Chiara Moccia, Giovenale Moirano, Maja Popovic, Costanza Pizzi, Piero Fariselli, Lorenzo Richiardi, Claus Thorn Ekstrøm, Milena Maule
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引用次数: 0
摘要
在因果推断中,通常采用参数模型来解决因果问题,估计相关效应。然而,参数模型依赖于正确的模型规范假设,如果不满足这一假设,就会导致有偏差的效应估计。正确的模型规范具有挑战性,尤其是在高维环境中。将机器学习(ML)纳入因果分析可能会减少因模型规范错误而产生的偏差,因为 ML 方法不需要规范变量之间关系的函数形式。但是,如果将 ML 预测直接插入相关效应的预定义公式中,就有可能在效应测量中引入 "插入偏差"。为了克服这一问题并获得有用的渐近特性,有人提出了结合 ML 预测潜力和传统统计方法推断人群参数能力的新估计器。对于有兴趣利用 ML 进行因果推断研究的流行病学家来说,我们将概述代表当前最新技术水平的三种估计器,即目标最大似然估计(TMLE)、增强反向概率加权(AIPW)和双重/有偏差机器学习(DML)。
Machine learning in causal inference for epidemiology
In causal inference, parametric models are usually employed to address causal questions estimating the effect of interest. However, parametric models rely on the correct model specification assumption that, if not met, leads to biased effect estimates. Correct model specification is challenging, especially in high-dimensional settings. Incorporating Machine Learning (ML) into causal analyses may reduce the bias arising from model misspecification, since ML methods do not require the specification of a functional form of the relationship between variables. However, when ML predictions are directly plugged in a predefined formula of the effect of interest, there is the risk of introducing a “plug-in bias” in the effect measure. To overcome this problem and to achieve useful asymptotic properties, new estimators that combine the predictive potential of ML and the ability of traditional statistical methods to make inference about population parameters have been proposed. For epidemiologists interested in taking advantage of ML for causal inference investigations, we provide an overview of three estimators that represent the current state-of-art, namely Targeted Maximum Likelihood Estimation (TMLE), Augmented Inverse Probability Weighting (AIPW) and Double/Debiased Machine Learning (DML).
期刊介绍:
The European Journal of Epidemiology, established in 1985, is a peer-reviewed publication that provides a platform for discussions on epidemiology in its broadest sense. It covers various aspects of epidemiologic research and statistical methods. The journal facilitates communication between researchers, educators, and practitioners in epidemiology, including those in clinical and community medicine. Contributions from diverse fields such as public health, preventive medicine, clinical medicine, health economics, and computational biology and data science, in relation to health and disease, are encouraged. While accepting submissions from all over the world, the journal particularly emphasizes European topics relevant to epidemiology. The published articles consist of empirical research findings, developments in methodology, and opinion pieces.
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