Temporo-frontal Activation During Phonological Processing Predicts Gains in Arithmetic Facts in Young Children

Overview

Journal Dev Cogn Neurosci

Publisher Elsevier

Specialties Neurology
Psychiatry

Date 2019 Dec 1

PMID 31785530

Citations 8

Authors

Macarena Suarez-Pellicioni

Lynn Fuchs

James R Booth

Affiliations

Soon will be listed here.

Abstract

Behavioral studies have shown discrepant results regarding the role of phonology in predicting math gains. The objective of this study was to use fMRI to study the role of activation during a rhyming judgment task in predicting behavioral gains on math fluency, multiplication, and subtraction skill. We focused within the left middle/superior temporal gyrus and left inferior frontal gyrus, brain areas associated with the storage of phonological representations and with their access, respectively. We ran multiple regression analyses to determine whether activation predicted gains in the three math measures, separately for younger (i.e. 10 years old) and older (i.e 12 years old) children. Results showed that activation in both temporal and frontal cortex only predicted gains in fluency and multiplication skill, and only for younger children. This study suggests that both temporal and frontal cortex activation during phonological processing are important in predicting gains in math tasks that involve the retrieval of facts that are stored as phonological codes in memory. Moreover, these results were specific to younger children, suggesting that phonology is most important in the early stages of math development. When the math task involved subtractions, which relies on quantity representations, phonological processes were not important in driving gains.

Citing Articles

Positive math attitudes are associated with greater frontal activation among children from higher socio-economic status families.

Suarez-Pellicioni M, Demir-Lira O, Booth J Neuropsychologia. 2024; 194:108788.

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Neurocognitive mechanisms of co-occurring math difficulties in dyslexia: Differences in executive function and visuospatial processing.

Marks R, Pollack C, Meisler S, DMello A, Centanni T, Romeo R Dev Sci. 2023; 27(2):e13443.

PMID: 37675857 PMC: 10918042. DOI: 10.1111/desc.13443.

Neural pathways of phonological and semantic processing and its relations to children's reading skills.

Wagley N, Booth J Front Neurosci. 2022; 16:984328.

PMID: 36312011 PMC: 9597189. DOI: 10.3389/fnins.2022.984328.

Temporal cortex activation explains children's improvement in math attitudes.

Suarez-Pellicioni M, Booth J Child Dev. 2022; 93(4):1012-1029.

PMID: 35244210 PMC: 10038318. DOI: 10.1111/cdev.13749.

Neurocognitive mechanisms explaining the role of math attitudes in predicting children's improvement in multiplication skill.

Suarez-Pellicioni M, Demir-Lira O, Booth J Cogn Affect Behav Neurosci. 2021; 21(5):917-935.

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