Neural Correlates Associated with Superior Tactile Symmetry Perception in the Early Blind

Overview

Journal Cortex

Specialties Neurology
Psychology
Social Sciences

Date 2014 Sep 23

PMID 25243993

Citations 19

Authors

Corinna Bauer

Lindsay Yazzolino

Gabriella Hirsch

Zaira Cattaneo

Tomaso Vecchi

Lotfi B Merabet

Affiliations

Soon will be listed here.

Abstract

Symmetry is an organizational principle that is ubiquitous throughout the visual world. However, this property can also be detected through non-visual modalities such as touch. The role of prior visual experience on detecting tactile patterns containing symmetry remains unclear. We compared the behavioral performance of early blind and sighted (blindfolded) controls on a tactile symmetry detection task. The tactile patterns used were similar in design and complexity as in previous visual perceptual studies. The neural correlates associated with this behavioral task were identified with functional magnetic resonance imaging (fMRI). In line with growing evidence demonstrating enhanced tactile processing abilities in the blind, we found that early blind individuals showed significantly superior performance in detecting tactile symmetric patterns compared to sighted controls. Furthermore, comparing patterns of activation between these two groups identified common areas of activation (e.g. superior parietal cortex) but key differences also emerged. In particular, tactile symmetry detection in the early blind was also associated with activation that included peri-calcarine cortex, lateral occipital (LO), and middle temporal (MT) cortex, as well as inferior temporal and fusiform cortex. These results contribute to the growing evidence supporting superior behavioral abilities in the blind, and the neural correlates associated with crossmodal neuroplasticity following visual deprivation.

Citing Articles

Perception and discrimination of real-life emotional vocalizations in early blind individuals.

Ferrari C, Arioli M, Atias D, Merabet L, Cattaneo Z Front Psychol. 2024; 15:1386676.

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Decoding Reach Direction in Early "Visual" Cortex of Congenitally Blind Individuals.

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Reading Braille by Touch Recruits Posterior Parietal Cortex.

Liu Y, Rapp B, Bedny M J Cogn Neurosci. 2023; 35(10):1593-1616.

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