A vast amount of literature has confirmed the role of gene-environment (G×E) interaction in the etiology of complex human diseases. Traditional methods are predominantly focused on the analysis of interaction between a single nucleotide polymorphism (SNP) and an environmental variable. Given that genes are the functional units, it is crucial to understand how gene effects (rather than single SNP effects) are influenced by an environmental variable to affect disease risk. Motivated by the increasing awareness of the power of gene-based association analysis over single variant based approach, in this work, we proposed a sparse principle component regression (sPCR) model to understand the gene-based G×E interaction effect on complex disease. W...
Gene-environment interactions (GxE) can be fundamental in applications ranging from functional genom...
Genetic and environmental factors are both known to contribute to susceptibility to complex diseases...
The analysis of gene-environment interaction (G×E) may hold the key for further understanding the et...
A vast amount of literature has confirmed the role of gene-environment (G×E) interaction in the etio...
The genetic basis of a complex trait often involves the function of multiple genetic factors, their ...
It is believed that almost all common diseases are the consequence of complex interactions between g...
Despite longstanding interest in gene-by-environment (GxE) interactions, the contribution of GxE int...
Many complex diseases are known to be affected by the interactions between genetic variants and envi...
Gene-environment (GE) interaction has important implications in the etiology of complex diseases tha...
Complex diseases are driven by multiple risk factors, including genetic variants, environmental expo...
Abstract Background Gene × environment models are widely used to assess genetic and environmental ri...
Despite considerable effort to elucidate the genetic architecture of multi-factorial traits and dise...
BACKGROUND: Complex diseases are multifactorial traits caused by both genetic and environmental fact...
Accounting for gene-environment (GxE) interactions in complex trait association studies can facilita...
Introduction: In genetic epidemiology, log-linear models of population risk may be used to study the...
Gene-environment interactions (GxE) can be fundamental in applications ranging from functional genom...
Genetic and environmental factors are both known to contribute to susceptibility to complex diseases...
The analysis of gene-environment interaction (G×E) may hold the key for further understanding the et...
A vast amount of literature has confirmed the role of gene-environment (G×E) interaction in the etio...
The genetic basis of a complex trait often involves the function of multiple genetic factors, their ...
It is believed that almost all common diseases are the consequence of complex interactions between g...
Despite longstanding interest in gene-by-environment (GxE) interactions, the contribution of GxE int...
Many complex diseases are known to be affected by the interactions between genetic variants and envi...
Gene-environment (GE) interaction has important implications in the etiology of complex diseases tha...
Complex diseases are driven by multiple risk factors, including genetic variants, environmental expo...
Abstract Background Gene × environment models are widely used to assess genetic and environmental ri...
Despite considerable effort to elucidate the genetic architecture of multi-factorial traits and dise...
BACKGROUND: Complex diseases are multifactorial traits caused by both genetic and environmental fact...
Accounting for gene-environment (GxE) interactions in complex trait association studies can facilita...
Introduction: In genetic epidemiology, log-linear models of population risk may be used to study the...
Gene-environment interactions (GxE) can be fundamental in applications ranging from functional genom...
Genetic and environmental factors are both known to contribute to susceptibility to complex diseases...
The analysis of gene-environment interaction (G×E) may hold the key for further understanding the et...