Activation of the primary visual cortex by Braille reading in blind subjects

Sadato, Norihiro; Pascual‐Leone, Álvaro; Grafman, Jordan; Ibáñez, Vicente; Deiber, Marie-Pierre; Dold, George; Hallett, Mark

doi:10.1038/380526a0

Cited by 1,065 publications

(713 citation statements)

References 17 publications

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“…For example, Neville et al reported changes in evoked visual response in congenitally deaf persons and interprfeted it as a neuroplastic change, in which visual input invades unused areas of the auditory cortex. [27] These fi nding were later confi rmed in studies of subjects with single sensory deprivation (auditory or visual) using neuroimaging techniques with greater spatial resolution (fMRI and PET), [5,[28][29][30] which demonstrated extensive cerebral reorganization in cortical areas, showing how auditory areas of the brain are activated by visual stimuli in deaf persons, [3] while the visual cortex is activated by somatosensory and auditory stimuli in blind persons. [5,28,31,32] Our fi ndings could be ascribed to this form of neuroplasticity, CMP.…”

Section: Discussionmentioning

confidence: 83%

See 1 more Smart Citation

Cross-modal plasticity in cuban visually-impaired child cochlear implant candidates: topography of somatosensory evoked potentials

Charroó-Ruíz¹,

Pérez-Abalo²,

Hernández³

et al. 2012

MEDICC rev.

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Section: Discussionmentioning

confidence: 83%

“…[2][3][4] Furthermore, it has been shown that in the congenitally blind, visual cortical areas are activated during linguistic processing via touch. [5] This evidence of cortical reorganization is known as cross-modal plasticity (CMP).…”

Section: Introductionmentioning

confidence: 99%

Cross-modal plasticity in cuban visually-impaired child cochlear implant candidates: topography of somatosensory evoked potentials

Charroó-Ruíz¹,

Pérez-Abalo²,

Hernández³

et al. 2012

MEDICC rev.

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“…There is growing evidence for early sensory interactions between vision and touch, and it has been suggested that the reorganization of the visual cortex of blind individuals that occurs in the absence of visual input reinforces preexisting connections between the somatosensory and visual cortices (see a review by Pascual-Leone, Amedi, & Fregni, 2005). Consistent with this suggestion, studies have demonstrated that the visual cortex of blind individuals is activated during tasks such as Braille reading (Cohen et al, 1997;Sadato et al, 1996) and haptic object recognition (Amedi, Raz, Azulay, Malach, & Zohary, 2010). Moreover, the existence of networks between vision and touch in normally sighted individuals is supported by neuroimaging studies; visual areas have been shown to be activated during tactile orientation discrimination (Sathian & Zangaladze, 2002;Sathian, Zangaladze, Epstein, & Grafton, 1999), haptic object recognition (Amedi, Jacobson, Hendler, Malach, & Zohary, 2002;Amedi et al, 2010;Deibert, Kraut, Kremen, & Hart, 1999;James, Humphrey, Gati, Servos, Menon, & Goodale, 2002;Pietrini et al, 2004), and Braille reading in sighted subjects following 5 days of complete visual deprivation (Merabet et al, 2008).…”

Section: Introductionmentioning

confidence: 93%

Cross-modal associations between vision, touch, and audition influence visual search through top-down attention, not bottom-up capture

Orchard-Mills

Alais

Burg

2013

Atten Percept Psychophys

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Recently, Guzman-Martinez, Ortega, Grabowecky, Mossbridge, and Suzuki (Current Biology : CB, 22(5), [383][384][385][386][387][388] 2012) reported that observers could systematically match auditory amplitude modulations and tactile amplitude modulations to visual spatial frequencies, proposing that these cross-modal matches produced automatic attentional effects. Using a series of visual search tasks, we investigated whether informative auditory, tactile, or bimodal cues can guide attention toward a visual Gabor of matched spatial frequency (among others with different spatial frequencies). These cues improved visual search for some but not all frequencies. Auditory cues improved search only for the lowest and highest spatial frequencies, whereas tactile cues were more effective and frequency specific, although less effective than visual cues. Importantly, although tactile cues could produce efficient search when informative, they had no effect when uninformative. This suggests that cross-modal frequency matching occurs at a cognitive rather than sensory level and, therefore, influences visual search through voluntary, goaldirected behavior, rather than automatic attentional capture.

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“…Sadato et al [1996] used positron emission tomography (PET) to demonstrate that Braille reading in these subjects activated the somatosensory cortex assigned to the Braille reading fingers, as well as the primary visual cortex. They also showed that transient inactivation of the occipital cortex with transcranial magnetic stimulation (TMS) impaired tactile discrimination in the blind subjects but did not affect sensation in nonblind individuals [Cohen et al, 1997].…”

Section: Clinical Examples Of Plasticity and Reorganization In Cerebrmentioning

confidence: 99%

Plasticity in the developing brain: Implications for rehabilitation

Johnston

2009

Dev Disabil Res Revs

442

273

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Neuronal plasticity allows the central nervous system to learn skills and remember information, to reorganize neuronal networks in response to environmental stimulation, and to recover from brain and spinal cord injuries. Neuronal plasticity is enhanced in the developing brain and it is usually adaptive and beneficial but can also be maladaptive and responsible for neurological disorders in some situations. Basic mechanisms that are involved in plasticity include neurogenesis, programmed cell death, and activity-dependent synaptic plasticity. Repetitive stimulation of synapses can cause long-term potentiation or long-term depression of neurotransmission. These changes are associated with physical changes in dendritic spines and neuronal circuits. Overproduction of synapses during postnatal development in children contributes to enhanced plasticity by providing an excess of synapses that are pruned during early adolescence. Clinical examples of adaptive neuronal plasticity include reorganization of cortical maps of the fingers in response to practice playing a stringed instrument and constraint-induced movement therapy to improve hemiparesis caused by stroke or cerebral palsy. These forms of plasticity are associated with structural and functional changes in the brain that can be detected with magnetic resonance imaging, positron emission tomography, or transcranial magnetic stimulation (TMS). TMS and other forms of brain stimulation are also being used experimentally to enhance brain plasticity and recovery of function. Plasticity is also influenced by genetic factors such as mutations in brain-derived neuronal growth factor. Understanding brain plasticity provides a basis for developing better therapies to improve outcome from acquired brain injuries. ' 2009 Wiley-Liss, Inc. Dev Disabil Res Rev 200915:94-101.

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Activation of the primary visual cortex by Braille reading in blind subjects

Cited by 1,065 publications

References 17 publications

Cross-modal plasticity in cuban visually-impaired child cochlear implant candidates: topography of somatosensory evoked potentials

Cross-modal plasticity in cuban visually-impaired child cochlear implant candidates: topography of somatosensory evoked potentials

Cross-modal associations between vision, touch, and audition influence visual search through top-down attention, not bottom-up capture

Plasticity in the developing brain: Implications for rehabilitation

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