Power and Sample Size Calculations for the Restricted Mean Time Analysis of Prioritized Composite Endpoints.

IF 1.5 4区医学 Q3 MATHEMATICAL & COMPUTATIONAL BIOLOGY Statistics in Biopharmaceutical Research Pub Date : 2023-01-01 DOI:10.1080/19466315.2022.2110936

Lu Mao

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引用次数: 2

Abstract

As a new way of reporting treatment effect, the restricted mean time in favor (RMT-IF) of treatment measures the net average time the treated have had a less serious outcome than the untreated over a specified time window. With multiple outcomes of differing severity, this offers a more interpretable and data-efficient alternative to the prototypical restricted mean (event-free) survival time. To facilitate its adoption in actual trials, we develop simple approaches to power and sample size calculations and implement them in user-friendly R programs. In doing so we model the bivariate outcomes of death and a nonfatal event using a Gumbel-Hougaard copula with component-wise proportional hazards structures, under which the RMT-IF estimand is derived in closed form. In a standard set-up for censoring, the variance of the nonparametric effect-size estimator is simplified and computed via a hybrid of numerical and Monte Carlo integrations, allowing us to compute the power and sample size as functions of component-wise hazard ratios. Simulation studies show that these formulas provide accurate approximations in realistic settings. To illustrate our methods, we consider designing a new trial to evaluate treatment effect on the composite outcomes of death and cancer relapse in lymph node-positive breast cancer patients, with baseline parameters calculated from a previous study.

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优先复合端点限制平均时间分析的功率和样本量计算。

作为一种报告治疗效果的新方法，治疗的限制平均有利时间(RMT-IF)衡量的是在指定的时间窗口内，治疗组比未治疗组预后较轻的净平均时间。对于不同严重程度的多种结果，这为典型的受限平均(无事件)生存时间提供了更可解释和数据效率更高的替代方案。为了便于在实际试验中采用，我们开发了简单的方法来计算功率和样本量，并在用户友好的R程序中实现它们。在这样做的过程中，我们使用Gumbel-Hougaard copula和成分比例风险结构来模拟死亡和非致命事件的双变量结果，在这种情况下，RMT-IF估计以封闭形式导出。在审查的标准设置中，非参数效应大小估计量的方差通过数值和蒙特卡罗积分的混合进行简化和计算，使我们能够计算功率和样本量作为成分风险比的函数。仿真研究表明，这些公式在实际情况下提供了准确的近似值。为了说明我们的方法，我们考虑设计一项新的试验来评估治疗对淋巴结阳性乳腺癌患者死亡和癌症复发的复合结局的影响，基线参数从先前的研究中计算出来。

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来源期刊

Statistics in Biopharmaceutical Research MATHEMATICAL & COMPUTATIONAL BIOLOGY-STATISTICS & PROBABILITY

CiteScore

3.90

自引率

16.70%

发文量

期刊介绍： Statistics in Biopharmaceutical Research ( SBR), publishes articles that focus on the needs of researchers and applied statisticians in biopharmaceutical industries; academic biostatisticians from schools of medicine, veterinary medicine, public health, and pharmacy; statisticians and quantitative analysts working in regulatory agencies (e.g., U.S. Food and Drug Administration and its counterpart in other countries); statisticians with an interest in adopting methodology presented in this journal to their own fields; and nonstatisticians with an interest in applying statistical methods to biopharmaceutical problems. Statistics in Biopharmaceutical Research accepts papers that discuss appropriate statistical methodology and information regarding the use of statistics in all phases of research, development, and practice in the pharmaceutical, biopharmaceutical, device, and diagnostics industries. Articles should focus on the development of novel statistical methods, novel applications of current methods, or the innovative application of statistical principles that can be used by statistical practitioners in these disciplines. Areas of application may include statistical methods for drug discovery, including papers that address issues of multiplicity, sequential trials, adaptive designs, etc.; preclinical and clinical studies; genomics and proteomics; bioassay; biomarkers and surrogate markers; models and analyses of drug history, including pharmacoeconomics, product life cycle, detection of adverse events in clinical studies, and postmarketing risk assessment; regulatory guidelines, including issues of standardization of terminology (e.g., CDISC), tolerance and specification limits related to pharmaceutical practice, and novel methods of drug approval; and detection of adverse events in clinical and toxicological studies. Tutorial articles also are welcome. Articles should include demonstrable evidence of the usefulness of this methodology (presumably by means of an application). The Editorial Board of SBR intends to ensure that the journal continually provides important, useful, and timely information. To accomplish this, the board strives to attract outstanding articles by seeing that each submission receives a careful, thorough, and prompt review. Authors can choose to publish gold open access in this journal.