Network Enrichment Significance Testing in Brain-phenotype Association Studies

Overview

Journal Hum Brain Mapp

Publisher Wiley

Specialty Neurology

Date 2024 Jun 15

PMID 38878300

Authors

Sarah M Weinstein

Simon N Vandekar

Bin Li

Aaron F Alexander-Bloch

Armin Raznahan

Mingyao Li

Raquel E Gur

Ruben C Gur

David R Roalf

Min Tae M Park

Mallar Chakravarty

Erica B Baller

Kristin A Linn

Theodore D Satterthwaite

Russell T Shinohara

Affiliations

Soon will be listed here.

Abstract

Functional networks often guide our interpretation of spatial maps of brain-phenotype associations. However, methods for assessing enrichment of associations within networks of interest have varied in terms of both scientific rigor and underlying assumptions. While some approaches have relied on subjective interpretations, others have made unrealistic assumptions about spatial properties of imaging data, leading to inflated false positive rates. We seek to address this gap in existing methodology by borrowing insight from a method widely used in genetics research for testing enrichment of associations between a set of genes and a phenotype of interest. We propose network enrichment significance testing (NEST), a flexible framework for testing the specificity of brain-phenotype associations to functional networks or other sub-regions of the brain. We apply NEST to study enrichment of associations with structural and functional brain imaging data from a large-scale neurodevelopmental cohort study.

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