Prenatal Drug Exposure to Illicit Drugs Alters Working Memory-related Brain Activity and Underlying Network Properties in Adolescence

Overview

Journal Neurotoxicol Teratol

Specialties Neurology
Toxicology

Date 2015 Feb 17

PMID 25683798

Citations 8

Authors

Julie B Schweitzer

Tracy Riggins

Xia Liang

Courtney Gallen

Pradeep K Kurup

Thomas J Ross

Maureen M Black

Prasanna Nair

Betty Jo Salmeron

Affiliations

Soon will be listed here.

Abstract

The persistence of effects of prenatal drug exposure (PDE) on brain functioning during adolescence is poorly understood. We explored neural activation to a visuospatial working memory (VSWM) versus a control task using functional magnetic resonance imaging (fMRI) in adolescents with PDE and a community comparison group (CC) of non-exposed adolescents. We applied graph theory metrics to resting state data using a network of nodes derived from the VSWM task activation map to further explore connectivity underlying WM functioning. Participants (ages 12-15 years) included 47 adolescents (27 PDE and 20 CC). All analyses controlled for potentially confounding differences in birth characteristics and postnatal environment. Significant group by task differences in brain activation emerged in the left middle frontal gyrus (BA 6) with the CC group, but not the PDE group, activating this region during VSWM. The PDE group deactivated the culmen, whereas the CC group activated it during the VSWM task. The CC group demonstrated a significant relation between reaction time and culmen activation, not present in the PDE group. The network analysis underlying VSWM performance showed that PDE group had lower global efficiency than the CC group and a trend level reduction in local efficiency. The network node corresponding to the BA 6 group by task interaction showed reduced nodal efficiency and fewer direct connections to other nodes in the network. These results suggest that adolescence reveals altered neural functioning related to response planning that may reflect less efficient network functioning in youth with PDE.

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