future.

Results: The optimal sample size for the clinical trial decreases as the size of the population decreases. For non-zero cost of treating future patients, either monetary or in terms of potential harmful effects, stronger evidence is required for approval as the population size increases, though this is not the case if the costs of treating future patients are ignored.

Conclusions: Decision-theoretic VOI methods offer a flexible approach with both type I error rate and power (or equivalently trial sample size) depending on the size of the future population for whom the treatment under investigation is intended. This might be particularly suitable for small populations when there is considerable information about the patient population.

Citing Articles

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Innovations in Clinical Development in Rare Diseases of Children and Adults: Small Populations and/or Small Patients.

Beckman R, Antonijevic Z, Ghadessi M, Xu H, Chen C, Liu Y Paediatr Drugs. 2022; 24(6):657-669.

PMID: 36241954 DOI: 10.1007/s40272-022-00538-7.

The Value of the Information That Can Be Generated: Optimizing Study Design to Enable the Study of Treatments Addressing an Unmet Need for Rare Pathogens.

Dane A, Rex J, Newell P, Stallard N Open Forum Infect Dis. 2022; 9(7):ofac266.

PMID: 35854983 PMC: 9290570. DOI: 10.1093/ofid/ofac266.

A framework for assessing the impact of accelerated approval.

Gould A, Campbell R, Loewy J, Beckman R, Dey J, Schiel A PLoS One. 2022; 17(6):e0265712.

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Collaborative Platform Trials to Fight COVID-19: Methodological and Regulatory Considerations for a Better Societal Outcome.

Collignon O, Burman C, Posch M, Schiel A Clin Pharmacol Ther. 2021; 110(2):311-320.

PMID: 33506495 PMC: 8014457. DOI: 10.1002/cpt.2183.

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