PURPOSE: Propensity scores (PSs), a powerful bias-reduction tool, can balance treatment groups on measured covariates in nonexperimental studies. We demonstrate the use of multiple PS estimation methods to optimize covariate balance. METHODS: We used secondary data from 1292 adults with nonpsychotic major depressive disorder in the Sequenced Treatment Alternatives to Relieve Depression trial (2001-2004). After initial citalopram treatment failed, patient preference influenced assignment to medication augmentation (n = 565) or switch (n = 727). To reduce selection bias, we used boosted classification and regression trees (BCART) and logistic regression iteratively to identify two potentially optimal PSs. We assessed and compared covariate balance. RESULTS: After iterative selection of interaction terms to minimize imbalance, logistic regression yielded better balance than BCART (average standardized absolute mean difference across 47 covariates: 0.03 vs. 0.08, matching; 0.02 vs. 0.05, weighting). CONCLUSIONS: Comparing multiple PS estimates is a pragmatic way to optimize balance. Logistic regression remains valuable for this purpose. Simulation studies are needed to compare PS models under varying conditions. Such studies should consider more flexible estimation methods, such as logistic models with automated selection of interactions or hybrid models using main effects logistic regression instead of a constant log-odds as the initial model for BCART.
PURPOSE: Propensity scores (PSs), a powerful bias-reduction tool, can balance treatment groups on measured covariates in nonexperimental studies. We demonstrate the use of multiple PS estimation methods to optimize covariate balance. METHODS: We used secondary data from 1292 adults with nonpsychotic major depressive disorder in the Sequenced Treatment Alternatives to Relieve Depression trial (2001-2004). After initial citalopram treatment failed, patient preference influenced assignment to medication augmentation (n = 565) or switch (n = 727). To reduce selection bias, we used boosted classification and regression trees (BCART) and logistic regression iteratively to identify two potentially optimal PSs. We assessed and compared covariate balance. RESULTS: After iterative selection of interaction terms to minimize imbalance, logistic regression yielded better balance than BCART (average standardized absolute mean difference across 47 covariates: 0.03 vs. 0.08, matching; 0.02 vs. 0.05, weighting). CONCLUSIONS: Comparing multiple PS estimates is a pragmatic way to optimize balance. Logistic regression remains valuable for this purpose. Simulation studies are needed to compare PS models under varying conditions. Such studies should consider more flexible estimation methods, such as logistic models with automated selection of interactions or hybrid models using main effects logistic regression instead of a constant log-odds as the initial model for BCART.
Authors: Sherry Weitzen; Kate L Lapane; Alicia Y Toledano; Anne L Hume; Vincent Mor Journal: Pharmacoepidemiol Drug Saf Date: 2004-12 Impact factor: 2.890
Authors: Soko Setoguchi; Sebastian Schneeweiss; M Alan Brookhart; Robert J Glynn; E Francis Cook Journal: Pharmacoepidemiol Drug Saf Date: 2008-06 Impact factor: 2.890
Authors: Daniel Westreich; Stephen R Cole; Michele Jonsson Funk; M Alan Brookhart; Til Stürmer Journal: Pharmacoepidemiol Drug Saf Date: 2010-12-09 Impact factor: 2.890
Authors: A John Rush; Maurizio Fava; Stephen R Wisniewski; Philip W Lavori; Madhukar H Trivedi; Harold A Sackeim; Michael E Thase; Andrew A Nierenberg; Frederic M Quitkin; T Michael Kashner; David J Kupfer; Jerrold F Rosenbaum; Jonathan Alpert; Jonathan W Stewart; Patrick J McGrath; Melanie M Biggs; Kathy Shores-Wilson; Barry D Lebowitz; Louise Ritz; George Niederehe Journal: Control Clin Trials Date: 2004-02