A Global Multicohort Study to Map Subcortical Brain Development and Cognition in Infancy and Early Childhood

Overview

Journal Nat Neurosci

Date 2023 Nov 23

PMID 37996530

Authors

Ann M Alex

Fernando Aguate

Kelly Botteron

Claudia Buss

Yap-Seng Chong

Stephen R Dager

Kirsten A Donald

Sonja Entringer

Damien A Fair

Marielle V Fortier

Nadine Gaab

John H Gilmore

Jessica B Girault

Alice M Graham

Nynke A Groenewold

Heather Hazlett

Weili Lin

Michael J Meaney

Joseph Piven

Anqi Qiu

Jerod M Rasmussen

Annerine Roos

Robert T Schultz

Michael A Skeide

Dan J Stein

Martin Styner

Paul M Thompson

Ted K Turesky

Pathik D Wadhwa

Heather J Zar

Lilla Zollei

Gustavo de Los Campos

Rebecca C Knickmeyer

Affiliations

Soon will be listed here.

Abstract

The human brain grows quickly during infancy and early childhood, but factors influencing brain maturation in this period remain poorly understood. To address this gap, we harmonized data from eight diverse cohorts, creating one of the largest pediatric neuroimaging datasets to date focused on birth to 6 years of age. We mapped the developmental trajectory of intracranial and subcortical volumes in ∼2,000 children and studied how sociodemographic factors and adverse birth outcomes influence brain structure and cognition. The amygdala was the first subcortical volume to mature, whereas the thalamus exhibited protracted development. Males had larger brain volumes than females, and children born preterm or with low birthweight showed catch-up growth with age. Socioeconomic factors exerted region- and time-specific effects. Regarding cognition, males scored lower than females; preterm birth affected all developmental areas tested, and socioeconomic factors affected visual reception and receptive language. Brain-cognition correlations revealed region-specific associations.

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