about
CSF-contacting neurons regulate locomotion by relaying mechanical stimuli to spinal circuits.Optical sectioning deep inside live embryos by selective plane illumination microscopyNeural Circuits Underlying Visually Evoked Escapes in Larval Zebrafish.In vivo validation of a computationally predicted conserved Ath5 target gene setInvestigation of spinal cerebrospinal fluid-contacting neurons expressing PKD2L1: evidence for a conserved system from fish to primatesThe dual developmental origin of spinal cerebrospinal fluid-contacting neurons gives rise to distinct functional subtypesEmergence of patterned activity in the developing zebrafish spinal cordCharacterization of the calcium binding protein family in zebrafishRemote control of neuronal activity with a light-gated glutamate receptor.CRISPR/Cas9-mediated conversion of eGFP- into Gal4-transgenic lines in zebrafish.Filtering of visual information in the tectum by an identified neural circuit.Deletion of a kinesin I motor unmasks a mechanism of homeostatic branching control by neurotrophin-3.State-Dependent Modulation of Locomotion by GABAergic Spinal Sensory Neurons.2C-Cas9: a versatile tool for clonal analysis of gene function.Cell cycle control by homeobox genes in development and disease.Neuronal Ndrg4 Is Essential for Nodes of Ranvier Organization in Zebrafish.Regulation of neurogenesis by interkinetic nuclear migration through an apical-basal notch gradient.Optogenetic localization and genetic perturbation of saccade-generating neurons in zebrafish.Optogenetic dissection of a behavioural module in the vertebrate spinal cord.Highly efficient CRISPR/Cas9-mediated knock-in in zebrafish by homology-independent DNA repair.Optogenetics: a new enlightenment age for zebrafish neurobiology.Let there be light: zebrafish neurobiology and the optogenetic revolution.CRISPR/Cas9 and TALEN-mediated knock-in approaches in zebrafish.Genome editing using CRISPR/Cas9-based knock-in approaches in zebrafish.Homology-Independent Integration of Plasmid DNA into the Zebrafish Genome.Clonal analysis of gene loss of function and tissue-specific gene deletion in zebrafish via CRISPR/Cas9 technology.Mutations affecting retina development in Medaka.Report of the Second European Zebrafish Principal Investigator Meeting in Karlsruhe, Germany, March 21-24, 2012.Differentiation of the vertebrate retina is coordinated by an FGF signaling center.Asymmetric inheritance of the apical domain and self-renewal of retinal ganglion cell progenitors depend on Anillin function.Hydrogen peroxide (H2O2) controls axon pathfinding during zebrafish development.An Attractive Reelin Gradient Establishes Synaptic Lamination in the Vertebrate Visual System.Genetic dissection of the formation of the forebrain in Medaka, Oryzias latipes.A systematic genome-wide screen for mutations affecting organogenesis in Medaka, Oryzias latipes.Angiotropism and extravascular migratory metastasis in cutaneous and uveal melanoma progression in a zebrafish model.Transparent Danionella translucida as a genetically tractable vertebrate brain modelA light-gated potassium channel for sustained neuronal inhibitionPublisher Correction: Transparent Danionella translucida as a genetically tractable vertebrate brain modelLive tracking of inter-organ communication by endogenous exosomes in vivoZebrafish as a Model for the Study of Live Processive Transport in Neurons
P50
Q27325769-81E13A93-E900-4E24-93C8-ED4FFC6292BEQ29619782-CE25DF34-A6CD-4C87-812A-BC79DCBD5A1FQ30364238-0A8F96EA-A85D-447D-93AA-F8A64700A265Q33300135-D1F1B81A-50C3-48EB-BC86-D59B908C4354Q33600510-A426CA45-C37C-41CB-9507-EA5FEA56A505Q33670972-7D0D9A78-6DFA-4759-9BDC-9E104642C392Q34242855-B7BCCE9E-1933-4BA6-A368-24510CFFEB8EQ34558444-E4A03A4B-E63C-471F-9D2A-DCE1A59A981DQ34631094-90D3D03B-BD72-4C0E-B80E-8FD2C48ED11AQ35418660-C28D41E7-F68F-4B4F-A3FC-13CF31C6C3C1Q35626742-195084CD-5B34-4A63-AB9E-6F1CE56BEDF7Q35664198-00934FEE-40A6-4E58-A38B-B7A04AEC2666Q35890373-87467350-F2F9-4EFF-8752-FF3EDD537284Q35950415-7D72A558-695F-4978-B97C-35EAE74B0B92Q36102457-275B89FA-F65A-4794-BE5F-8DB2F05A9608Q36208019-63B7C722-653F-4E85-BD09-6C1F5A4F7FF4Q37066544-E3EFE55A-ABC1-43B7-84C3-52151E52D5DFQ37347600-D08DE4EC-2D24-42DD-BAEE-DDF1BB5338B7Q37405062-0FDBD4D0-0ADB-4787-A18E-A2EEE5C023F3Q37420338-D609662D-593E-459C-9348-59C374A174BFQ37875036-9503B828-1554-42E3-939B-47C45619A770Q37880100-1C7ADA3B-F9F6-47CE-901B-38B4BDB73F29Q38202388-38C0067E-51C0-43A8-AED0-DCBDFC6B2B37Q39181797-C9CA553E-0298-4D10-86B4-93488DFD6896Q39553858-94A7F1F9-F8EA-49FD-ADAE-99A830CA1167Q39574686-800A143F-0341-4A31-B294-D15289F12B80Q44946705-F042872D-B4FA-4464-BE50-72E4D81E00D1Q45416015-D8240EFA-D760-4E68-BC91-4C022BBCEBFCQ46421014-61E27F0B-5087-4964-B35C-E00559820869Q47073222-9A2BB4AE-8694-40E2-82EE-8A0018F12594Q48757570-7D3A9DC3-1040-410F-8187-D96F11F6D6F3Q50074748-F4FD88CD-E2B0-4E69-89AF-5AA3B3832FBFQ52089030-BAADB6D8-8E22-42A2-A00D-5EDB69475D42Q52089032-6A5EE0AB-AC10-4E7B-948B-5F47259E3EF0Q55645366-45D1774A-4328-469E-AA7A-6086E4375D4CQ57464804-3933D821-0E9D-4F20-97E6-49C208FE093CQ58083855-F15BDFAB-0B09-490F-B9F1-7C22D96C70A3Q58611524-296B86F1-D0A9-4DDD-9785-F0CA2E926680Q61917602-6E67AB6A-312D-406A-ABBD-FF570038DB9DQ64228744-CFEA5FE2-7605-472A-85B6-582C8D93BCC6
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Filippo Del Bene
@ast
Filippo Del Bene
@en
Filippo Del Bene
@es
Filippo Del Bene
@nl
type
label
Filippo Del Bene
@ast
Filippo Del Bene
@en
Filippo Del Bene
@es
Filippo Del Bene
@nl
prefLabel
Filippo Del Bene
@ast
Filippo Del Bene
@en
Filippo Del Bene
@es
Filippo Del Bene
@nl
P1053
D-1245-2010
P106
P1153
55957264800
P214
36149542762600301513
P31
P4012
P496
0000-0001-8551-2846
P7859
viaf-36149542762600301513