Finger-Based Numerical Training Increases Sensorimotor Activation for Arithmetic in Children-An FNIRS Study

Overview

Journal Brain Sci

Publisher MDPI

Date 2022 May 28

PMID 35625023

Authors

Christina Artemenko

Silke Maria Wortha

Thomas Dresler

Mirjam Frey

Roberta Barrocas

Hans-Christoph Nuerk

Korbinian Moeller

Affiliations

Soon will be listed here.

Abstract

Most children use their fingers when learning to count and calculate. These sensorimotor experiences were argued to underlie reported behavioral associations of finger gnosis and counting with mathematical skills. On the neural level, associations were assumed to originate from overlapping neural representations of fingers and numbers. This study explored whether finger-based training in children would lead to specific neural activation in the sensorimotor cortex, associated with finger movements, as well as the parietal cortex, associated with number processing, during mental arithmetic. Following finger-based training during the first year of school, trained children showed finger-related arithmetic effects accompanied by activation in the sensorimotor cortex potentially associated with implicit finger movements. This indicates embodied finger-based numerical representations after training. Results for differences in neural activation between trained children and a control group in the IPS were less conclusive. This study provides the first evidence for training-induced sensorimotor plasticity in brain development potentially driven by the explicit use of fingers for initial arithmetic, supporting an embodied perspective on the representation of numbers.

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