Avoiding the high Bonferroni penalty in genome-wide association studies

## Abstract The potential of genome‐wide association analysis can only be realized when they have power to detect signals despite the detrimental effect of multiple testing on power. We develop a weighted multiple testing procedure that facilitates the input of prior information in the form of grou

## Abstract Genome‐wide association studies employ hundreds of thousands of statistical tests to determine which regions of the genome may likely harbor disease‐causing alleles. Such large‐scale testing simultaneously requires stringent control over type I error and maintenance of sufficient power

## Abstract Genome‐wide case‐control association study is gaining popularity, thanks to the rapid development of modern genotyping technology. In such studies, population stratification is a potential concern especially when the number of study subjects is large as it can lead to seriously inflated

## Abstract Though multiple interacting loci are likely involved in the etiology of complex diseases, early genome‐wide association studies (GWAS) have depended on the detection of the marginal effects of each locus. Here, we evaluate the power of GWAS in the presence of two linked and potentially

## Abstract Genome‐wide association studies (GWAS) have been widely used to identify genetic effects on complex diseases or traits. Most currently used methods are based on separate single‐nucleotide polymorphism (SNP) analyses. Because this approach requires correction for multiple testing to avoi

## Abstract In this paper we investigate the power to identify gene × gene interactions in genome‐wide association studies. In our analysis we focus on two‐stage analyses: analyses in which we only test for interactions between single nucleotide polymorphisms that show some marginal effect. We give