Developmental dissociation in the neural responses to simple multiplication and subtraction problems

Developmental dissociation in the neural responses to simple multiplication and subtraction problems

Mastering single‐digit arithmetic during school years is commonly thought to depend upon an increasing reliance on verbally memorized facts. An alternative model, however, posits that fluency in single‐digit arithmetic might also be achieved via the increasing use of efficient calculation procedures...

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Bibliographic Details
Published in:Developmental science Vol. 17; no. 4; pp. 537 - 552
Main Authors: Prado, Jérôme, Mutreja, Rachna, Booth, James R.
Format: Journal Article
Language:English
Published: England Blackwell Publishing Ltd 01-07-2014
Wiley-Blackwell
Wiley Subscription Services, Inc
Wiley
Subjects:
Age Differences
Arithmetic
Behavior
Brain
Brain - physiology
Brain Hemisphere Functions
Brain Mapping
Child
Child development
Cognition & reasoning
Cognitive Processes
Cognitive science
Computation
Correlation
Cross-Sectional Studies
Elementary School Students
Female
Grade 2
Grade 3
Grade 4
Grade 5
Grade 6
Grade 7
Humans
Hypothesis Testing
Junior High School Students
Language
Learning
Magnetic Resonance Imaging
Male
Mathematical Concepts
Mathematics
Middle School Students
Models, Neurological
Multiplication
Multiplication & division
Neurology
Neurons - physiology
Numeracy
Parietal Lobe - physiology
Subtraction
Temporal Lobe - physiology
Time Factors
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Summary:Mastering single‐digit arithmetic during school years is commonly thought to depend upon an increasing reliance on verbally memorized facts. An alternative model, however, posits that fluency in single‐digit arithmetic might also be achieved via the increasing use of efficient calculation procedures. To test between these hypotheses, we used a cross‐sectional design to measure the neural activity associated with single‐digit subtraction and multiplication in 34 children from 2nd to 7th grade. The neural correlates of language and numerical processing were also identified in each child via localizer scans. Although multiplication and subtraction were undistinguishable in terms of behavior, we found a striking developmental dissociation in their neural correlates. First, we observed grade‐related increases of activity for multiplication, but not for subtraction, in a language‐related region of the left temporal cortex. Second, we found grade‐related increases of activity for subtraction, but not for multiplication, in a region of the right parietal cortex involved in the procedural manipulation of numerical quantities. The present results suggest that fluency in simple arithmetic in children may be achieved by both increasing reliance on verbal retrieval and by greater use of efficient quantity‐based procedures, depending on the operation. Mastering single‐digit arithmetic during school years is commonly thought to depend upon an increasing reliance on verbally memorized facts. An alternative model, however, posits that fluency in single‐digit arithmetic might also be achieved via the increasing use of efficient calculation procedures. To test between these hypotheses, we used a cross‐sectional design to measure the neural activity associated with single‐digit subtraction and multiplication in 34 children from 2nd to 7th grade.
Bibliography:National Institute of Child Health and Human Development - No. HD059177
ArticleID:DESC12140
Figure S1. Right Intraparietal sulcus (IPS). (A) Location of the right IPS ROI overlaid on a 3D rendering of the MNI-normalized anatomical brain. (B) Activity in the right IPS as a function of operation and grade. Smaller and larger problems were combined because grade-related differences did not vary with problem size (see text). (C) Median-split analysis. Activity in the right IPS as a function of operation and problem size in lower (left) and higher (right) graders.Figure S2. Left Inferior Frontal Gyrus (IFG). (A) Location of the left IFG ROI overlaid on a 3D rendering of the MNI-normalized anatomical brain. (B) Activity in the left IFG as a function of operation and grade. Smaller and larger problems were combined because grade-related differences did not vary with problem size (see text). (C) Median-split analysis. Activity in the left IFG as a function of operation and problem size in lower (left) and higher (right) graders.Figure S3. Whole-brain analysis. (A) Regions showing a grade-related increase of activity for smaller subtraction. (B) Regions showing a greater grade-related increase of activity for smaller subtraction than smaller multiplication. (C) Regions showing more activity for larger than smaller subtraction across all subjects. (D) Regions showing more activity for larger than smaller multiplication across all subjects. All activations are overlaid on a 3D rendering of the MNI-normalized anatomical brain. PSPL: Posterior Superior Parietal Lobule, MOG: bilateral Middle Occipital Gyrus, Prec: Precuneus, IPS: Intraparietal Sulcus, ACC: Anterior Cingulate Cortex, DLPFC: Dorsolateral Prefrontal Cortex.
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ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
PMCID: PMC4122319
ISSN:1363-755X
1467-7687
DOI:10.1111/desc.12140