结合随机和非随机数据,预测竞争疗法的异质性效果。

IF 5 2区 生物学 Q1 MATHEMATICAL & COMPUTATIONAL BIOLOGY Research Synthesis Methods Pub Date : 2024-03-19 DOI:10.1002/jrsm.1717
Konstantina Chalkou, Tasnim Hamza, Pascal Benkert, Jens Kuhle, Chiara Zecca, Gabrielle Simoneau, Fabio Pellegrini, Andrea Manca, Matthias Egger, Georgia Salanti
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引用次数: 0

摘要

一些患者能从治疗中获益,而另一些患者可能获益较少或根本无法获益。我们之前开发了一个两阶段网络元回归预测模型,该模型综合了随机试验并评估了不同患者特征下的治疗效果差异。在本文中,我们对该模型进行了扩展,以结合不同格式的不同类型来源:来自随机和非随机证据的总体数据(AD)和个体参与者数据(IPD)。在第一阶段,我们开发了一个预后模型,利用大型队列研究预测结果的基线风险。在第二阶段,我们对这一预后模型进行了重新校准,以改进我们对随机试验入组患者的预测。在第三阶段,我们在结合 AD、IPD 随机临床试验的网络元回归模型中使用基线风险作为效应修饰符,以估计异质性治疗效果。我们在重新分析比较三种治疗复发缓解型多发性硬化症药物的网络研究中说明了这种方法。患者的一些特征会影响复发的基线风险,进而改变药物的效果。所提出的模型对几种治疗方案下的健康结果进行了个性化预测,并涵盖了所有相关的随机和非随机证据。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Combining randomized and non-randomized data to predict heterogeneous effects of competing treatments

Some patients benefit from a treatment while others may do so less or do not benefit at all. We have previously developed a two-stage network meta-regression prediction model that synthesized randomized trials and evaluates how treatment effects vary across patient characteristics. In this article, we extended this model to combine different sources of types in different formats: aggregate data (AD) and individual participant data (IPD) from randomized and non-randomized evidence. In the first stage, a prognostic model is developed to predict the baseline risk of the outcome using a large cohort study. In the second stage, we recalibrated this prognostic model to improve our predictions for patients enrolled in randomized trials. In the third stage, we used the baseline risk as effect modifier in a network meta-regression model combining AD, IPD randomized clinical trial to estimate heterogeneous treatment effects. We illustrated the approach in the re-analysis of a network of studies comparing three drugs for relapsing–remitting multiple sclerosis. Several patient characteristics influence the baseline risk of relapse, which in turn modifies the effect of the drugs. The proposed model makes personalized predictions for health outcomes under several treatment options and encompasses all relevant randomized and non-randomized evidence.

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来源期刊
Research Synthesis Methods
Research Synthesis Methods MATHEMATICAL & COMPUTATIONAL BIOLOGYMULTID-MULTIDISCIPLINARY SCIENCES
CiteScore
16.90
自引率
3.10%
发文量
75
期刊介绍: Research Synthesis Methods is a reputable, peer-reviewed journal that focuses on the development and dissemination of methods for conducting systematic research synthesis. Our aim is to advance the knowledge and application of research synthesis methods across various disciplines. Our journal provides a platform for the exchange of ideas and knowledge related to designing, conducting, analyzing, interpreting, reporting, and applying research synthesis. While research synthesis is commonly practiced in the health and social sciences, our journal also welcomes contributions from other fields to enrich the methodologies employed in research synthesis across scientific disciplines. By bridging different disciplines, we aim to foster collaboration and cross-fertilization of ideas, ultimately enhancing the quality and effectiveness of research synthesis methods. Whether you are a researcher, practitioner, or stakeholder involved in research synthesis, our journal strives to offer valuable insights and practical guidance for your work.
期刊最新文献
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