| scholarly article | Q13442814 |
| P50 | author | Michael P. Stryker | Q38326883 |
| P2093 | author name string | David A Feldheim | |
| Jianhua Cang | |||
| Jena Yamada | |||
| Megumi Kaneko | |||
| Georgia Woods | |||
| P2860 | cites work | RETINAL WAVES AND VISUAL SYSTEM DEVELOPMENT | Q22337029 |
| Molecular regionalization of the neocortex is disrupted in Fgf8 hypomorphic mutants | Q28184215 | ||
| Neocortex patterning by the secreted signaling molecule FGF8 | Q28188453 | ||
| Multiple roles of EPH receptors and ephrins in neural development | Q28205325 | ||
| Generating the cerebral cortical area map | Q28207236 | ||
| The ephrins and Eph receptors in neural development | Q28266706 | ||
| Specification of cerebral cortical areas | Q28295048 | ||
| Distinct actions of Emx1, Emx2, and Pax6 in regulating the specification of areas in the developing neocortex | Q28587131 | ||
| Topographic guidance labels in a sensory projection to the forebrain | Q28589074 | ||
| Opposing gradients of ephrin-As and EphA7 in the superior colliculus are essential for topographic mapping in the mammalian visual system | Q28591937 | ||
| EMX2 regulates sizes and positioning of the primary sensory and motor areas in neocortex by direct specification of cortical progenitors | Q28594829 | ||
| Ephrin-As and neural activity are required for eye-specific patterning during retinogeniculate mapping | Q28768597 | ||
| Independent parcellation of the embryonic visual cortex and thalamus revealed by combinatorial Eph/ephrin gene expression | Q31882279 | ||
| Regulation of area identity in the mammalian neocortex by Emx2 and Pax6. | Q33898094 | ||
| Development and plasticity of cortical areas and networks | Q34205588 | ||
| Do cortical areas emerge from a protocortex? | Q34418564 | ||
| Axonal ephrin-As and odorant receptors: coordinate determination of the olfactory sensory map. | Q34536164 | ||
| Regulation of axial patterning of the retina and its topographic mapping in the brain. | Q35068992 | ||
| COUP-TFI: an intrinsic factor for early regionalization of the neocortex | Q35080812 | ||
| Thalamocortical development: how are we going to get there? | Q35097313 | ||
| Multiple roles of ephrins during the formation of thalamocortical projections: maps and more | Q35685283 | ||
| Developmental mechanisms patterning thalamocortical projections: intrinsic, extrinsic and in between. | Q35818619 | ||
| Intermediate targets in formation of topographic projections: inputs from the thalamocortical system. | Q35872310 | ||
| Mechanisms of retinotopic map development: Ephs, ephrins, and spontaneous correlated retinal activity | Q35974447 | ||
| Regulation of thalamic neurite outgrowth by the Eph ligand ephrin-A5: implications in the development of thalamocortical projections | Q36069998 | ||
| Organized growth of thalamocortical axons from the deep tier of terminations into layer IV of developing mouse barrel cortex | Q36757305 | ||
| Retinal axon response to ephrin-as shows a graded, concentration-dependent transition from growth promotion to inhibition | Q40548457 | ||
| A mapping label required for normal scale of body representation in the cortex | Q40892578 | ||
| Regional differences in the developing cerebral cortex revealed by ephrin-A5 expression | Q41692176 | ||
| Malformation of the functional organization of somatosensory cortex in adult ephrin-A5 knock-out mice revealed by in vivo functional imaging. | Q41749789 | ||
| Topographic mapping from the retina to the midbrain is controlled by relative but not absolute levels of EphA receptor signaling | Q41752889 | ||
| EphA family gene expression in the developing mouse neocortex: regional patterns reveal intrinsic programs and extrinsic influence | Q44278554 | ||
| Neuronal birthdate-specific gene transfer with adenoviral vectors. | Q44723219 | ||
| Loss-of-function analysis of EphA receptors in retinotectal mapping. | Q44795517 | ||
| Topological precision in the thalamic projection to neonatal mouse barrel cortex | Q46342440 | ||
| New paradigm for optical imaging: temporally encoded maps of intrinsic signal | Q46547489 | ||
| Molecular gradients and compartments in the embryonic primate cerebral cortex | Q48105727 | ||
| Molecular evidence for the early specification of presumptive functional domains in the embryonic primate cerebral cortex. | Q48162701 | ||
| Area specificity and topography of thalamocortical projections are controlled by ephrin/Eph genes | Q48236950 | ||
| Emx2 patterns the neocortex by regulating FGF positional signaling | Q48249587 | ||
| Mechanisms underlying the early establishment of thalamocortical connections in the rat. | Q48427034 | ||
| Miswiring of limbic thalamocortical projections in the absence of ephrin-A5. | Q48453252 | ||
| Ephrin-A5 (AL-1/RAGS) is essential for proper retinal axon guidance and topographic mapping in the mammalian visual system | Q48517864 | ||
| Fibroblast growth factor 8 regulates neocortical guidance of area-specific thalamic innervation. | Q48805356 | ||
| Efficient in utero gene transfer system to the developing mouse brain using electroporation: visualization of neuronal migration in the developing cortex | Q48919857 | ||
| Genetic analysis of ephrin-A2 and ephrin-A5 shows their requirement in multiple aspects of retinocollicular mapping. | Q52169064 | ||
| Alkaline phosphatase fusions of ligands or receptors as in situ probes for staining of cells, tissues, and embryos | Q73110146 | ||
| Neuronal circuits are subdivided by differential expression of type-II classic cadherins in postnatal mouse brains | Q73854397 | ||
| Efficient gene transfer into the embryonic mouse brain using in vivo electroporation | Q77469506 | ||
| P433 | issue | 4 | |
| P407 | language of work or name | English | Q1860 |
| P304 | page(s) | 577-589 | |
| P577 | publication date | 2005-11-01 | |
| P1433 | published in | Neuron | Q3338676 |
| P1476 | title | Ephrin-as guide the formation of functional maps in the visual cortex | |
| P478 | volume | 48 |
| Q35117407 | A lifespan analysis of intraneocortical connections and gene expression in the mouse II |
| Q37714181 | A molecular mechanism for the topographic alignment of convergent neural maps. |
| Q36170813 | A role for ephrin-A5 in axonal sprouting, recovery, and activity-dependent plasticity after stroke |
| Q37380092 | A sharp cadherin-6 gene expression boundary in the developing mouse cortical plate demarcates the future functional areal border |
| Q48477874 | A unifying model for activity-dependent and activity-independent mechanisms predicts complete structure of topographic maps in ephrin-A deficient mice |
| Q37219918 | Accelerated experience-dependent pruning of cortical synapses in ephrin-A2 knockout mice |
| Q37577454 | Activity-dependent modulation of neural circuit synaptic connectivity |
| Q38673142 | Associating transcription factors and conserved RNA structures with gene regulation in the human brain. |
| Q45980717 | Auditory brainstem neural activation patterns are altered in EphA4- and ephrin-B2-deficient mice. |
| Q35945770 | Bilateral enucleation alters gene expression and intraneocortical connections in the mouse |
| Q28573764 | Changes in growth factor expression in normal aging of the rat retina |
| Q52584003 | Close homolog of L1 and neuropilin 1 mediate guidance of thalamocortical axons at the ventral telencephalon. |
| Q35571306 | Competition is a driving force in topographic mapping |
| Q38030191 | Development and plasticity of the primary visual cortex |
| Q42144918 | Development of precise maps in visual cortex requires patterned spontaneous activity in the retina |
| Q37678850 | Different roles of axon guidance cues and patterned spontaneous activity in establishing receptive fields in the mouse superior colliculus. |
| Q28585295 | Differential gene expression between sensory neocortical areas: potential roles for Ten_m3 and Bcl6 in patterning visual and somatosensory pathways |
| Q92647900 | Dynamic Alterations of Retinal EphA5 Expression in Retinocollicular Map Plasticity |
| Q48375524 | Enduring critical period plasticity visualized by transcranial flavoprotein imaging in mouse primary visual cortex. |
| Q24629758 | Eph and ephrin signaling in the formation of topographic maps |
| Q89963849 | Eph/ephrin Function Contributes to the Patterning of Spinocerebellar Mossy Fibers Into Parasagittal Zones |
| Q30440725 | EphA signaling impacts development of topographic connectivity in auditory corticofugal systems |
| Q54369986 | EphA4 is associated with multiple cell types in the marmoset primary visual cortex throughout the lifespan. |
| Q46779394 | EphA4 misexpression alters tonotopic projections in the auditory brainstem. |
| Q43130537 | Ephrin-A2 and ephrin-A5 guide contralateral targeting but not topographic mapping of ventral cochlear nucleus axons |
| Q33631928 | Ephrin-A5 regulates the formation of the ascending midbrain dopaminergic pathways |
| Q36877352 | Ephrin-As and patterned retinal activity act together in the development of topographic maps in the primary visual system |
| Q24622218 | Ephrin-B2 elicits differential growth cone collapse and axon retraction in retinal ganglion cells from distinct retinal regions |
| Q51873917 | Ephrin/ephrin receptor expression during early stages of mouse inner ear development. |
| Q33582731 | Experience-dependent and independent binocular correspondence of receptive field subregions in mouse visual cortex |
| Q46479964 | Functional topography and integration of the contralateral and ipsilateral retinocollicular projections of ephrin-A-/- mice. |
| Q52585765 | GAP-43 is critical for normal targeting of thalamocortical and corticothalamic, but not trigeminothalamic axons in the whisker barrel system. |
| Q37467785 | Gradients of Eph-A6 expression in primate retina suggest roles in both vascular and axon guidance |
| Q37350500 | Grading the thalamus: how can an 'Eph' be excellent? |
| Q36858519 | Heparan sulfate regulates ephrin-A3/EphA receptor signaling |
| Q48437621 | High-performance and site-directed in utero electroporation by a triple-electrode probe |
| Q30498204 | Highly selective receptive fields in mouse visual cortex |
| Q35709366 | Homeostatic plasticity mechanisms are required for juvenile, but not adult, ocular dominance plasticity |
| Q57020987 | In vivo methods for acute modulation of gene expression in the central nervous system |
| Q30494626 | Integration of neuronal clones in the radial cortical columns by EphA and ephrin-A signalling |
| Q48171804 | Interplay between laminar specificity and activity-dependent mechanisms of thalamocortical axon branching |
| Q34488140 | L1 and CHL1 Cooperate in Thalamocortical Axon Targeting |
| Q35618995 | Laminar expression of ephrin-A2 in primary somatosensory cortex of postnatal rats |
| Q38671212 | Learning to see again: biological constraints on cortical plasticity and the implications for sight restoration technologies. |
| Q52593134 | Low-intensity repetitive transcranial magnetic stimulation requires concurrent visual system activity to modulate visual evoked potentials in adult mice. |
| Q24658038 | Mechanisms underlying development of visual maps and receptive fields |
| Q37266839 | Natural scene statistics and the structure of orientation maps in the visual cortex. |
| Q100389560 | New insights on the modeling of the molecular mechanisms underlying neural maps alignment in the midbrain |
| Q34568049 | NrCAM deletion causes topographic mistargeting of thalamocortical axons to the visual cortex and disrupts visual acuity |
| Q30473649 | Null mutations in EphB receptors decrease sharpness of frequency tuning in primary auditory cortex |
| Q49724156 | Online LI-rTMS during a Visual Learning Task: Differential Impacts on Visual Circuit and Behavioral Plasticity in Adult Ephrin-A2A5-/- Mice |
| Q39114367 | Origins of strabismus and loss of binocular vision |
| Q37339004 | Parcellation of the thalamus into distinct nuclei reflects EphA expression and function |
| Q49160832 | Primary visual cortex projections to extrastriate cortices in enucleated and anophthalmic mice |
| Q35801848 | Rapid Changes in Cortical and Subcortical Brain Regions after Early Bilateral Enucleation in the Mouse |
| Q30492947 | Retinal input instructs alignment of visual topographic maps |
| Q36438044 | Role of EphA/ephrin--a signaling in the development of topographic maps in mouse corticothalamic projections |
| Q37408292 | Role of interstitial branching in the development of visual corticocortical connections: a time-lapse and fixed-tissue analysis |
| Q37636604 | Role of retinal input on the development of striate-extrastriate patterns of connections in the rat |
| Q36986494 | Roles of ephrin-as and structured activity in the development of functional maps in the superior colliculus |
| Q37784308 | Roles of heparan sulfate in mammalian brain development current views based on the findings from Ext1 conditional knockout studies |
| Q30482219 | Selective disruption of one Cartesian axis of cortical maps and receptive fields by deficiency in ephrin-As and structured activity |
| Q28263026 | Should I stay or should I go? Ephs and ephrins in neuronal migration |
| Q47833280 | Spatial Frequency Selectivity Is Impaired in Dopamine D2 Receptor Knockout Mice |
| Q35821146 | Spatiotemporal dynamics of the postnatal developing primate brain transcriptome |
| Q37301626 | Specificity and sufficiency of EphB1 in driving the ipsilateral retinal projection |
| Q34574563 | Spontaneous retinal activity mediates development of ocular dominance columns and binocular receptive fields in v1 |
| Q36094421 | Stochastic Interaction between Neural Activity and Molecular Cues in the Formation of Topographic Maps |
| Q48246545 | Targeted in vivo genetic manipulation of the mouse or rat brain by in utero electroporation with a triple-electrode probe. |
| Q27334204 | Ten_m3 regulates eye-specific patterning in the mammalian visual pathway and is required for binocular vision |
| Q56960831 | Thalamocortical Circuits and Functional Architecture |
| Q39431443 | The Impact of Ecological Niche on Adaptive Flexibility of Sensory Circuitry |
| Q50296161 | The Mouse Superior Colliculus: An Emerging Model for Studying Circuit Formation and Function |
| Q28073395 | The Wiring of Developing Sensory Circuits-From Patterned Spontaneous Activity to Synaptic Plasticity Mechanisms |
| Q34071756 | The developmental remodeling of eye-specific afferents in the ferret dorsal lateral geniculate nucleus |
| Q42383711 | The effects of lifelong blindness on murine neuroanatomy and gene expression |
| Q48481641 | The influence of electro-acupuncture on neural plasticity in acute cerebral infarction |
| Q43123035 | The mapping of eccentricity and meridional angle onto orthogonal axes in the primary visual cortex: an activity-dependent developmental model |
| Q38170465 | The molecular basis for the development of neural maps |
| Q33549691 | The refinement of ipsilateral eye retinotopic maps is increased by removing the dominant contralateral eye in adult mice |
| Q42083386 | Topography of striate-extrastriate connections in neonatally enucleated rats |
| Q36700646 | TrkB kinase is required for recovery, but not loss, of cortical responses following monocular deprivation |
| Q41011574 | Tumor necrosis factor-alpha mediates one component of competitive, experience-dependent plasticity in developing visual cortex |
| Q37781094 | Unravelling the development of the visual cortex: implications for plasticity and repair |
| Q37794523 | Visual Map Development: Bidirectional Signaling, Bifunctional Guidance Molecules, and Competition |
| Q54959907 | Visual Maps Development: Reconsidering the Role of Retinal Efnas and Basic Principle of Map Alignment. |
| Q48459201 | Visual capabilities and cortical maps in BALB/c mice. |
| Q34287671 | Visual cortex modulates the magnitude but not the selectivity of looming-evoked responses in the superior colliculus of awake mice |
| Q30499411 | Visual receptive field properties of neurons in the superficial superior colliculus of the mouse |
| Q91657426 | Wiring the Binocular Visual Pathways |
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