Your search keyword '"survival tree"' showing total 2 results

1. DYNAMIC RISK PREDICTION TRIGGERED BY INTERMEDIATE EVENTS USING SURVIVAL TREE ENSEMBLES.

Author

Sun, Yifei, Chiou, Sy Han, Wu, Colin O, McGarry, Meghan, and Huang, Chiung-Yu

Subjects

Mathematical Sciences, Statistics, Rare Diseases, Cystic Fibrosis, Lung, Patient Safety, Dynamic prediction, landmark analysis, multi-state model, survival tree, time-dependent predictors, Econometrics, Statistics & Probability

Abstract

With the availability of massive amounts of data from electronic health records and registry databases, incorporating time-varying patient information to improve risk prediction has attracted great attention. To exploit the growing amount of predictor information over time, we develop a unified framework for landmark prediction using survival tree ensembles, where an updated prediction can be performed when new information becomes available. Compared to conventional landmark prediction with fixed landmark times, our methods allow the landmark times to be subject-specific and triggered by an intermediate clinical event. Moreover, the nonparametric approach circumvents the thorny issue of model incompatibility at different landmark times. In our framework, both the longitudinal predictors and the event time outcome are subject to right censoring, and thus existing tree-based approaches cannot be directly applied. To tackle the analytical challenges, we propose a risk-set-based ensemble procedure by averaging martingale estimating equations from individual trees. Extensive simulation studies are conducted to evaluate the performance of our methods. The methods are applied to the Cystic Fibrosis Foundation Patient Registry (CFFPR) data to perform dynamic prediction of lung disease in cystic fibrosis patients and to identify important prognosis factors.

Published

2023

2. Which Sleep Health Characteristics Predict All-Cause Mortality in Older Men? An Application of Flexible Multivariable Approaches

Author

Wallace, Meredith L, Stone, Katie, Smagula, Stephen F, Hall, Martica H, Simsek, Burcin, Kado, Deborah M, Redline, Susan, Vo, Tien N, and Buysse, Daniel J

Subjects

Biomedical and Clinical Sciences, Behavioral and Social Science, Aging, Sleep Research, Neurosciences, Good Health and Well Being, Actigraphy, Aged, Cardiovascular Diseases, Cognition, Health Status, Humans, Male, Mortality, Osteoporotic Fractures, Polysomnography, Proportional Hazards Models, Sleep, Sleep Wake Disorders, sleep health, circadian rhythm, multivariable analyses, mortality, men, late-life, survival tree, random survival forest, Osteoporotic Fractures in Men (MrOS) Study Research Group, Biological Sciences, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery, Biological sciences, Biomedical and clinical sciences, Psychology

Abstract

Sleep is multidimensional, with domains including duration, timing, continuity, regularity, rhythmicity, quality, and sleepiness/alertness. Individual sleep characteristics representing these domains are known to predict health outcomes. However, most studies consider sleep characteristics in isolation, resulting in an incomplete understanding of which sleep characteristics are the strongest predictors of health outcomes. We applied three multivariable approaches to robustly determine which sleep characteristics increase mortality risk in the osteoporotic fractures in men sleep study. In total, 2,887 men (mean 76.3 years) completed relevant assessments and were followed for up to 11 years. One actigraphy or self-reported sleep characteristic was selected to represent each of seven sleep domains. Multivariable Cox models, survival trees, and random survival forests were applied to determine which sleep characteristics increase mortality risk. Rhythmicity (actigraphy pseudo-F statistic) and continuity (actigraphy minutes awake after sleep onset) were the most robust sleep predictors across models. In a multivariable Cox model, lower rhythmicity (hazard ratio, HR [95%CI] =1.12 [1.04, 1.22]) and lower continuity (1.16 [1.08, 1.24]) were the strongest sleep predictors. In the random survival forest, rhythmicity and continuity were the most important individual sleep characteristics (ranked as the sixth and eighth most important among 43 possible sleep and non-sleep predictors); moreover, the predictive importance of all sleep information considered simultaneously followed only age, cognition, and cardiovascular disease. Research within a multidimensional sleep health framework can jumpstart future research on causal pathways linking sleep and health, new interventions that target specific sleep health profiles, and improved sleep screening for adverse health outcomes.

Published

2018