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Emerging neural specialization of the ventral occipitotemporal cortex to characters through phonological association learning in preschool children
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Emerging neural specialization of the ventral occipitotemporal cortex to characters through phonological association learning in preschool children
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Emerging neural specialization of the ventral occipitotemporal cortex to characters through phonological association learning in preschool children
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Journal Article
Emerging neural specialization of the ventral occipitotemporal cortex to characters through phonological association learning in preschool children
2019
Overview
The ventral occipitotemporal (vOT) cortex serves as a core region for visual processing, and specific areas of this region show preferential activation for various visual categories such as faces and print. The emergence of such functional specialization in the human cortex represents a pivotal developmental process, which provides a basis for targeted and efficient information processing. For example, functional specialization to print in the left vOT is an important prerequisite for fluent reading. However, it remains unclear, which processes initiate the preferential cortical activations to characters arising in the vOT during child development. Using a multimodal neuroimaging approach with preschool children at familial risk for developmental dyslexia, we demonstrate how varying levels of expertise modulate the neural response to single characters, which represent the building blocks of print units. The level of expertise to characters was manipulated firstly through brief training of false-font speech–sound associations and secondly by comparing characters for which children differed in their level of familiarity and expertise accumulated through abundant exposure in their everyday environment. Neural correlates of character processing were tracked with simultaneous high-density electroencephalography and functional magnetic resonance imaging in a target detection task. We found training performance and expertise-dependent modulation of the visual event-related potential around 220 ms (N1) and the corresponding vOT activation. Additionally, trained false-font characters revealed stronger functional connectivity between the left fusiform gyrus (FFG) seed and left superior parietal/lateral occipital cortex regions with higher training performance. In sum, our results demonstrate that learning artificial-character speech–sound associations enhances activation to trained characters in the vOT and that the magnitude of this activation and the functional connectivity of the left FFG to the parieto-occipital cortex depends on learning performance. This pattern of results suggests emerging development of the reading network after brief training that parallels network specialization during reading acquisition.
•Artificial character-speech sound training induced preferred N1 and vOT activation.•N1 and vOT BOLD tuning depends on training performance in prereaders.•Functional connectivity of left FFG and SPL also depends on training performance.•Level of expertise to character types modulates the N1 and vOT BOLD activation.•Results suggest a phonologically guided N1 and vOT tuning in children.
Publisher
Elsevier Inc,Elsevier Limited
Subject
/ Child
/ Child Development - physiology
/ Children
/ Cortex
/ Dyslexia
/ EEG
/ Electroencephalography - methods
/ ERP-N1
/ Evoked Potentials, Visual - physiology
/ Experts
/ Female
/ Functional magnetic resonance imaging
/ Functional Neuroimaging - methods
/ Humans
/ Language
/ Learning
/ Magnetic Resonance Imaging - methods
/ Male
/ Nerve Net - diagnostic imaging
/ Nerve Net - growth & development
/ Neurodevelopmental disorders
/ Occipital Lobe - diagnostic imaging
/ Occipital Lobe - growth & development
/ Pattern Recognition, Visual - physiology
/ Reading
/ Recognition, Psychology - physiology
/ Regions
/ Risk
/ Speech
/ Temporal Lobe - diagnostic imaging
/ Temporal Lobe - growth & development
/ Training
/ vOT
