Whole brain functional connectivity in the early blind

Liu, Yong; Yu, Chunshui; Liang, Meng; Li, Jun; Tian, Lihong; Zhou, Yuan; Qin, Wen; Li, Kuncheng; Jiang, Tianzi

doi:10.1093/brain/awm121

Cited by 258 publications

(250 citation statements)

References 86 publications

(138 reference statements)

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“…A finding that initially seems at odds with our data is that Liu et al (2007) and Yu et al (2008) reported decreased functional connectivity [i.e., correlations of the BOLD signal between brain regions (Friston et al, 1993)] in blind volunteers compared with controls between visual and auditory cortical areas during resting-state fMRI. However, if one considers that the visual cortex can also be activated by auditory stimuli in sighted if the task requires high levels of attention (Cate et al, 2009), the results seem more alike: possibly, the visual cortex of blind people is predominantly recruited during demanding tasks or when relevant information is supplied (Röder et al, 1996).…”

Section: Figurecontrasting

confidence: 96%

“…However, if one considers that the visual cortex can also be activated by auditory stimuli in sighted if the task requires high levels of attention (Cate et al, 2009), the results seem more alike: possibly, the visual cortex of blind people is predominantly recruited during demanding tasks or when relevant information is supplied (Röder et al, 1996). This would explain why resting-state studies (no attentional demands) failed to find coupling (Liu et al, 2007;Yu et al, 2008), whereas activation-based effective-connectivity studies did find enhanced coupling in the blind (Fujii et al, 2009;present study). This hypothesis is also backed by studies that found attentional modulations of visual cortex activity in the blind (Liotti et al, 1998;Stevens et al, 2007).…”

Section: Figurementioning

confidence: 99%

“…Additional evidence for corticocortical connectivity from auditory to visual cortex comes from activation-based fMRI studies in both sighted (den Ouden et al, 2009;Werner and Noppeney, 2010) and blind humans (Fujii et al, 2009). Support for thalamocortical connections in the blind comes from a resting-state fMRI study (Liu et al, 2007), but a degeneration of the lateral geniculate nucleus (LGN) has also been observed in the blind (Noppeney et al, 2005). Hence, corticocortical connections seem more probable than thalamocortical connections to be mediating auditory responses in the visual cortex of the blind.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Corticocortical Connections Mediate Primary Visual Cortex Responses to Auditory Stimulation in the Blind

Klinge

Eippert²,

Röder³

et al. 2010

J. Neurosci.

133

121

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Blind individuals have to rely on nonvisual information to a greater extent than sighted to efficiently interact with the environment, and consequently exhibit superior skills in their spared modalities. These performance advantages are often paralleled by responses in the occipital cortex, which have been suggested to be essential for nonvisual processing in the blind. However, it is currently unclear through which pathways (i.e., thalamocortical or corticocortical connections) nonvisual information reaches the occipital cortex of the blind. Here, we used functional magnetic resonance imaging to study blind and matched sighted humans with an auditory discrimination paradigm and used dynamic causal modeling to investigate the effective connectivity underlying auditory activations in the primary visual cortex of blind volunteers. Model comparison revealed that a model connecting the medial geniculate nucleus (MGN), primary auditory cortex (A1), and primary visual cortex (V1) in a bidirectional manner outperformed all other models in both groups. Regarding inference on model parameters, we observed that basic auditory mechanisms (i.e., sensory input to MGN and connections from MGN to A1) did not differ significantly between the two groups. In contrast, we found clear evidence for stronger corticocortical connections from A1 to V1 in the blind, whereas results with regard to thalamocortical enhancement (from MGN to V1 and, in a control analysis, from the lateral geniculate nucleus to V1) were not consistent. These results suggest that plastic changes especially in corticocortical connectivity allow auditory information to evoke responses in the primary visual cortex of blind individuals.

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Section: Figurecontrasting

confidence: 96%

Section: Figurementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Corticocortical Connections Mediate Primary Visual Cortex Responses to Auditory Stimulation in the Blind

Klinge

Eippert²,

Röder³

et al. 2010

J. Neurosci.

133

121

View full text Add to dashboard Cite

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“…Thus the interruption of synaptic elimination by early visual deprivation may prevent the visual cortex from thinning. Plastic changes have been reported in the visual cortex in resting state (Liu et al, 2007) and imaginary, tactile, and auditory tasks (Noppeney, 2007;Cattaneo et al, 2008), and in the early sensory areas of spared modalities following visual deprivation in early life (Bavelier and Neville, 2002). Thus, plasticity may lead to changes in cortical thickness in the early blind.…”

Section: Introductionmentioning

confidence: 99%

Thick Visual Cortex in the Early Blind

Jiang¹,

Zhu²,

Shi³

et al. 2009

J. Neurosci.

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192

158

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We investigated the key neurodevelopmental factors that determine cortical thickness, namely synaptogenesis and regression, by analyzing the thickness of the visual cortex in humans with early-and late-onset blindness. The bilateral visual cortices of the early blind were significantly thicker than those of the late blind and the sighted controls, but the latter two groups did not differ significantly. This suggests reduced "pruning" of synapses in the visual cortex, which may be due to a lack of visual experience during a critical developmental period. These findings support the hypothesis that sensory experience is necessary for an appropriate regression and remodeling of neuronal processes and that synaptic regression might be a major determinant of macroscopic anatomical features like cortical thickness.

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“…While congenitally blind subjects exhibit lower cortical volume in both frontal areas (BA 44, 45) and visual areas (BA 17,18) 48 , compared to a control population, functional connectivity between frontal areas (parts of BA 44, 45, and 47) and occipital areas is stronger in early blind 49 .…”

Section: Visual Activation (And Rems) In Blind Subjectsmentioning

confidence: 92%

Rapid Eye Movements (REMs) and visual dream recall in both congenitally blind and sighted subjects

Bértolo

Mestre

Barrio

et al. 2017

Third International Conference on Applications of Optics and Photonics

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Our objective was to evaluate rapid eye movements (REMs) associated with visual dream recall in sighted subjects and congenital blind. During two consecutive nights polysomnographic recordings were performed at subjects home. REMs were detected by visual inspection on both EOG channels (EOG-H, EOG-V) and further classified as occurring isolated or in bursts. Dream recall was defined by the existence of a dream report. The two groups were compared using t-test and also the two-way ANOVA and a post-hoc Fisher test (for the features diagnosis (blind vs. sighted) and dream recall (yes or no) as a function of time). The average of REM awakenings per subject and the recall ability were identical in both groups. CB had a lower REM density than CS; the same applied to REM bursts and isolated eye movements. In the two-way ANOVA, REM bursts and REM density were significantly different for positive dream recall, mainly for the CB group and for diagnosis; furthermore for both features significant results were obtained for the interaction of time, recall and diagnosis; the interaction of recall and time was however, stronger. In line with previous findings the data show that blind have lower REMs density. However the ability of dream recall in congenitally blind and sighted controls is identical. In both groups visual dream recall is associated with an increase in REM bursts and density. REM bursts also show differences in the temporal profile. REM visual dream recall is associated with increased REMs activity. 3,4,5,6,7,8 . Keywords Dream recallThe study of dreams is closely related to the ability to recall them. There are different methods to study the capacity for dream recall: the morning recall by means of brief questionnaires or dream diaries or the recall after dream interruption. Both methods, if applied to frequent dreamers, revealed consistent results 9,10 . However, this consistency does not occur in infrequent dreamers, for whom the capacity for recall is greater in provoked awakenings 10 . , although it does increase with interest, motivation, moodiness and stress 14. The capacity for dream recall is also slightly higher in women.The content of dream recall varies throughout the night. At the beginning of the night daily residues, related to every day's activity predominate, whereas later in the night hallucinatory or complex character narrative is more frequent 11 . Oneiric dream contentRecall is also positively related to the vivacity, bizarreness and emotional content of dreams, which in turn are influenced by the oneiric visual content 15 .In fact, the richness and continuity of the visual content increases the capacity for spontaneous recall 16 . For these reasons the recall/visual content binomial assumes a particular relevance in the dreams of blind subjects. The works that consider that blind subjects do not have visual dream contents 17 , were contradicted by several studies, namely by one from our group 18 , which demonstrated that blind people do have the ability to draw their own dreams and,...

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Whole brain functional connectivity in the early blind

Cited by 258 publications

References 86 publications

Corticocortical Connections Mediate Primary Visual Cortex Responses to Auditory Stimulation in the Blind

Corticocortical Connections Mediate Primary Visual Cortex Responses to Auditory Stimulation in the Blind

Thick Visual Cortex in the Early Blind

Rapid Eye Movements (REMs) and visual dream recall in both congenitally blind and sighted subjects

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