{"title":"解决精准医学中的不朽时间偏差:实用指南和方法开发。","authors":"Deirdre Weymann, Emanuel Krebs, Dean A Regier","doi":"10.1111/1475-6773.14376","DOIUrl":null,"url":null,"abstract":"<p><strong>Objective: </strong>To compare theoretical strengths and limitations of common immortal time adjustment methods, propose a new approach using multiple imputation (MI), and provide practical guidance for using MI in precision medicine evaluations centered on a real-world case study.</p><p><strong>Study setting and design: </strong>Methods comparison, guidance, and real-world case study based on previous literature. We compared landmark analysis, time-distribution matching, time-dependent analysis, and our proposed MI application. Guidance for MI spanned (1) selecting the imputation method; (2) specifying and applying the imputation model; and (3) conducting comparative analysis and pooling estimates. Our case study used a matched cohort design to evaluate overall survival benefits of whole-genome and transcriptome analysis, a precision medicine technology, compared to usual care for advanced cancers, and applied both time-distribution matching and MI. Bootstrap simulation characterized imputation sensitivity to varying data missingness and sample sizes.</p><p><strong>Data sources and analytic sample: </strong>Case study used population-based administrative data and single-arm precision medicine program data from British Columbia, Canada for the study period 2012 to 2015.</p><p><strong>Principal findings: </strong>While each method described can reduce immortal time bias, MI offers theoretical advantages. Compared to alternative approaches, MI minimizes information loss and better characterizes statistical uncertainty about the true length of the immortal time period, avoiding false precision. Additionally, MI explicitly considers the impacts of patient characteristics on immortal time distributions, with inclusion criteria and follow-up period definitions that do not inadvertently risk biasing evaluations. In the real-world case study, survival analysis results did not substantively differ across MI and time distribution matching, but standard errors based on MI were higher for all point estimates. Mean imputed immortal time was stable across simulations.</p><p><strong>Conclusions: </strong>Precision medicine evaluations must employ immortal time adjustment methods for unbiased, decision-grade real-world evidence generation. MI is a promising solution to the challenge of immortal time bias.</p>","PeriodicalId":55065,"journal":{"name":"Health Services Research","volume":" ","pages":""},"PeriodicalIF":3.1000,"publicationDate":"2024-09-03","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Addressing immortal time bias in precision medicine: Practical guidance and methods development.\",\"authors\":\"Deirdre Weymann, Emanuel Krebs, Dean A Regier\",\"doi\":\"10.1111/1475-6773.14376\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><strong>Objective: </strong>To compare theoretical strengths and limitations of common immortal time adjustment methods, propose a new approach using multiple imputation (MI), and provide practical guidance for using MI in precision medicine evaluations centered on a real-world case study.</p><p><strong>Study setting and design: </strong>Methods comparison, guidance, and real-world case study based on previous literature. We compared landmark analysis, time-distribution matching, time-dependent analysis, and our proposed MI application. Guidance for MI spanned (1) selecting the imputation method; (2) specifying and applying the imputation model; and (3) conducting comparative analysis and pooling estimates. Our case study used a matched cohort design to evaluate overall survival benefits of whole-genome and transcriptome analysis, a precision medicine technology, compared to usual care for advanced cancers, and applied both time-distribution matching and MI. Bootstrap simulation characterized imputation sensitivity to varying data missingness and sample sizes.</p><p><strong>Data sources and analytic sample: </strong>Case study used population-based administrative data and single-arm precision medicine program data from British Columbia, Canada for the study period 2012 to 2015.</p><p><strong>Principal findings: </strong>While each method described can reduce immortal time bias, MI offers theoretical advantages. Compared to alternative approaches, MI minimizes information loss and better characterizes statistical uncertainty about the true length of the immortal time period, avoiding false precision. Additionally, MI explicitly considers the impacts of patient characteristics on immortal time distributions, with inclusion criteria and follow-up period definitions that do not inadvertently risk biasing evaluations. 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引用次数: 0
摘要
目的:比较常见不朽时间调整方法的理论优势和局限性,提出一种使用多重归因(MI)的新方法,并以真实世界案例研究为中心,为在精准医学评估中使用MI提供实用指导:研究设置和设计:方法比较、指导和基于以往文献的真实世界案例研究。我们比较了地标分析、时间分布匹配、时间依赖分析和我们提出的 MI 应用。MI指南包括:(1)选择估算方法;(2)指定并应用估算模型;以及(3)进行比较分析和汇总估计值。我们的案例研究采用匹配队列设计来评估全基因组和转录组分析(一种精准医疗技术)与晚期癌症常规治疗相比所带来的总生存益处,并同时应用了时间分布匹配和MI。数据来源和分析样本:案例研究使用了加拿大不列颠哥伦比亚省 2012 年至 2015 年期间基于人口的行政数据和单臂精准医疗计划数据:虽然所述的每种方法都能减少不朽时间偏差,但多元智能具有理论上的优势。与其他方法相比,MI 最大限度地减少了信息损失,更好地描述了不朽时间真实长度的统计不确定性,避免了错误的精确性。此外,MI 明确考虑了患者特征对不朽时间分布的影响,纳入标准和随访期定义不会无意中造成评估偏差的风险。在真实世界的案例研究中,MI 和时间分布匹配的生存分析结果没有实质性差异,但基于 MI 的标准误差对所有点估计值都较高。在不同的模拟中,平均估算的不朽时间是稳定的:结论:精准医疗评估必须采用不朽时间调整方法,以生成无偏见、决策级的真实世界证据。MI是解决不朽时间偏差挑战的一个很有前景的方案。
Addressing immortal time bias in precision medicine: Practical guidance and methods development.
Objective: To compare theoretical strengths and limitations of common immortal time adjustment methods, propose a new approach using multiple imputation (MI), and provide practical guidance for using MI in precision medicine evaluations centered on a real-world case study.
Study setting and design: Methods comparison, guidance, and real-world case study based on previous literature. We compared landmark analysis, time-distribution matching, time-dependent analysis, and our proposed MI application. Guidance for MI spanned (1) selecting the imputation method; (2) specifying and applying the imputation model; and (3) conducting comparative analysis and pooling estimates. Our case study used a matched cohort design to evaluate overall survival benefits of whole-genome and transcriptome analysis, a precision medicine technology, compared to usual care for advanced cancers, and applied both time-distribution matching and MI. Bootstrap simulation characterized imputation sensitivity to varying data missingness and sample sizes.
Data sources and analytic sample: Case study used population-based administrative data and single-arm precision medicine program data from British Columbia, Canada for the study period 2012 to 2015.
Principal findings: While each method described can reduce immortal time bias, MI offers theoretical advantages. Compared to alternative approaches, MI minimizes information loss and better characterizes statistical uncertainty about the true length of the immortal time period, avoiding false precision. Additionally, MI explicitly considers the impacts of patient characteristics on immortal time distributions, with inclusion criteria and follow-up period definitions that do not inadvertently risk biasing evaluations. In the real-world case study, survival analysis results did not substantively differ across MI and time distribution matching, but standard errors based on MI were higher for all point estimates. Mean imputed immortal time was stable across simulations.
Conclusions: Precision medicine evaluations must employ immortal time adjustment methods for unbiased, decision-grade real-world evidence generation. MI is a promising solution to the challenge of immortal time bias.
期刊介绍:
Health Services Research (HSR) is a peer-reviewed scholarly journal that provides researchers and public and private policymakers with the latest research findings, methods, and concepts related to the financing, organization, delivery, evaluation, and outcomes of health services. Rated as one of the top journals in the fields of health policy and services and health care administration, HSR publishes outstanding articles reporting the findings of original investigations that expand knowledge and understanding of the wide-ranging field of health care and that will help to improve the health of individuals and communities.