Prenatal Social Disadvantage is Associated with Alterations in Functional Networks at Birth

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2024 Dec 2

PMID 39621900

Authors

Ashley N Nielsen

Regina L Triplett

Lourdes M Bernardez

Ursula A Tooley

Max P Herzberg

Rachel E Lean

Sydney Kaplan

Dominique Meyer

Jeanette K Kenley

Dimitrios Alexopoulos

David Losielle

Aidan Latham

Tara A Smyser

Arpana Agrawal

Josh S Shimony

Joshua J Jackson

J Philip Miller

Marcus E Raichle

Barbara B Warner

Cynthia E Rogers

Chad M Sylvester

Deanna M Barch

Joan L Luby

Christopher D Smyser

Affiliations

Soon will be listed here.

Abstract

Childhood exposure to social disadvantage is a major risk factor for psychiatric disorders and poor developmental, educational, and occupational outcomes, presumably because adverse exposures alter the neurodevelopmental processes that contribute to risk trajectories. Yet, given the limited social mobility in the United States and other countries, childhood social disadvantage is frequently preceded by maternal social disadvantage during pregnancy, potentially altering fetal brain development during a period of high neuroplasticity through hormonal, microbiome, epigenetic, and immune factors that cross the placenta and fetal blood-brain barrier. The current study examines prenatal social disadvantage to determine whether these exposures in utero are associated with alterations in functional brain networks as early as birth. As part of the Early Life Adversity and Biological Embedding study, mothers were recruited during pregnancy, prenatal social disadvantage was assessed across trimesters, and their healthy, full-term offspring were imaged using resting-state functional magnetic resonance imaging during the first weeks of life. Multivariate machine learning methods revealed that neonatal functional connectivity (FC) varied as a function of prenatal exposure to social disadvantage (n = 261, R = 0.43, R = 0.18), with validation in an independent sample. Alterations in FC associated with prenatal social disadvantage occurred brain-wide and were most pronounced in association networks (fronto-parietal, ventral attention, dorsal attention) and the somatomotor network. Amygdala FC was altered at birth, with a pattern shared across subcortical structures. These findings provide critical insights into how early in development functional networks begin to diverge in the context of social disadvantage and elucidate the functional networks that are most impacted.

Citing Articles

Prenatal social disadvantage is associated with alterations in functional networks at birth.

Nielsen A, Triplett R, Bernardez L, Tooley U, Herzberg M, Lean R Proc Natl Acad Sci U S A. 2024; 121(50):e2405448121.

PMID: 39621900 PMC: 11648631. DOI: 10.1073/pnas.2405448121.

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