Is visual input during critical periods of development crucial for the emergence of the fundamental topographical mapping of the visual cortex? And would this structure be retained throughout life-long blindness or would it fade as a result of plastic, use-based reorganization? We used functional connectivity magnetic resonance imaging based on intrinsic blood oxygen level-dependent fluctuations to investigate whether significant traces of topographical mapping of the visual scene in the form of retinotopic organization, could be found in congenitally blind adults. A group of 11 fully and congenitally blind subjects and 18 sighted controls were studied. The blind demonstrated an intact functional connectivity network structural organization of the three main retinotopic mapping axes: eccentricity (centre-periphery), laterality (left-right), and elevation (upper-lower) throughout the retinotopic cortex extending to high-level ventral and dorsal streams, including characteristic eccentricity biases in face-and houseselective areas. Functional connectivity-based topographic organization in the visual cortex was indistinguishable from the normally sighted retinotopic functional connectivity structure as indicated by clustering analysis, and was found even in participants who did not have a typical retinal development in utero (microphthalmics). While the internal structural organization of the visual cortex was strikingly similar, the blind exhibited profound differences in functional connectivity to other (non-visual) brain regions as compared to the sighted, which were specific to portions of V1. Central V1 was more connected to language areas but peripheral V1 to spatial attention and control networks. These findings suggest that current accounts of critical periods and experiencedependent development should be revisited even for primary sensory areas, in that the connectivity basis for visual cortex largescale topographical organization can develop without any visual experience and be retained through life-long experience-dependent plasticity. Furthermore, retinotopic divisions of labour, such as that between the visual cortex regions normally representing the fovea and periphery, also form the basis for topographically-unique plastic changes in the blind.
|Number of pages||17|
|State||Published - 1 Jun 2015|
Bibliographical noteFunding Information:
This work was supported by a European Research Council grant (grant number 310809; A.A.), The Gatsby Charitable Foundation (A.A.), The James S. McDonnell Foundation scholar award (grant number 220020284; A.A.), The Israel Science Foundation (grant number ISF 1684/08; A.A.), The Edmond and Lily Safra Center for Brain Sciences (ELSC) Vision center grant (A.A.), the support of the Maratier family (A.A.), and the German Excellence Initiative Grant to the Berlin School of Mind and Brain (A.V.). None of the authors of this work has a financial interest related to this work.
© The Author (2015). Published by Oxford University Press on behalf of the Guarantors of Brain.
ASJC Scopus subject areas
- Clinical Neurology