Monocular deprivation reduces reliability of visual cortical responses to binocular disparity stimuli

Monocular deprivation (MD) of vision during early postnatal life induces amblyopia, and most neurons in the primary visual cortex lose their responses to the closed eye. Anatomically, the somata of neurons in the closed-eye recipient layer of the lateral geniculate nucleus (LGN) shrink and their axons projecting to the visual cortex retract. Although it has been difficult to restore visual acuity after maturation, recent studies in rodents and cats showed that a period of exposure to complete darkness could promote recovery from amblyopia induced by prior MD. However, in cats, which have an organization of central visual pathways similar to humans, the effect of dark rearing only improves monocular vision and does not restore binocular depth perception. To determine whether dark rearing can completely restore the visual pathway, we examined its effect on the three major concomitants of MD in individual visual neurons, eye preference of visual cortical neurons and soma size and axon morphology of LGN neurons. Dark rearing improved the recovery of visual cortical responses to the closed eye compared with the recovery under binocular conditions. However, geniculocortical axons serving the closed eye remained retracted after dark rearing, whereas reopening the closed eye restored the soma size of LGN neurons. These results indicate that dark rearing incompletely restores the visual pathway, and thus exerts a limited restorative effect on visual function.

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Visual Cortical Recovery From Reverse Occlusion Depends on Concordant Binocular Experience

Journal of Neurophysiology ◽

10.1152/jn.00912.2005 ◽

2006 ◽

Vol 95 (3) ◽

pp. 1718-1726 ◽

Cited By ~ 8

Author(s):

Stuart D. Faulkner ◽

Vasily Vorobyov ◽

Frank Sengpiel

Keyword(s):

Binocular Vision ◽

Monocular Deprivation ◽

Competitive Interactions ◽

Orientation Tuning ◽

Physiological Changes ◽

Single Cell Recording ◽

Intrinsic Signals ◽

Cortical Responses ◽

Cell Recording ◽

Visual Cortical

The effects of early monocular deprivation on visual acuity and visual cortical responses can be reversed quickly if vision is restored to the deprived eye and the other eye is deprived instead, a procedure known as reverse occlusion. However, recovery of vision through the originally deprived eye (ODE) is not stable. Following re-opening of the recently deprived (originally nondeprived) eye (ONDE), vision in the ODE typically deteriorates rapidly, possibly because of competitive interactions, whereas vision in the ONDE also remains compromised, resulting in bilateral amblyopia, the reasons for which are unknown. Here we monitor the physiological changes in the visual cortex during recovery from reverse occlusion in a longitudinal study, using optical imaging of intrinsic signals and single-cell recording in anesthetized cats. We show that a brief period of just 4 days of concordant binocular vision intercalated between the two periods of monocular experience allows close to equal responses to develop through both eyes, both in terms of cortical territory and orientation selectivity. In contrast, with no binocular vision or discordant binocular experience, cortical territory dominated by the ONDE is significantly reduced, and orientation tuning of cells dominated by the ODE is wider than that of cells dominated by the ONDE. These results support the notion that a brief period of binocular vision is sufficient to prevent bilateral acuity loss caused by reverse occlusion.

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Reticular facilitation of cat visual cortical responses is mediated by nicotinic and muscarinic cholinergic mechanisms

Experimental Brain Research ◽

10.1007/bf00230433 ◽

1993 ◽

Vol 96 (1) ◽

pp. 1-7 ◽

Cited By ~ 19

Author(s):

M. H. Lewandowski ◽

C. M. Müller ◽

W. Singer

Keyword(s):

Cholinergic Mechanisms ◽

Cortical Responses ◽

Muscarinic Cholinergic ◽

Visual Cortical

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Context-Dependent Modulation of Early Visual Cortical Responses to Numerical and Nonnumerical Magnitudes

Journal of Cognitive Neuroscience ◽

10.1162/jocn_a_01774 ◽

2021 ◽

pp. 1-12

Author(s):

Joonkoo Park ◽

Sonia Godbole ◽

Marty G. Woldorff ◽

Elizabeth M. Brannon

Keyword(s):

Visual Processing ◽

Context Dependency ◽

Numerical Magnitude ◽

Continuous Variables ◽

Processing Stream ◽

Cortical Responses ◽

Early Visual Cortex ◽

Context Dependent ◽

Visual Cortical ◽

The Brain

Abstract Whether and how the brain encodes discrete numerical magnitude differently from continuous nonnumerical magnitude is hotly debated. In a previous set of studies, we orthogonally varied numerical (numerosity) and nonnumerical (size and spacing) dimensions of dot arrays and demonstrated a strong modulation of early visual evoked potentials (VEPs) by numerosity and not by nonnumerical dimensions. Although very little is known about the brain's response to systematic changes in continuous dimensions of a dot array, some authors intuit that the visual processing stream must be more sensitive to continuous magnitude information than to numerosity. To address this possibility, we measured VEPs of participants viewing dot arrays that changed exclusively in one nonnumerical magnitude dimension at a time (size or spacing) while holding numerosity constant and compared this to a condition where numerosity was changed while holding size and spacing constant. We found reliable but small neural sensitivity to exclusive changes in size and spacing; however, changing numerosity elicited a much more robust modulation of the VEPs. Together with previous work, these findings suggest that sensitivity to magnitude dimensions in early visual cortex is context dependent: The brain is moderately sensitive to changes in size and spacing when numerosity is held constant, but sensitivity to these continuous variables diminishes to a negligible level when numerosity is allowed to vary at the same time. Neurophysiological explanations for the encoding and context dependency of numerical and nonnumerical magnitudes are proposed within the framework of neuronal normalization.

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Early visual cortical responses produced by checkerboard pattern stimulation

NeuroImage ◽

10.1016/j.neuroimage.2016.03.078 ◽

2016 ◽

Vol 134 ◽

pp. 532-539 ◽

Cited By ~ 9

Author(s):

Yoshihito Shigihara ◽

Hideyuki Hoshi ◽

Semir Zeki

Keyword(s):

Checkerboard Pattern ◽

Cortical Responses ◽

Pattern Stimulation ◽

Visual Cortical

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Critical periods in amblyopia

Visual Neuroscience ◽

10.1017/s0952523817000219 ◽

2018 ◽

Vol 35 ◽

Cited By ~ 47

Author(s):

TAKAO K. HENSCH ◽

ELIZABETH M. QUINLAN

Keyword(s):

Visual Cortex ◽

Critical Period ◽

Molecular Mechanisms ◽

Ocular Dominance ◽

Molecular Genetic ◽

Monocular Deprivation ◽

Critical Periods ◽

Developmental Constraints ◽

Early Postnatal Development ◽

Visual Cortical

AbstractThe shift in ocular dominance (OD) of binocular neurons induced by monocular deprivation is the canonical model of synaptic plasticity confined to a postnatal critical period. Developmental constraints on this plasticity not only lend stability to the mature visual cortical circuitry but also impede the ability to recover from amblyopia beyond an early window. Advances with mouse models utilizing the power of molecular, genetic, and imaging tools are beginning to unravel the circuit, cellular, and molecular mechanisms controlling the onset and closure of the critical periods of plasticity in the primary visual cortex (V1). Emerging evidence suggests that mechanisms enabling plasticity in juveniles are not simply lost with age but rather that plasticity is actively constrained by the developmental up-regulation of molecular ‘brakes’. Lifting these brakes enhances plasticity in the adult visual cortex, and can be harnessed to promote recovery from amblyopia. The reactivation of plasticity by experimental manipulations has revised the idea that robust OD plasticity is limited to early postnatal development. Here, we discuss recent insights into the neurobiology of the initiation and termination of critical periods and how our increasingly mechanistic understanding of these processes can be leveraged toward improved clinical treatment of adult amblyopia.

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Suprachoroidal electrical stimulation: effects of stimulus pulse parameters on visual cortical responses

Journal of Neural Engineering ◽

10.1088/1741-2560/10/5/056011 ◽

2013 ◽

Vol 10 (5) ◽

pp. 056011 ◽

Cited By ~ 12

Author(s):

Sam E John ◽

Mohit N Shivdasani ◽

Chris E Williams ◽

John W Morley ◽

Robert K Shepherd ◽

...

Keyword(s):

Electrical Stimulation ◽

Stimulus Pulse ◽

Pulse Parameters ◽

Cortical Responses ◽

Visual Cortical

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An examination of linking hypotheses drawn from the perceptual consequences of experimentally induced changes in neural circuitry

Visual Neuroscience ◽

10.1017/s095252381300028x ◽

2013 ◽

Vol 30 (5-6) ◽

pp. 271-276 ◽

Cited By ~ 1

Author(s):

DONALD E. MITCHELL ◽

STEPHEN G. LOMBER

Keyword(s):

Striate Cortex ◽

Extended Period ◽

Monocular Deprivation ◽

Specific Cell ◽

Cortical Areas ◽

Good Spatial Resolution ◽

Areas 17 And 18 ◽

Visual Cortical ◽

Areas Of Interest ◽

Induced Changes

AbstractBecause targeted early experiential manipulations alter both perception and the response properties of particular cells in the striate cortex, they have been used as evidence for linking hypotheses between the two. However, such hypotheses assume that the effects of the early biased visual input are restricted to just the specific cell population and/or visual areas of interest and that the neural populations that contribute to the visual perception itself do not change. To examine this assumption, we measured the consequences for vision of an extended period of early monocular deprivation (MD) on a kitten (from 19 to 219 days of age) that began well before, and extended beyond, bilateral ablation of visual cortical areas 17 and 18 at 132 days of age. In agreement with previous work, the lesion reduced visual acuity by only a factor of two indicating that the neural sites, other than cortical areas 17 and 18, that support vision in their absence have good spatial resolution. However, these sites appear to be affected profoundly by MD as the effects on vision were just as severe as those observed following MD imposed on normal animals. The pervasive effects of selected early visual deprivation across many cortical areas reported here and elsewhere, together with the potential for perception to be mediated at a different neural site following deprivation than after typical rearing, points to a need for caution in the use of data from early experiential manipulations for formulation of linking hypotheses.

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