Semiparametric Joint Model for Longitudinal and Survival Data with Application to Hemodialysis Study

• Published in: Biometrics Vol. 65; no. 3; pp. 737 - 745
• Main Authors: Li, Liang, Hu, Bo, Greene, Tom
• Format: Journal Article
• Language: English
• Published: Malden, USA Blackwell Publishing Inc 01.09.2009; Wiley-Blackwell; Blackwell Publishing Ltd
• Subjects: Albumins; Biomarkers; Biometric Methodology; Biometrics; Biometry - methods; Biostatistics; Computer Simulation; Consistent estimators; Corrected score; Cox model; Data Interpretation, Statistical; Dialysis; Estimation methods; Estimators; Female; Humans; Induced substructures; Joint modeling; Kidney Failure, Chronic - mortality; Kidney Failure, Chronic - rehabilitation; Male; Measurement error; Modeling; Models, Statistical; Parametric models; Point estimators; Proportional Hazards Models; Regression analysis; Regression spline; Renal Dialysis - mortality; Risk Assessment - methods; Risk Factors; Shared parameter model; Survival Analysis; Survival Rate
• ISSN: 0006-341X; 1541-0420; 1541-0420
• DOI: 10.1111/j.1541-0420.2008.01168.x

In many longitudinal clinical studies, the level and progression rate of repeatedly measured biomarkers on each subject quantify the severity of the disease and that subject's susceptibility to progression of the disease. It is of scientific and clinical interest to relate such quantities to a later time-to-event clinical endpoint such as patient survival. This is usually done with a shared parameter model. In such models, the longitudinal biomarker data and the survival outcome of each subject are assumed to be conditionally independent given subject-level severity or susceptibility (also called frailty in statistical terms). In this article, we study the case where the conditional distribution of longitudinal data is modeled by a linear mixed-effect model, and the conditional distribution of the survival data is given by a Cox proportional hazard model. We allow unknown regression coefficients and time-dependent covariates in both models. The proposed estimators are maximizers of an exact correction to the joint log likelihood with the frailties eliminated as nuisance parameters, an idea that originated from correction of covariate measurement error in measurement error models. The corrected joint log likelihood is shown to be asymptotically concave and leads to consistent and asymptotically normal estimators. Unlike most published methods for joint modeling, the proposed estimation procedure does not rely on distributional assumptions of the frailties. The proposed method was studied in simulations and applied to a data set from the Hemodialysis Study.