Adjustment for time-dependent unmeasured confounders in marginal structural Cox models using validation sample data

Abstract

Large databases used in observational studies of drug safety often lack information on important confounders. The resulting unmeasured confounding bias may be avoided by using additional confounder information, frequently available in smaller clinical “validation samples”. Yet, no existing method that uses such validation samples is able to deal with unmeasured time-varying variables acting as both confounders and possible mediators of the treatment effect. We propose and compare alternative methods which control for confounders measured only in a validation sample within marginal structural Cox models. Each method corrects the time-varying inverse probability of treatment weights for all subject-by-time observations using either regression calibration of the propensity score, or multiple imputation of unmeasured confounders. Two proposed methods rely on martingale residuals from a Cox model that includes only confounders fully measured in the large database, to correct inverse probability of treatment weight for imputed values of unmeasured confounders. Simulation demonstrates that martingale residual-based methods systematically reduce confounding bias over naïve methods, with multiple imputation including the martingale residual yielding, on average, the best overall accuracy. We apply martingale residual-based imputation to re-assess the potential risk of drug-induced hypoglycemia in diabetic patients, where an important laboratory test is repeatedly measured only in a small sub-cohort.

Keywords

Unmeasured confounding survival analysis marginal structural models martingale residuals simulations

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References

Choi

Hernán

Seeger

et al.

Methotrexate and mortality in patients with rheumatoid arthritis: a prospective study. Lancet 2002; 359: 1173–1177.

Cole

Hernán

Robins

et al.

Effect of highly active antiretroviral therapy on time to acquired immunodeficiency syndrome or death using marginal structural models. Am J Epidemiol 2003; 158: 687–694.

Roumie

Greevy

Grijalva

et al.

Association between intensification of metformin treatment with insulin vs sulfonylureas and cardiovascular events and all-cause mortality among patients with diabetes. J Am Med Assoc 2014; 311: 2288–2296.

Hernán

Brumback

Robins

. Marginal structural models to estimate the causal effect of zidovudine on the survival of HIV-positive men. Epidemiology 2000; 11: 561–570.

Robins

Hernán

Brumback

. Marginal structural models and causal inference in epidemiology. Epidemiology 2000; 11: 550–560.

Xiao

Abrahamowicz

Moodie

. Accuracy of conventional and marginal structural Cox model estimators: a simulation study. Int J Biostat 2010; 6: 1–28.

Brumback

Hernán

Haneuse

et al.

Sensitivity analyses for unmeasured confounding assuming a marginal structural model for repeated measures. Stat Med 2004; 23: 749–767.

Moodie

Delaney

Lefebvre

et al.

Missing confounding data in marginal structural models: a comparison of inverse probability weighting and multiple imputation. Int J Biostat 2008; 4: 1–23. .

Cole

Hernàn

. Constructing inverse probability weights for marginal structural models. Am J Epidemiol 2008; 168: 656–664.

10.

Avorn

. In defense of pharmacoepidemiology – embracing the yin and yang of drug research. N Engl J Med 2007; 357: 2219.

11.

Walker

. Confounding by indication. Epidemiology 1996; 7: 335–336.

12.

Patorno

Garry

Patrick

et al.

Addressing limitations in observational studies of the association between glucose-lowering medications and all-cause mortality: a review. Drug Saf 2015; 38: 295–310.

13.

Wolfe

Zwillich

. The long-term outcomes of rheumatoid arthritis: a 23-year prospective, longitudinal study of total joint replacement and its predictors in 1,600 patients with rheumatoid arthritis. Arthritis Rheum 1998; 41: 1072–1082.

14.

Franklin

Eddings

Schneeweiss

et al.

Incorporating linked healthcare claims to improve confounding control in a study of in-hospital medication use. Drug Saf 2015; 38: 589–600.

15.

Wood

Frazier

Nordeng

et al.

Prenatal triptan exposure and parentreported early childhood neurodevelopmental outcomes: an application of propensity score calibration to adjust for unmeasured confounding by migraine severity. Pharmacoepidemiol Drug Saf 2016; 25: 493–502. .

16.

Stürmer

Schneeweiss

Avorn

et al.

Adjusting effect estimates for unmeasured confounding with validation data using propensity score calibration. Am J Epidemiol 2005; 162: 279–289.

17.

Stürmer

Schneeweiss

Rothman

et al.

Performance of propensity score calibration – a simulation study. Am J Epidemiol 2007; 165: 1110–1118.

18.

McCandless

Richardson

Best

. Adjustment for missing confounders using external validation data and propensity scores. J Am Stat Assoc 2012; 107: 40–51.

19.

Lin

Chen

. Adjustment for missing confounders in studies based on observational databases: 2-stage calibration combining propensity scores from primary and validation data. Am J Epidemiol 2014; 180(3): 308–317.

20.

Burne

Abrahamowicz

. Martingale residual-based method to control for confounders measured only in a validation sample in time-to-event analysis. Stat Med 2016; 35: 4588–4606. .

21.

Xiao

Moodie

Abrahamowicz

. Comparison of approaches to weight truncation for marginal structural Cox models. Epidemiol Methods 2013; 2: 1–20.

22.

Xiao

Abrahamowicz

Moodie

et al.

Flexible marginal structural models for estimating the cumulative effect of a time-dependent treatment on the hazard: Reassessing the cardiovascular risks of didanosine treatment in the Swiss HIV cohort study. J Am Stat Assoc 2014; 109: 455–464.

23.

Rosner

Willett

Spiegelman

. Correction of logistic regression relative risk estimates and confidence intervals for systematic within-person measurement error. Stat Med 1989; 8: 1051–1069.

24.

Moons

Donders

Stijnen

et al.

Using the outcome for imputation of missing predictor values was preferred. J Clin Epidemiol 2006; 59: 1092–1101.

25.

White

Royston

. Imputing missing covariate values for the Cox model. Stat Med 2009; 28: 1982–1998.

26.

Therneau

Grambsch

Fleming

. Martingale-based residuals for survival models. Biometrika 1990; 77: 147–160.

27.

Breslow

. Covariance analysis of censored survival data. Biometrics 1974; 30: 89–99.

28.

Rubin

. Multiple imputation for nonresponse in surveys, New York: Wiley & Sons, 1987.

29.

R Core Team. R: a language environment for statistical computing, Vienna, Austria: R Foundation for Statistical Computing, 2014.

30.

Young

Hernän

Picciotto

et al.

Relation between three classes of structural models for the effect of a time-varying exposure on survival. Lifetime Data Anal 2010; 16: 71–84.

31.

Canadian Diabetes Association Clinical Practice Guidelines Expert Committee. Pharmacologic management of type 2 diabetes. Can J Diabetes 2013; 37: S61–S68.

32.

Nathan

Buse

Davidson

et al.

Medical management of hyperglycemia in type 2 diabetes: a consensus algorithm for the initiation and adjustment of therapy a consensus statement of the American Diabetes Association and the European Association for the study of diabetes. Diabetes Care 2009; 32: 193–203.

33.

Tricco

Antony

Khan

et al.

Safety and effectiveness of dipeptidyl peptidase-4 inhibitors versus intermediate-acting insulin or placebo for patients with type 2 diabetes failing two oral antihyperglycaemic agents: a systematic review and network meta-analysis. BMJ Open 2014; 4: e005752.

34.

Lipska

Warton

Huang

et al.

Hba1c and risk of severe hypoglycemia in type 2 diabetes the diabetes and aging study. Diabetes Care 2013; 36: 3535–3542.

35.

McCoy

Van Houten

Ziegenfuss

et al.

Increased mortality of patients with diabetes reporting severe hypoglycemia. Diabetes Care 2012; 35: 1897–1901.

36.

Miller

Phillips

Ziemer

et al.

Hypoglycemia in patients with type 2 diabetes mellitus. Arch Internal Med 2001; 161(13): 1653–1659.

37.

Dicker

. Dpp-4 inhibitors impact on glycemic control and cardiovascular risk factors. Diabetes Care 2011; 34(Suppl 2): S276–S278.

38.

Lozano-Ortega

Goring

Bennett

et al.

Network meta-analysis of treatments for type 2 diabetes mellitus following failure with metformin plus sulfonylurea. Curr Med Res Opin 2016; 32: 807–816.

39.

Charlson

Szatrowski

Peterson

et al.

Validation of a combined comorbidity index. J Clin Epidemiol 1994; 47: 1245–1251.

40.

Brookhart

Wang

Solomon

et al.

Evaluating short-term drug effects using a physician-specific prescribing preference as an instrumental variable. Epidemiology 2006; 17: 268–275.

41.

Schneeweiss

Rassen

Glynn

et al.

High-dimensional propensity score adjustment in studies of treatment effects using health care claims data. Epidemiology 2009; 20: 512.

42.

Abrahamowicz

Bjerre

Beauchamp

et al.

The missing cause approach to unmeasured confounding in pharmacoepidemiology. Stati Med 2016; 35: 1001–1016.

43.

Groenwold

RHH

Nelson

Nichol

et al.

Sensitivity analyses to estimate the potential impact of unmeasured confounding in causal research. Int J Epidemiol 2010; 39: 107–117.

44.

Daniel

Cousens

De Stavola

et al.

Methods for dealing with timedependent confounding. Stat Med 2013; 32: 1584–1618.

45.

Bembom

van der Laan

Haight

et al.

Leisure-time physical activity and all-cause mortality in an elderly cohort. Epidemiology 2009; 20: 424–430.

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