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A Bayesian joint longitudinal-survival model with a latent stochastic process for intensive longitudinal data (2405.00179v1)

Published 30 Apr 2024 in stat.ME

Abstract: The availability of mobile health (mHealth) technology has enabled increased collection of intensive longitudinal data (ILD). ILD have potential to capture rapid fluctuations in outcomes that may be associated with changes in the risk of an event. However, existing methods for jointly modeling longitudinal and event-time outcomes are not well-equipped to handle ILD due to the high computational cost. We propose a joint longitudinal and time-to-event model suitable for analyzing ILD. In this model, we summarize a multivariate longitudinal outcome as a smaller number of time-varying latent factors. These latent factors, which are modeled using an Ornstein-Uhlenbeck stochastic process, capture the risk of a time-to-event outcome in a parametric hazard model. We take a Bayesian approach to fit our joint model and conduct simulations to assess its performance. We use it to analyze data from an mHealth study of smoking cessation. We summarize the longitudinal self-reported intensity of nine emotions as the psychological states of positive and negative affect. These time-varying latent states capture the risk of the first smoking lapse after attempted quit. Understanding factors associated with smoking lapse is of keen interest to smoking cessation researchers.

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References (33)
  1. A continuous-time dynamic factor model for intensive longitudinal data arising from mobile health studies. arXiv preprint arXiv:2307.15681 .
  2. An approach for jointly modeling multivariate longitudinal measurements and discrete time-to-event data. The Annals of Applied Statistics 4, 1517–1532.
  3. Perceived partner responsiveness predicts smoking cessation in single-smoker couples. Addictive Behaviors 88, 122–128.
  4. Transitions between cigarette, ends and dual use in adults in the PATH study (waves 1–4): multistate transition modelling accounting for complex survey design. Tobacco Control 31, 424–431.
  5. A flexible b-spline model for multiple longitudinal biomarkers and survival. Biometrics 61, 64–73.
  6. Mechanisms linking socioeconomic status to smoking cessation: a structural equation modeling approach. Health Psychology 29, 262–273.
  7. Stan: A probabilistic programming language. Journal of Statistical Software 76, 1–32.
  8. An approximate joint model for multiple paired longitudinal outcomes and time-to-event data. Biometrics 74, 1112–1119.
  9. Gaussian processes for survival analysis. arXiv preprint arXiv:1611.00817 .
  10. Joint modeling of multivariate longitudinal measurements and survival data with applications to Parkinson’s disease. Statistical Methods in Medical Research 25, 1346–1358.
  11. joinerml: a joint model and software package for time-to-event and multivariate longitudinal outcomes. BMC Medical Research Methodology 18,.
  12. Jackson, C. (2016). flexsurv: A platform for parametric survival modeling in R. Journal of Statistical Software 70, 1–33.
  13. A joint model for multivariate longitudinal and survival data to discover the conversion to alzheimer’s disease. Statistics in Medicine 41, 356–373.
  14. Consistent estimation of a joint model for multivariate longitudinal and survival data with latent variables. Journal of Multivariate Analysis 187, 104827.
  15. Dynamic prediction of alzheimer’s disease progression using features of multiple longitudinal outcomes and time-to-event data. Statistics in Medicine 38, 4804––4818.
  16. A flexible joint model for multiple longitudinal biomarkers and a time-to-event outcome: With applications to dynamic prediction using highly correlated biomarkers. Biometrical Journal page 10.1002/bimj.202000085.
  17. Joint models for time-to-event data and longitudinal biomarkers of high dimension. Statistics in Biosciences 11, 614–629.
  18. Joint models with multiple longitudinal outcomes and a time-to-event outcome: A corrected two-stage approach. Statistics and Computing 30, 999–1014.
  19. A fast approximate EM algorithm for joint models of survival and multivariate longitudinal data. Computational Statistics & Data Analysis 170,.
  20. A joint model for repeated events of different types and multiple longitudinal outcomes with application to a follow-up study of patients after kidney transplant. Biometrical Journal 57, 185–200.
  21. Socio-economic status moderates within-person associations of risk factors and smoking lapse in daily life. Addiction 118, 925–934.
  22. Joint modeling of repeated multivariate cognitive measures and competing risks of dementia and death: a latent process and latent class approach. Statistics in Medicine 35, 382–398.
  23. Survival analysis with time-varying covariates measured at random times by design. Journal of the Royal Statistical Society. Series C, Applied Statistics 62, 419–434.
  24. A Bayesian semiparametric multivariate joint model for multiple longitudinal outcomes and a time-to-event. Statistics in Medicine 30, 1366–1380.
  25. Fully exponential Laplace approximations for the joint modelling of survival and longitudinal data. Journal of the Royal Statistical Society. Series B, Statistical Methodology 71, 637–654.
  26. Fast and flexible inference for joint models of multivariate longitudinal and survival data using integrated nested Laplace approximations. Biostatistics .
  27. Penalized regression calibration: A method for the prediction of survival outcomes using complex longitudinal and high-dimensional data. Statistics in Medicine 40, 6178–6196.
  28. An estimator for the proportional hazards model with multiple longitudinal covariates measured with error. Biostatistics 3, 511–528.
  29. Bayesian semiparametric joint model of multivariate longitudinal and survival data with dependent censoring. Lifetime Data Analysis 29, 888–918.
  30. Latent Ornstein-Uhlenbeck models for Bayesian analysis of multivariate longitudinal categorical responses. Biometrics 77, 689–701.
  31. Joint modeling of longitudinal and time-to-event data: an overview. Statistica Sinica 14, 809–834.
  32. The assocation of positive emotion and first smoking lapse: an ecological momentary assessment study. Health Psychology 36, 1038–1046.
  33. Semiparametric latent-class models for multivariate longitudinal and survival data. The Annals of Statistics 50, 487–510.

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