about
Stem cells in retinal regeneration: past, present and futureIntravitreally Injected Anti-VEGF Antibody Reduces Brown Fat in Neonatal MiceAstrocyte-derived vascular endothelial growth factor stabilizes vessels in the developing retinal vasculatureImproving Mitochondrial Function Protects Bumblebees from Neonicotinoid PesticidesPilot application of iTRAQ to the retinal disease Macular Telangiectasia.Perifoveal müller cell depletion in a case of macular telangiectasia type 2.The Leber congenital amaurosis protein AIPL1 and EB proteins co-localize at the photoreceptor ciliumTreatment with 670 nm light up regulates cytochrome C oxidase expression and reduces inflammation in an age-related macular degeneration model.Patterns of peripheral retinal and central macula ischemia in diabetic retinopathy as evaluated by ultra-widefield fluorescein angiography.Using Stem Cells to Model Diseases of the Outer RetinaA simple method for in vivo labelling of infiltrating leukocytes in the mouse retina using indocyanine green dye.Neuropilin 1 Involvement in Choroidal and Retinal Neovascularisation.Retinal lipid and glucose metabolism dictates angiogenesis through the lipid sensor Ffar1.Basement membrane changes in capillaries of the ageing human retina.Pleiotropic action of CpG-ODN on endothelium and macrophages attenuates angiogenesis through distinct pathways.Mislocalisation of BEST1 in iPSC-derived retinal pigment epithelial cells from a family with autosomal dominant vitreoretinochoroidopathy (ADVIRC)Development of human embryonic stem cell therapies for age-related macular degeneration.Neural retinal regeneration with pluripotent stem cells.Rescue of the MERTK phagocytic defect in a human iPSC disease model using translational read-through inducing drugs.Evaluation of Nonperfused Retinal Vessels in Ischemic Retinopathy.Differential apicobasal VEGF signaling at vascular blood-neural barriers.No evidence for loss of short-wavelength sensitive cone photoreceptors in normal ageing of the primate retina.Expression of neonatal Fc receptor in the eye.Loss of Müller's cells and photoreceptors in macular telangiectasia type 2.Death by color: differential cone loss in the aging mouse retina.Primate retinal cones express phosphorylated tau associated with neuronal degeneration yet survive in old age.FUNDUS-WIDE SUBRETINAL AND PIGMENT EPITHELIAL ABNORMALITIES IN MACULAR TELANGIECTASIA TYPE 2.Assessment of the Complex Refractive Indices of Xenopus Laevis Sciatic Nerve for the Optimisation of Optical (NIR) NeurostimulationThe Effects of Macular Ischemia on Visual Acuity in Diabetic RetinopathyVisualization of gene expression in whole mouse retina by in situ hybridizationQuantification of vascular tortuosity as an early outcome measure in oxygen induced retinopathy (OIR)Corrigendum: Retinal lipid and glucose metabolism dictates angiogenesis through the lipid sensor Ffar1Mitochondrial absorption of short wavelength light drives primate blue retinal cones into glycolysis which may increase their pace of agingFundamental differences in patterns of retinal ageing between primates and mice
P50
Q26828014-0E09E16A-7F6C-46EC-9F96-A2B0E583A9A5Q27301339-66D6EAD8-DBFD-4334-923E-D1401ED27151Q28750081-E2146A69-F9BF-48CB-B108-6A9F7DE7D8D7Q30828987-D73F2E21-F40A-489E-947A-0DEB950749DBQ34078445-BB4D5930-55A3-40F8-9DE1-97D3AC16375CQ34129204-DDFD272F-7F9C-4695-AAEB-9310561E634CQ34468188-142D0777-DFED-4B95-A13F-E8FBFE80CAC8Q34612483-CFE655DF-C143-4316-8D0D-15281F491467Q35141669-EBF0340A-CA4D-4885-B465-1B76269E0761Q35768469-E43C791A-F60D-4050-8823-A2643FBD80A0Q35785469-86AD2ABD-2EE0-4EBC-ACEA-D5FA822BBAEDQ36255703-CF921798-B0B9-40B2-AD94-0DA79F178CA3Q36772416-07C8C0EB-7804-46AC-B7CB-5540823A440FQ36860958-534A46A0-9EF1-46D7-B368-8D4F07B974D4Q37202398-9D1B4236-42E0-4815-B957-879E57946931Q37273988-A22DC809-FB8E-4D2F-AA5C-15F0DA5BDA43Q38100293-FE3946EB-0057-45AB-9AE3-FA5E85B6EB10Q38204639-CFFD66F1-C234-4594-BBFB-036DA992C88BQ38936740-A721F0BE-9FA8-429F-829A-AB56C52EDFD6Q39358202-2A1B39AC-F8A4-4D2D-A86C-6D9674A1C36AQ42030071-46C00631-D8A9-4246-A55D-6D0D82CAFD57Q42291841-BC34F758-17FA-4025-9BCC-D7A5119BD1D9Q42587613-65D0BAA9-B363-44B3-B650-B2A35BAD463AQ44574404-DA308948-7518-4372-B812-17BBE4E09D21Q46879557-E8F1BFF0-C2FA-4DA6-9FD9-5FB1E9E8991CQ46950096-D510F237-6186-4CE9-B3BA-BACAF9B45752Q50089121-36BAD0FF-EE50-492C-9C97-F13B3E1DD2BCQ58116881-29742962-E08F-495C-8BDE-27DF1717A702Q59305531-1638DF7B-87B0-4A69-B449-8D17EC62A455Q84106665-6B1CFB1F-EE8E-4063-B9D3-4A7BAD426DEEQ87087505-8FA60C6F-1065-4E77-8602-4EFFC5BDA6D2Q87606090-D6EB855C-190F-4DB6-A29C-BBE9D37162EAQ92746045-F1ECF1E2-628D-4120-8DF1-3CE96B0EB8CCQ92995559-CDBA669E-01F7-4DF6-8DD0-B84390C7B95A
P50
description
hulumtues
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Michael B. Powner
@ast
Michael B. Powner
@en
Michael B. Powner
@es
Michael B. Powner
@nl
Michael B. Powner
@sl
type
label
Michael B. Powner
@ast
Michael B. Powner
@en
Michael B. Powner
@es
Michael B. Powner
@nl
Michael B. Powner
@sl
prefLabel
Michael B. Powner
@ast
Michael B. Powner
@en
Michael B. Powner
@es
Michael B. Powner
@nl
Michael B. Powner
@sl
P106
P1153
36188607200
P21
P31
P496
0000-0003-4913-1004