Robust semiparametric gene‐environment interaction analysis using sparse boosting

Wu, Mengyun; Ma, Shuangge

doi:10.1002/sim.8322

Cited by 12 publications

(16 citation statements)

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“…For example, Boosting, a popular machine learning method, aggregates multiple weak learners (individual features of weak predictive power for the response variable) into a strong learner (a model of strong predictive power) ( [54,55,56]). Within a regression framework, boosting has strong connections to penalization ( [57−59]), which makes it a natural choice for detecting important G × E interactions ( [60,61]). Support vector machine, another popular machine learning technique which is tightly connected to penalization in the form of "hinge loss + ridge penalty", can also be adopted for G × E interactions ( [62,63]).…”

Section: Other Variable Selection Methodsmentioning

confidence: 99%

“…Such a connection is the driving force of development of new boosting methods for detecting G × E interactions. As increasing amount of attention has been paid to robustness and hierarchical structure of interaction studies, Wu and Ma ( [61]) has proposed a robust semiparametric sparse Boosting approach for simultaneous identification of both linear and nonlinear interactions. They have adopted the Huber loss function for robustness, and a multiple imputation approach to accommodate missing values in the E factor.…”

Section: Remarks On the Choices Of Penalty Functions Under Model (6)mentioning

confidence: 99%

“…Our summary in Section 2.1 shows that besides penalization and Bayesian methods, other popular machine learning methods have also been proposed. For example, the strategy of using a stagewise approach to progressively optimize the objective function has been adopted in Boosting based G × E studies ( [60,61]). 3.…”

Section: Computational Aspects In G × E Studiesmentioning

confidence: 99%

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Gene–Environment Interaction: A Variable Selection Perspective

Zhou

Ren

et al. 2021

Methods in Molecular Biology

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Gene-environment interactions have important implications to elucidate the genetic basis of complex diseases beyond the joint function of multiple genetic factors and their interactions (or epistasis). In the past, G × E interactions have been mainly conducted within the framework of genetic association studies. The high dimensionality of G × E interactions, due to the complicated form of environmental effects and presence of a large number of genetic factors including gene expressions and SNPs, has motivated the recent development of penalized variable selection methods for dissecting G × E interactions, which has been ignored in majority of published reviews on genetic interaction studies. In this article, we first survey existing overviews on both gene-environment and gene-gene interactions. Then, after a brief introduction on the variable selection methods, we review penalization and relevant variable selection methods in marginal and joint paradigms respectively under a variety of conceptual models. Discussions on strengths and limitations, as well as computational aspects of the variable selection methods tailored for G × E studies have also been provided.

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Section: Other Variable Selection Methodsmentioning

confidence: 99%

Section: Remarks On the Choices Of Penalty Functions Under Model (6)mentioning

confidence: 99%

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Gene–Environment Interaction: A Variable Selection Perspective

Zhou

Ren

et al. 2021

Methods in Molecular Biology

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“…Our model can be potentially extended in the following aspects. First, as data contamination and outliers have been widely observed in repeated measurements, robust variable selection methods in G × E interaction studies [23,[50][51][52] can be extended to longitudinal settings. Second, recently, multiple Bayesian methods have been proposed for pinpointing important G × E interaction effects [53][54][55].…”

Section: Discussionmentioning

confidence: 99%

Penalized Variable Selection for Lipid–Environment Interactions in a Longitudinal Lipidomics Study

Zhou

Ren

et al. 2019

Genes

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Lipid species are critical components of eukaryotic membranes. They play key roles in many biological processes such as signal transduction, cell homeostasis, and energy storage. Investigations of lipid–environment interactions, in addition to the lipid and environment main effects, have important implications in understanding the lipid metabolism and related changes in phenotype. In this study, we developed a novel penalized variable selection method to identify important lipid–environment interactions in a longitudinal lipidomics study. An efficient Newton–Raphson based algorithm was proposed within the generalized estimating equation (GEE) framework. We conducted extensive simulation studies to demonstrate the superior performance of our method over alternatives, in terms of both identification accuracy and prediction performance. As weight control via dietary calorie restriction and exercise has been demonstrated to prevent cancer in a variety of studies, analysis of the high-dimensional lipid datasets collected using 60 mice from the skin cancer prevention study identified meaningful markers that provide fresh insight into the underlying mechanism of cancer preventive effects.

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“…The proposed approach is based on sparse boosting, 19 which demonstrates competitive performances in high-dimensional data analysis compared to penalization and other techniques. 15,20 In all, this study is warranted by providing a practically useful new approach for exploring heterogeneity and commonality across multiple high-dimensional datasets.…”

Section: Introductionmentioning

confidence: 99%

Robust nonparametric integrative analysis to decipher heterogeneity and commonality across subgroups using sparse boosting

Luo

Sun

2022

Statistics in Medicine

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In many biomedical problems, data are often heterogeneous, with samples spanning multiple patient subgroups, where different subgroups may have different disease subtypes, stages, or other medical contexts. These subgroups may be related, but they are also expected to have differences with respect to the underlying biology. The heterogeneous data presents a precious opportunity to explore the heterogeneities and commonalities between related subgroups. Unfortunately, effective statistical analysis methods are still lacking. Recently, several novel methods based on integrative analysis have been proposed to tackle this challenging problem. Despite promising results, the existing studies are still limited by ignoring data contamination and making strict assumptions of linear effects of covariates on response. As such, we develop a robust nonparametric integrative analysis approach to identify heterogeneity and commonality, as well as select important covariates and estimate covariate effects. Possible data contamination is accommodated by adopting the Cauchy loss function, and a nonparametric model is built to accommodate nonlinear effects. The proposed approach is based on a sparse boosting technique. The advantages of the proposed approach are demonstrated in extensive simulations. The analysis of The Cancer Genome Atlas data on glioblastoma multiforme and lung adenocarcinoma shows that the proposed approach makes biologically meaningful findings with satisfactory prediction.

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Robust semiparametric gene‐environment interaction analysis using sparse boosting

Cited by 12 publications

References 50 publications

Gene–Environment Interaction: A Variable Selection Perspective

Gene–Environment Interaction: A Variable Selection Perspective

Penalized Variable Selection for Lipid–Environment Interactions in a Longitudinal Lipidomics Study

Robust nonparametric integrative analysis to decipher heterogeneity and commonality across subgroups using sparse boosting

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