Abstract
Abstract Doubly robust (DR) estimators are an important class of statistics derived from a theory of semiparametric efficiency. They have become a popular tool in causal inference, including applications to dynamic treatment regimes. The doubly robust estimators for the mean response to a dynamic treatment regime may be conceived through the augmented inverse probability weighted (AIPW) estimating function, defined as the sum of the inverse probability weighted (IPW) estimating function and an augmentation term. The IPW estimating function of the causal estimand via marginal structural model is defined as the complete-case score function for those subjects whose treatment sequence is consistent with the dynamic regime in question divided by the probability of observing the treatment sequence given the subject's treatment and covariate histories. The augmentation term is derived by projecting the IPW estimating function onto the nuisance tangent space and has mean-zero under the truth. The IPW estimator of the causal estimand is consistent if (i) the treatment assignment mechanism is correctly modeled and the AIPW estimator is consistent if either (i) is true or (ii) nested functions of intermediate and final outcomes are correctly modeled. Hence, the AIPW estimator is doubly robust and, moreover, the AIPW is semiparametric efficient if both (i) and (ii) are true simultaneously. Unfortunately, DR estimators can be inferior when either (i) or (ii) is true and the other false. In this case, the misspecified parts of the model can have a detrimental effect on the variance of the DR estimator. We propose an improved DR estimator of causal estimand in dynamic treatment regimes through a technique originally developed by [4] which aims to mitigate the ill-effects of model misspecification through a constrained optimization. In addition to solving a doubly robust system of equations, the improved DR estimator simultaneously minimizes the asymptotic variance of the estimator under a correctly specified treatment assignment mechanism but misspecification of intermediate and final outcome models. We illustrate the desirable operating characteristics of the estimator through Monte Carlo studies and apply the methods to data from a randomized study of integrilin therapy for patients undergoing coronary stent implantation. The methods proposed here are new and may be used to further improve personalized medicine, in general.
Highlights
Estimating population parameters in the presence of missing data is a common but challenging problem when one desires robust precise estimates under a missing at random assumption [e.g. 22]
When the propensity score (PS) model is correctly specified and (12) is evaluated with {πj0}, we show that (12) has mean zero at α = αopt, and the constrained augmentation improved doubly robust (IDR) estimatorβ︀IDR has the smallest asymptotic variance among the class of augmented inverse probability weighted (AIPW) estimators with correctly specified {πj}, whereβ︀IDR is the solution to the AIPW estimating equations withα︀ solving (12)
All estimators of causal estimands adjust for potential confounders including angina and weight at baseline as well as time-dependent enzyme level measured during post-surgery observation
Summary
Estimating population parameters in the presence of missing data is a common but challenging problem when one desires robust precise estimates under a missing at random assumption [e.g. 22]. Augmented inverse probability weighted (AIPW) estimating functions [16] are constructed as the sum of the IPW estimating function and a mean-zero augmentation term. The AIPW estimators are doubly robust (DR) which implies they are consistent whether the missingness probability is modeled correctly or the OR models in the augmentation term are modeled correctly. If both models are correctly specified, the AIPW is semiparametric efficient [2, 16, 22]. This adaptive estimator is not optimal when only some models are correctly specified [e.g. 9, 19, 27]
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