Multilayer Network Associations Between the Exposome and Childhood Brain Development

Overview

Journal bioRxiv

Date 2023 Nov 14

PMID 37961103

Authors

Ivan L Simpson-Kent

Martins M Gatavins

Ursula A Tooley

Austin L Boroshok

Cassidy L McDermott

Anne T Park

Lourdes Delgado Reyes

Joe Bathelt

M Dylan Tisdall

Allyson P Mackey

Affiliations

Soon will be listed here.

Abstract

Growing up in a high poverty neighborhood is associated with elevated risk for academic challenges and health problems. Here, we take a data-driven approach to exploring how measures of children's environments relate to the development of their brain structure and function in a community sample of children between the ages of 4 and 10 years. We constructed exposomes including measures of family socioeconomic status, children's exposure to adversity, and geocoded measures of neighborhood socioeconomic status, crime, and environmental toxins. We connected the exposome to two structural measures (cortical thickness and surface area, = 170) and two functional measures (participation coefficient and clustering coefficient, = 130). We found dense connections exposome and brain layers and sparse connections exposome and brain layers. Lower family income was associated with thinner visual cortex, consistent with the theory that accelerated development is detectable in early-developing regions. Greater neighborhood incidence of high blood lead levels was associated with greater segregation of the default mode network, consistent with evidence that toxins are deposited into the brain along the midline. Our study demonstrates the utility of multilayer network analysis to bridge environmental and neural explanatory levels to better understand the complexity of child development.

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