Jacob V Spertus1, Sharon-Lise T Normand2, Robert Wolf1, Matt Cioffi1, Ann Lovett1, Sherri Rose1. 1. From the Department of Health Care Policy, Harvard Medical School, Boston, MA (J.V.S., S.-L.T.N., R.W., M.C., A.L., S.R.); and Department of Biostatistics, Harvard T.H. Chan School of Public Health, Boston, MA (S.-L.T.N.). 2. From the Department of Health Care Policy, Harvard Medical School, Boston, MA (J.V.S., S.-L.T.N., R.W., M.C., A.L., S.R.); and Department of Biostatistics, Harvard T.H. Chan School of Public Health, Boston, MA (S.-L.T.N.). sharon@hcp.med.harvard.edu.
Abstract
BACKGROUND: Although risk adjustment remains a cornerstone for comparing outcomes across hospitals, optimal strategies continue to evolve in the presence of many confounders. We compared conventional regression-based model to approaches particularly suited to leveraging big data. METHODS AND RESULTS: We assessed hospital all-cause 30-day excess mortality risk among 8952 adults undergoing percutaneous coronary intervention between October 1, 2011, and September 30, 2012, in 24 Massachusetts hospitals using clinical registry data linked with billing data. We compared conventional logistic regression models with augmented inverse probability weighted estimators and targeted maximum likelihood estimators to generate more efficient and unbiased estimates of hospital effects. We also compared a clinically informed and a machine-learning approach to confounder selection, using elastic net penalized regression in the latter case. Hospital excess risk estimates range from -1.4% to 2.0% across methods and confounder sets. Some hospitals were consistently classified as low or as high excess mortality outliers; others changed classification depending on the method and confounder set used. Switching from the clinically selected list of 11 confounders to a full set of 225 confounders increased the estimation uncertainty by an average of 62% across methods as measured by confidence interval length. Agreement among methods ranged from fair, with a κ statistic of 0.39 (SE: 0.16), to perfect, with a κ of 1 (SE: 0.0). CONCLUSIONS: Modern causal inference techniques should be more frequently adopted to leverage big data while minimizing bias in hospital performance assessments.
BACKGROUND: Although risk adjustment remains a cornerstone for comparing outcomes across hospitals, optimal strategies continue to evolve in the presence of many confounders. We compared conventional regression-based model to approaches particularly suited to leveraging big data. METHODS AND RESULTS: We assessed hospital all-cause 30-day excess mortality risk among 8952 adults undergoing percutaneous coronary intervention between October 1, 2011, and September 30, 2012, in 24 Massachusetts hospitals using clinical registry data linked with billing data. We compared conventional logistic regression models with augmented inverse probability weighted estimators and targeted maximum likelihood estimators to generate more efficient and unbiased estimates of hospital effects. We also compared a clinically informed and a machine-learning approach to confounder selection, using elastic net penalized regression in the latter case. Hospital excess risk estimates range from -1.4% to 2.0% across methods and confounder sets. Some hospitals were consistently classified as low or as high excess mortality outliers; others changed classification depending on the method and confounder set used. Switching from the clinically selected list of 11 confounders to a full set of 225 confounders increased the estimation uncertainty by an average of 62% across methods as measured by confidence interval length. Agreement among methods ranged from fair, with a κ statistic of 0.39 (SE: 0.16), to perfect, with a κ of 1 (SE: 0.0). CONCLUSIONS: Modern causal inference techniques should be more frequently adopted to leverage big data while minimizing bias in hospital performance assessments.
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