Subgroup Identification in Clinical Trials

Li, Xiaochen

04 1900

Indiana University-Purdue University Indianapolis (IUPUI) / Subgroup analyses assess the heterogeneity of treatment effects in groups of patients defined by patients’ baseline characteristics. Identifying subgroup of patients with differential treatment effect is crucial for tailored therapeutics and personalized medicine. Model-based variable selection methods are well developed and widely applied to select significant treatment-by-covariate interactions for subgroup analyses. Machine learning and data-driven based methods for subgroup identification have also been developed. In this dissertation, I consider two different types of subgroup identification methods: one is nonparametric machine learning based and the other is model based. In the first part, the problem of subgroup identification was transferred to an optimization problem and a stochastic search technique was implemented to partition the whole population into disjoint subgroups with differential treatment effect. In the second approach, an integrative three-step model-based variable selection method was proposed for subgroup analyses in longitudinal data. Using this three steps variable selection framework, informative features and their interaction with the treatment indicator can be identified for subgroup analysis in longitudinal data. This method can be extended to longitudinal binary or categorical data. Simulation studies and real data examples were used to demonstrate the performance of the proposed methods. / 2022-05-06

Clinical trials

Statistical heterogeneity

Subgroup identification

Variable selection

Linear Mixed Model Selection by Partial Correlation

Alabiso, Audry

29 April 2020

No description available.

Statistics

Linear Mixed Model

High Dimensional Variable Selection

Partial Faithfulness

Predicting Monthly Precipitation in Ontario using a Multi-Model Ensemble and the XGBoost Algorithm

Hadzi-Tosev, Milena

January 2020

There is a strong interest in the climate community to improve the ability to accurately predict future trends of climate variables. Recently, machine learning methods have proven their ability to contribute to more accurate predictions of historical data on a variety of climate variables. There is also a strong interest in using statistical downscaling to predict local station data from the output of multi-model ensembles. This project looks at using the machine learning algorithm XGBoost and evaluating its ability to accurately predict historical monthly precipitation, with a focus of applying this method to simulate future precipitation trends. / Thesis / Master of Science (MSc)

climate modeling

machine learning

precipitation

variable selection

statistical downscaling

On Multiplicity Adjustment in Bayesian Variable Selection and An Objective Bayesian Analysis of a Crossover Design

Li, Dandan

23 October 2014

No description available.

Statistics

multiplicity adjustment

variable selection

objective Bayesian

crossover design

A Bayesian Approach to Prediction and Variable Selection Using Nonstationary Gaussian Processes

Davis, Casey Benjamin

28 May 2015

No description available.

Statistics

nonstationary

Gaussian processes

Bayesian

prediction

variable selection

screening

A Penalized Approach to Mixed Model Selection Via Cross Validation

Xiong, Jingwei

05 December 2017

No description available.

Statistics

linear mixed models

penalized approaches

variable selection

cross validation

Two Essays on High-Dimensional Robust Variable Selection and an Application to Corporate Bankruptcy Prediction

Li, Shaobo

29 October 2018

No description available.

Statistics

Variable selection

LASSO

robust statistics

default risk

Improving the Accuracy of Variable Selection Using the Whole Solution Path

Liu, Yang

23 July 2015

No description available.

Statistics

variable selection

high dimensional data

SPSP

AIS

Multilevel Model Selection: A Regularization Approach Incorporating Heredity Constraints

Stone, Elizabeth Anne

January 2013

This dissertation focuses on estimation and selection methods for a simple linear model with two levels of variation. This model provides a foundation for extensions to more levels. We propose new regularization criteria for model selection, subset selection, and variable selection in this context. Regularization is a penalized-estimation approach that shrinks the estimate and selects variables for structured data. This dissertation introduces a procedure (HM-ALASSO) that extends regularized multilevel-model estimation and selection to enforce principles of fixed heredity (e.g., including main effects when their interactions are included) and random heredity (e.g., including fixed effects when their random terms are included). The goals in developing this method were to create a procedure that provided reasonable estimates of all parameters, adhered to fixed and random heredity principles, resulted in a parsimonious model, was theoretically justifiable, and was able to be implemented and used in available software. The HM-ALASSO incorporates heredity-constrained selection directly into the estimation process. HM-ALASSO is shown to enjoy the properties of consistency, sparsity, and asymptotic normality. The ability of HM-ALASSO to produce quality estimates of the underlying parameters while adhering to heredity principles is demonstrated using simulated data. The performance of HM-ALASSO is illustrated using a subset of the High School and Beyond (HS&B) data set that includes math-achievement outcomes modeled via student- and school-level predictors. The HM-ALASSO framework is flexible enough that it can be adapted for various rule sets and parameterizations. / Statistics

Statistics

Hierarchical Linear Model

Mixed-effects Model

Variable Selection

Spatially Correlated Model Selection (SCOMS)

Velasco-Cruz, Ciro

31 May 2012

In this dissertation, a variable selection method for spatial data is developed. It is assumed that the spatial process is non-stationary as a whole but is piece-wise stationary. The pieces where the spatial process is stationary are called regions. The variable selection approach accounts for two sources of correlation: (1) the spatial correlation of the data within the regions, and (2) the correlation of adjacent regions. The variable selection is carried out by including indicator variables that characterize the significance of the regression coefficients. The Ising distribution as prior for the vector of indicator variables, models the dependence of adjacent regions. We present a case study on brook trout data where the response of interest is the presence/absence of the fish at sites in the eastern United States. We find that the method outperforms the case of the probit regression where the spatial field is assumed stationary and isotropic. Additionally, the method outperformed the case where multiple regions are assumed independent of their neighbors. / Ph. D.

Spatial statistics

Ising prior

Non-stationary spatial fields

Variable Selection