Anatomy and physiology of word‑selective visual cortex: from visual features to lexical processing
Fecha
2021Autor
Caffarra, Sendy
Karipidis, Iliana I.
Yablonski, Maya
Yeatman, Jason D.
Metadatos
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Caffarra, S., Karipidis, I.I., Yablonski, M. et al. Anatomy and physiology of word-selective visual cortex: from visual features to lexical processing. Brain Struct Funct 226, 3051–3065 (2021). https://doi.org/10.1007/s00429-021-02384-8
Resumen
Over the past 2 decades, researchers have tried to uncover how the human brain can extract linguistic information from
a sequence of visual symbols. The description of how the brain’s visual system processes words and enables reading has
improved with the progressive refinement of experimental methodologies and neuroimaging techniques. This review provides
a brief overview of this research journey. We start by describing classical models of object recognition in non-human
primates, which represent the foundation for many of the early models of visual word recognition in humans. We then review
functional neuroimaging studies investigating the word-selective regions in visual cortex. This research led to the differentiation
of highly specialized areas, which are involved in the analysis of different aspects of written language. We then
consider the corresponding anatomical measurements and provide a description of the main white matter pathways carrying
neural signals crucial to word recognition. Finally, in an attempt to integrate structural, functional, and electrophysiological
findings, we propose a view of visual word recognition, accounting for spatial and temporal facets of word-selective neural
processes. This multi-modal perspective on the neural circuitry of literacy highlights the relevance of a posterior–anterior
differentiation in ventral occipitotemporal cortex for visual processing of written language and lexical features. It also highlights
unanswered questions that can guide us towards future research directions. Bridging measures of brain structure and
function will help us reach a more precise understanding of the transformation from vision to language.