Cortical thickness development of human primary visual cortex related to the age of blindness onset

Li, Qiaojun; Song, Ming; Xu, Jiayuan; Qin, Wen; Yu, Chunshui; Jiang, Tianzi

doi:10.1007/s11682-016-9576-8

Cited by 34 publications

(34 citation statements)

References 64 publications

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“…Despite the presence of a normal optic chiasm and postgeniculate white matter anisotropy, GUCY2D -LCA patients have a thickened striate gray matter layer. The degree of cortical thickening found in blind people is proportional to the timing 94 and severity of vision loss. 74 The GUCY2D -LCA population has somewhat better residual visual function than the comparison blind group.…”

Section: Discussionmentioning

confidence: 99%

Postretinal Structure and Function in Severe Congenital Photoreceptor Blindness Caused by Mutations in the GUCY2D Gene

Aguirre

Butt

Datta

et al. 2017

Invest. Ophthalmol. Vis. Sci.

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PurposeTo examine how severe congenital blindness resulting from mutations of the GUCY2D gene alters brain structure and function, and to relate these findings to the notable preservation of retinal architecture in this form of Leber congenital amaurosis (LCA).MethodsSix GUCY2D-LCA patients (ages 20–46) were studied with optical coherence tomography of the retina and multimodal magnetic resonance imaging (MRI) of the brain. Measurements from this group were compared to those obtained from populations of normally sighted controls and people with congenital blindness of a variety of causes.ResultsPatients with GUCY2D-LCA had preservation of the photoreceptors, ganglion cells, and nerve fiber layer. Despite this, visual function in these patients ranged from 20/160 acuity to no light perception, and functional MRI responses to light stimulation were attenuated and restricted. This severe visual impairment was reflected in substantial thickening of the gray matter layer of area V1, accompanied by an alteration of resting-state correlations within the occipital lobe, similar to a comparison group of congenitally blind people with structural damage to the retina. In contrast to the comparison blind population, however, the GUCY2D-LCA group had preservation of the size of the optic chiasm, and the fractional anisotropy of the optic radiations as measured with diffusion tensor imaging was also normal.ConclusionsThese results identify dissociable effects of blindness upon the visual pathway. Further, the relatively intact postgeniculate white matter pathway in GUCY2D-LCA is encouraging for the prospect of recovery of visual function with gene augmentation therapy.

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Section: Discussionmentioning

confidence: 99%

Postretinal Structure and Function in Severe Congenital Photoreceptor Blindness Caused by Mutations in the GUCY2D Gene

Aguirre

Butt

Datta

et al. 2017

Invest. Ophthalmol. Vis. Sci.

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“…The functional and structural reorganization of visual areas and other higher cortices after blindness are driven by complex influences from developmental, experience-dependent plasticity and degenerative factors558081. Early studies have demonstrated that onset age of blindness have significant impacts on the functional and structural architecture of blind brain, indicating developmental factors play important roles in reshaping visual areas158283. It can explain higher functional connectivity between the AI subregions and the visual streams in blind individuals who lost vision at their earlier age (i.e., the CB or EB) than those who lost vision at elder age (i.e., the LB).…”

Section: Discussionmentioning

confidence: 99%

Visual deprivation selectively reshapes the intrinsic functional architecture of the anterior insula subregions

Liu

Yuan

Ding

et al. 2017

Sci Rep

Self Cite

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The anterior insula (AI) is the core hub of salience network that serves to identify the most relevant stimuli among vast sensory inputs and forward them to higher cognitive regions to guide behaviour. As blind subjects were usually reported with changed perceptive abilities for salient non-visual stimuli, we hypothesized that the resting-state functional network of the AI is selectively reorganized after visual deprivation. The resting-state functional connectivity (FC) of the bilateral dorsal and ventral AI was calculated for twenty congenitally blind (CB), 27 early blind (EB), 44 late blind (LB) individuals and 50 sighted controls (SCs). The FCs of the dorsal AI were strengthened with the dorsal visual stream, while weakened with the ventral visual stream in the blind than the SCs; in contrast, the FCs of the ventral AI of the blind was strengthened with the ventral visual stream. Furthermore, these strengthened FCs of both the dorsal and ventral AI were partially negatively associated with the onset age of blindness. Our result indicates two parallel pathways that selectively transfer non-visual salient information between the deprived “visual” cortex and salience network in blind subjects.

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“…Examples of the maladaptive nature of this plasticity are abundant in the auditory system, where the magnitude of cross‐modal recruitment in the deaf is inversely related to the success of cochlear implantation (Doucet, Bergeron, Lassonde, Ferron, & Lepore, ; Giraud & Lee, ; Lee et al, ). Furthermore, the fact that structural changes within the visual system are much less pronounced in the late blind (Li et al, ; Schoth, Burgel, Dorsch, Reinges, & Krings, ; Zhang, Wan, Ge, & Zhang, ) suggests that the necessary neuronal hardware is in place for successfully processing visual inputs following restoration procedures.…”

Section: Critical and Sensitive Periods For Cross‐modal Plasticity Fomentioning

confidence: 99%

Brain (re)organization following visual loss

Voss

2018

WIRES Cognitive Science

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The study of the neural consequences of sensory loss provides a unique window into the brain's functional and organizational principles. Although the blind visual cortex has been implicated in the cross-modal processing of nonvisual inputs for quite some time, recent research has shown that certain cortical organizational principles are preserved even in the case of complete sensory loss. Furthermore, a growing body of work has shown that markers of neuroplasticity extend to neuroanatomical metrics that include cortical thickness and myelinization. Although our understanding of the mechanisms that underlie sensory deprivation-driven cross-modal plasticity is improving, several critical questions remain unanswered. The specific pathways that underlie the rerouting of nonvisual information, for instance, have not been fully elucidated. The fact that important cross-modal recruitment occurs following transient deprivation in sighted individuals suggests that significant rewiring following blindness may not be required. Furthermore, there are marked individual differences regarding the magnitude and functional relevance of the cross-modal reorganization. It is also not clear to what extent precise environmental factors may play a role in establishing the degree of reorganization across individuals, as opposed to factors that might specifically relate to the cause or the nature of the visual loss. In sum, although many unresolved questions remain, sensory deprivation continues to be an excellent model for studying the plastic nature of the brain. This article is categorized under: Psychology > Brain Function and Dysfunction Psychology > Perception and Psychophysics Neuroscience > Plasticity.

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Cortical thickness development of human primary visual cortex related to the age of blindness onset

Cited by 34 publications

References 64 publications

Postretinal Structure and Function in Severe Congenital Photoreceptor Blindness Caused by Mutations in the GUCY2D Gene

Postretinal Structure and Function in Severe Congenital Photoreceptor Blindness Caused by Mutations in the GUCY2D Gene

Visual deprivation selectively reshapes the intrinsic functional architecture of the anterior insula subregions

Brain (re)organization following visual loss

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