Enhanced verbal abilities in the congenitally blind

Occelli, Valeria; Lacey, Simon; Stephens, Careese; Merabet, Lotfi B.; Sathian, K.

doi:10.1007/s00221-017-4931-6

Cited by 18 publications

(19 citation statements)

References 51 publications

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“…Sustained neural activity is a neural correlate of working memory 74,75 , which, in the present study, persisted longer in the blind compared to the sighted model. This phenomenon in the network is consistent with the observation of enhanced verbal working memory performance in congenitally blind individuals compared to control sighted ones 22,[31][32][33] . Note, furthermore, that during the reverberation phase, activity retreats from modality-specific to the modality general association cortices in frontal and temporal cortex (*AT, *PF) in both sighted (time steps [12][13][14] and blind models (time steps [17][18][19].…”

Section: Discussionsupporting

confidence: 90%

“…Similar differences in V1 activation have also been reported for single word 27,28 and sentence processing tasks 29,30 , which imply semantic understanding [27][28][29] . Furthermore, congenitally blind people with relatively stronger V1 activity in the processing of meaningful language were reported to show better verbal working memory 22 and generally enhanced verbal abilities compared to sighted individuals 22,[31][32][33] . Although one might argue that visual responses in blind individuals are epiphenomenal with no functional relevance for language processing, a study inducing temporary virtual lesions of the primary visual area (V1) using transcranial magnetic stimulation (TMS) during a verb generation task showed an increase in semantic (but not phonological) errors in blind individuals.…”

Section: Visual Cortex Recruitment During Language Processing In Blinmentioning

confidence: 99%

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Visual cortex recruitment during language processing in blind individuals is explained by Hebbian learning

Tomasello

Wennekers

Garagnani

et al. 2019

Sci Rep

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In blind people, the visual cortex takes on higher cognitive functions, including language. Why this functional reorganisation mechanistically emerges at the neuronal circuit level is still unclear. Here, we use a biologically constrained network model implementing features of anatomical structure, neurophysiological function and connectivity of fronto-temporal-occipital areas to simulate word-meaning acquisition in visually deprived and undeprived brains. We observed that, only under visual deprivation, distributed word-related neural circuits ‘grew into’ the deprived visual areas, which therefore adopted a linguistic-semantic role. Three factors are crucial for explaining this deprivation-related growth: changes in the network’s activity balance brought about by the absence of uncorrelated sensory input, the connectivity structure of the network, and Hebbian correlation learning. In addition, the blind model revealed long-lasting spiking neural activity compared to the sighted model during word recognition, which is a neural correlate of enhanced verbal working memory. The present neurocomputational model offers a neurobiological account for neural changes following sensory deprivation, thus closing the gap between cellular-level mechanisms, system-level linguistic and semantic function.

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Section: Discussionsupporting

confidence: 90%

Section: Visual Cortex Recruitment During Language Processing In Blinmentioning

confidence: 99%

Visual cortex recruitment during language processing in blind individuals is explained by Hebbian learning

Tomasello

Wennekers

Garagnani

et al. 2019

Sci Rep

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“…Regarding the working memory data, we observed that blind children outperformed their sighted peers on all the verbal memory tasks (both on the simple and on the complex span tasks). In contrast, the groups did not differ significantly on the spatial task, similarly to what has already been observed with adults (Castronovo & Delvenne, 2013;Dormal et al, 2016;Occelli, Lacey, Stephens, Merabet, & Sathian, 2017). Interestingly, while the sighted showed a larger spatial span when performing the task in their dominant visual modality, there was no difference between the blind tactile span and the sighted visual one.…”

Section: Discussionsupporting

confidence: 81%

Early visual deprivation does not prevent the emergence of basic numerical abilities in blind children

et al. 2021

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Studies involving congenitally blind adults demonstrated that visual experience is not a mandatory prerequisite for the emergence of efficient numerical abilities. It remains however unknown whether blind adults developed lifelong strategies to compensate for the absence of foundations vision would provide in infancy. We therefore assessed basic numerical abilities in blind and sighted children of 6 to 13 years old. We also assessed verbal and spatial working memory abilities and their relationship with mental arithmetic in both groups. Blind children showed similar or better numerical abilities as compared to the sighted. Blind children also outperformed their sighted peers in every task assessing verbal working memory and demonstrated a similar spatial span. The correlation between arithmetic and the spatial sketchpad was affected by the group while the correlations between arithmetic and the other two components (the central executive and the phonological loop) were not affected by early visual experience. Our data suggest that early blindness does not impair the development of basic numerical competencies in children but influences the associations between arithmetic and some working memory components.

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“…Congenitally blind adults also show superior performance on some linguistic tasks that recruit the "visual" cortex e.g. verbal memory (Amedi, Raz, Pianka, Malach, & Zohary, 2003;Occelli, Lacey, Stephens, Merabet, & Sathian, 2017;Pasqualotto, Lam, & Proulx, 2013). By contrast, there is at present no evidence for functional relevance of visual cortices to language (or any other cognitive function) in adult-onset blindness.…”

Section: A Sensitive Period In the Neural Substrates Of Language In Bmentioning

confidence: 98%

A sensitive period in the neural phenotype of language in blind individuals

Pant

Kanjlia²,

Bedny³

2019

Preprint

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In congenital blindness, "visual" cortices respond to linguistic information, and fronto-temporal language networks are less left-lateralized. Does this plasticity follow a sensitive period? We tested this by comparing the neural basis of sentence processing in two experiments with adult-onset blind (AB, n=16), congenitally blind (CB, n=22) and blindfolded sighted controls (n=18). In Experiment 1, participants made semantic judgments for spoken sentences and solved math equations in a control condition. In Experiment 2, participants answered "who did what to whom" questions for grammatically complex (with syntactic movement) and grammatically simpler sentences. In a control condition, participants performed a memory task with lists of non-words. In both experiments, visual cortices of CB and AB but not sighted participants responded more to sentences than control conditions, but the effect was much larger in the CB group. Crucially, only the "visual" cortex of CB participants responded to grammatical complexity. Unlike the CB group, the AB group showed no reduction in left-lateralization of fronto-temporal language network relative to the sighted. These results suggest that blindness during development modifies the neural basis of language, and this effect follows a sensitive period.

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Enhanced verbal abilities in the congenitally blind

Cited by 18 publications

References 51 publications

Visual cortex recruitment during language processing in blind individuals is explained by Hebbian learning

Visual cortex recruitment during language processing in blind individuals is explained by Hebbian learning

Early visual deprivation does not prevent the emergence of basic numerical abilities in blind children

A sensitive period in the neural phenotype of language in blind individuals

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