Your search keyword '"Lee, Kyu-Ha"' showing total 5 results

1. Characterizing quantile-varying covariate effects under the accelerated failure time model.

Author

Reeder, Harrison T, Lee, Kyu Ha, and Haneuse, Sebastien

Subjects

*QUANTILE regression, *PROPORTIONAL hazards models, *ALZHEIMER'S disease, *FLEXIBLE structures, *SURVIVAL analysis (Biometry), *TASK analysis

Abstract

An important task in survival analysis is choosing a structure for the relationship between covariates of interest and the time-to-event outcome. For example, the accelerated failure time (AFT) model structures each covariate effect as a constant multiplicative shift in the outcome distribution across all survival quantiles. Though parsimonious, this structure cannot detect or capture effects that differ across quantiles of the distribution, a limitation that is analogous to only permitting proportional hazards in the Cox model. To address this, we propose a general framework for quantile-varying multiplicative effects under the AFT model. Specifically, we embed flexible regression structures within the AFT model and derive a novel formula for interpretable effects on the quantile scale. A regression standardization scheme based on the g-formula is proposed to enable the estimation of both covariate-conditional and marginal effects for an exposure of interest. We implement a user-friendly Bayesian approach for the estimation and quantification of uncertainty while accounting for left truncation and complex censoring. We emphasize the intuitive interpretation of this model through numerical and graphical tools and illustrate its performance through simulation and application to a study of Alzheimer's disease and dementia. [ABSTRACT FROM AUTHOR]

Published

2024

2. Bayesian variable selection for multivariate zero-inflated models: Application to microbiome count data

Author

Lee, Kyu Ha, primary, Coull, Brent A, primary, Moscicki, Anna-Barbara, primary, Paster, Bruce J, primary, and Starr, Jacqueline R, primary

Published

2018

3. Bayesian variable selection for multivariate zero-inflated models: Application to microbiome count data.

Author

Lee, Kyu Ha, Coull, Brent A, Moscicki, Anna-Barbara, Paster, Bruce J, and Starr, Jacqueline R

Subjects

*MONTE Carlo method, *FALSE positive error, *FALSE discovery rate, *HIV infections, *TREATMENT effectiveness, *MARKOV chain Monte Carlo, *STATISTICS, *RESEARCH, *ORAL health, *RESEARCH methodology, *MEDICAL cooperation, *EVALUATION research, *COMPARATIVE studies, *RESEARCH funding, *STATISTICAL models, *PROBABILITY theory

Abstract

Microorganisms play critical roles in human health and disease. They live in diverse communities in which they interact synergistically or antagonistically. Thus for estimating microbial associations with clinical covariates, such as treatment effects, joint (multivariate) statistical models are preferred. Multivariate models allow one to estimate and exploit complex interdependencies among multiple taxa, yielding more powerful tests of exposure or treatment effects than application of taxon-specific univariate analyses. Analysis of microbial count data also requires special attention because data commonly exhibit zero inflation, i.e., more zeros than expected from a standard count distribution. To meet these needs, we developed a Bayesian variable selection model for multivariate count data with excess zeros that incorporates information on the covariance structure of the outcomes (counts for multiple taxa), while estimating associations with the mean levels of these outcomes. Though there has been much work on zero-inflated models for longitudinal data, little attention has been given to high-dimensional multivariate zero-inflated data modeled via a general correlation structure. Through simulation, we compared performance of the proposed method to that of existing univariate approaches, for both the binary ("excess zero") and count parts of the model. When outcomes were correlated the proposed variable selection method maintained type I error while boosting the ability to identify true associations in the binary component of the model. For the count part of the model, in some scenarios the univariate method had higher power than the multivariate approach. This higher power was at a cost of a highly inflated false discovery rate not observed with the proposed multivariate method. We applied the approach to oral microbiome data from the Pediatric HIV/AIDS Cohort Oral Health Study and identified five (of 44) species associated with HIV infection. [ABSTRACT FROM AUTHOR]

Published

2020

4. Lagged kernel machine regression for identifying time windows of susceptibility to exposures of complex mixtures

Author

Liu, Shelley H, primary, Bobb, Jennifer F, additional, Lee, Kyu Ha, additional, Gennings, Chris, additional, Claus Henn, Birgit, additional, Bellinger, David, additional, Austin, Christine, additional, Schnaas, Lourdes, additional, Tellez-Rojo, Martha M, additional, Hu, Howard, additional, Wright, Robert O, additional, Arora, Manish, additional, and Coull, Brent A, additional

Published

2017

5. Lagged kernel machine regression for identifying time windows of susceptibility to exposures of complex mixtures.

Author

Liu, Shelley H, Bobb, Jennifer F, Lee, Kyu Ha, Gennings, Chris, Henn, Birgit Claus, Bellinger, David, Austin, Christine, Schnaas, Lourdes, Tellez-Rojo, Martha M, Hu, Howard, Claus Henn, Birgit, Wright, Robert O, Arora, Manish, and Coull, Brent A

Subjects

KERNEL functions, CHILDREN'S health, REGRESSION analysis, COGNITIVE ability, COLLINEATION, CHILD development, COMPARATIVE studies, COMPUTER simulation, RESEARCH methodology, MEDICAL cooperation, METALS, POLLUTANTS, RESEARCH, STATISTICS, TIME, ENVIRONMENTAL exposure, EVALUATION research, STATISTICAL models, PRENATAL exposure delayed effects

Abstract

The impact of neurotoxic chemical mixtures on children's health is a critical public health concern. It is well known that during early life, toxic exposures may impact cognitive function during critical time intervals of increased vulnerability, known as windows of susceptibility. Knowledge on time windows of susceptibility can help inform treatment and prevention strategies, as chemical mixtures may affect a developmental process that is operating at a specific life phase. There are several statistical challenges in estimating the health effects of time-varying exposures to multi-pollutant mixtures, such as: multi-collinearity among the exposures both within time points and across time points, and complex exposure-response relationships. To address these concerns, we develop a flexible statistical method, called lagged kernel machine regression (LKMR). LKMR identifies critical exposure windows of chemical mixtures, and accounts for complex non-linear and non-additive effects of the mixture at any given exposure window. Specifically, LKMR estimates how the effects of a mixture of exposures change with the exposure time window using a Bayesian formulation of a grouped, fused lasso penalty within a kernel machine regression (KMR) framework. A simulation study demonstrates the performance of LKMR under realistic exposure-response scenarios, and demonstrates large gains over approaches that consider each time window separately, particularly when serial correlation among the time-varying exposures is high. Furthermore, LKMR demonstrates gains over another approach that inputs all time-specific chemical concentrations together into a single KMR. We apply LKMR to estimate associations between neurodevelopment and metal mixtures in Early Life Exposures in Mexico and Neurotoxicology, a prospective cohort study of child health in Mexico City. [ABSTRACT FROM AUTHOR]

Published

2018