The Attention Set-shifting Test is Sensitive for Revealing Sex-based Impairments in Executive Functions Following Developmental Lead Exposure in Rats

Overview

Journal Behav Brain Res

Specialties Neurology
Psychology
Social Sciences

Date 2019 Mar 18

PMID 30878351

Citations 8

Authors

Lorenz S Neuwirth

Sidrah Masood

David W Anderson

Jay S Schneider

Affiliations

Soon will be listed here.

Abstract

The literature on lead (Pb) exposure has focused in large part on hippocampal-based learning and memory deficits, although frontoexecutive dysfunctions are known to exist in Pb-exposed humans. This study examined the effects of perinatal (PERI) and early postnatal (EPN) developmental low-level Pb-exposures in rats on frontoexecutive functions, using the Attention Set-Shift Test (ASST). Control males and females performed the ASST similarly. Male EPN rats had difficulty with simple discrimination (SD) of odors and failed to complete the compound discrimination (CD) stage of the ASST. All other Pb-exposed rats completed the training and testing. Male PERI rats performed worse on the SD, intradimensional (ID), and intradimensional-reversal (ID-Rev) ASST stages when compared to male Control rats. Female EPN rats performed similar to Controls on the ID-Rev rats, whereas PERI rats performed better the trials-to-criterion on the ID-Rev than EPN and Control rats. Pb-exposed female rats had significant difficulty performing the ED/ED-Rev stages, with the number of trials-to-criterion double that required by Pb-exposed and Control male rats and Control female rats. Together, the ASST results showed that developmental Pb-exposure induces frontoexecutive dysfunction that persists into adulthood, with different sex-based vulnerabilities dependent upon the time-period of neurotoxicant exposure.

Citing Articles

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Low-level Lead Exposure Impairs Fronto-executive Functions: A Call to Update the DSM-5 with Lead Poisoning as a Neurodevelopmental Disorder.

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