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Stabilized direct learning for efficient estimation of individualized treatment rules

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  • Kushal S. Shah
  • Haoda Fu
  • Michael R. Kosorok

Abstract

In recent years, the field of precision medicine has seen many advancements. Significant focus has been placed on creating algorithms to estimate individualized treatment rules (ITRs), which map from patient covariates to the space of available treatments with the goal of maximizing patient outcome. Direct learning (D‐Learning) is a recent one‐step method which estimates the ITR by directly modeling the treatment–covariate interaction. However, when the variance of the outcome is heterogeneous with respect to treatment and covariates, D‐Learning does not leverage this structure. Stabilized direct learning (SD‐Learning), proposed in this paper, utilizes potential heteroscedasticity in the error term through a residual reweighting which models the residual variance via flexible machine learning algorithms such as XGBoost and random forests. We also develop an internal cross‐validation scheme which determines the best residual model among competing models. SD‐Learning improves the efficiency of D‐Learning estimates in binary and multi‐arm treatment scenarios. The method is simple to implement and an easy way to improve existing algorithms within the D‐Learning family, including original D‐Learning, Angle‐based D‐Learning (AD‐Learning), and Robust D‐learning (RD‐Learning). We provide theoretical properties and justification of the optimality of SD‐Learning. Head‐to‐head performance comparisons with D‐Learning methods are provided through simulations, which demonstrate improvement in terms of average prediction error (APE), misclassification rate, and empirical value, along with a data analysis of an acquired immunodeficiency syndrome (AIDS) randomized clinical trial.

Suggested Citation

  • Kushal S. Shah & Haoda Fu & Michael R. Kosorok, 2023. "Stabilized direct learning for efficient estimation of individualized treatment rules," Biometrics, The International Biometric Society, vol. 79(4), pages 2843-2856, December.
    • Handle: RePEc:bla:biomet:v:79:y:2023:i:4:p:2843-2856
    DOI: 10.1111/biom.13818
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    References listed on IDEAS

    as
    1. Daniel Jacob, 2021. "CATE meets ML -- The Conditional Average Treatment Effect and Machine Learning," Papers 2104.09935, arXiv.org, revised Apr 2021.
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    4. Jacob, Daniel, 2021. "CATE meets ML: Conditional average treatment effect and machine learning," IRTG 1792 Discussion Papers 2021-005, Humboldt University of Berlin, International Research Training Group 1792 "High Dimensional Nonstationary Time Series".
    5. Caiyun Fan & Wenbin Lu & Rui Song & Yong Zhou, 2017. "Concordance-assisted learning for estimating optimal individualized treatment regimes," Journal of the Royal Statistical Society Series B, Royal Statistical Society, vol. 79(5), pages 1565-1582, November.
    6. Xin Zhou & Nicole Mayer-Hamblett & Umer Khan & Michael R. Kosorok, 2017. "Residual Weighted Learning for Estimating Individualized Treatment Rules," Journal of the American Statistical Association, Taylor & Francis Journals, vol. 112(517), pages 169-187, January.
    7. Lu Tian & Ash A. Alizadeh & Andrew J. Gentles & Robert Tibshirani, 2014. "A Simple Method for Estimating Interactions Between a Treatment and a Large Number of Covariates," Journal of the American Statistical Association, Taylor & Francis Journals, vol. 109(508), pages 1517-1532, December.
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