Catching the voltage gradient—asymmetric boost of cortical spread generates motion signals across visual cortex: a brief review with special thanks to Amiram Grinvald

Jancke, Dirk

doi:10.1117/1.nph.4.3.031206

Cited by 4 publications

(1 citation statement)

References 128 publications

(135 reference statements)

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“…Recording the population response of the visual cortex is of great importance for studying basic visual processing, plasticity processes, and various pathologies. Of particular interest to this study is the generation of retinotopic maps, which can shed light on many retina-visual cortex processes, as well as plasticity, and circuitry [1][2][3][4]. Various techniques are available, enabling the investigation of the cortical population response; one such technique is Voltage-sensitive dye imaging (VSDI).…”

Section: Introductionmentioning

confidence: 99%

High-resolution VSDI retinotopic mapping via a DLP-based projection system

Gross¹,

Ivzan²,

Farah³

et al. 2019

Biomed. Opt. Express

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High-resolution recording of visual cortex activity is an important tool for vision research. Using a customized digital mirror device (DMD)-based system equipped with retinal imaging, we projected visual stimuli directly on the rat retina and recorded cortical responses by voltage-sensitive dye imaging. We obtained robust cortical responses and generated high-resolution retinotopic maps at an unprecedented retinal resolution of 4.6 degrees in the field of view, while further distinguishing between normal and pathological retinal areas. This system is a useful tool for studying the cortical response to localized retinal stimulation and may shed light on various cortical plasticity processes.

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Section: Introductionmentioning

confidence: 99%

High-resolution VSDI retinotopic mapping via a DLP-based projection system

Gross¹,

Ivzan²,

Farah³

et al. 2019

Biomed. Opt. Express

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Induction of excitatory brain state governs plastic functional changes in visual cortical topology

Eysel,

Jancke

2023

Brain Struct Funct

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Adult visual plasticity underlying local remodeling of the cortical circuitry in vivo appears to be associated with a spatiotemporal pattern of strongly increased spontaneous and evoked activity of populations of cells. Here we review and discuss pioneering work by us and others about principles of plasticity in the adult visual cortex, starting with our study which showed that a confined lesion in the cat retina causes increased excitability in the affected region in the primary visual cortex accompanied by fine-tuned restructuring of neuronal function. The underlying remodeling processes was further visualized with voltage-sensitive dye (VSD) imaging that allowed a direct tracking of retinal lesion-induced reorganization across horizontal cortical circuitries. Nowadays, application of noninvasive stimulation methods pursues the idea further of increased cortical excitability along with decreased inhibition as key factors for the induction of adult cortical plasticity. We used high-frequency transcranial magnetic stimulation (TMS), for the first time in combination with VSD optical imaging, and provided evidence that TMS-amplified excitability across large pools of neurons forms the basis for noninvasively targeting reorganization of orientation maps in the visual cortex. Our review has been compiled on the basis of these four own studies, which we discuss in the context of historical developments in the field of visual cortical plasticity and the current state of the literature. Overall, we suggest markers of LTP-like cortical changes at mesoscopic population level as a main driving force for the induction of visual plasticity in the adult. Elevations in excitability that predispose towards cortical plasticity are most likely a common property of all cortical modalities. Thus, interventions that increase cortical excitability are a promising starting point to drive perceptual and potentially motor learning in therapeutic applications.

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Optical Imaging With Voltage Sensors—Capturing TMS-Induced Neuronal Signals Using Light

Jancke

2018

Handbook of Behavioral Neuroscience

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Catching the voltage gradient—asymmetric boost of cortical spread generates motion signals across visual cortex: a brief review with special thanks to Amiram Grinvald

Cited by 4 publications

References 128 publications

High-resolution VSDI retinotopic mapping via a DLP-based projection system

High-resolution VSDI retinotopic mapping via a DLP-based projection system

Induction of excitatory brain state governs plastic functional changes in visual cortical topology

Optical Imaging With Voltage Sensors—Capturing TMS-Induced Neuronal Signals Using Light

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