Carlsbad / Osaka / Cork / Neuroreport / Pittsburgh / Shizuoka-ken / San Jose / Santa Cruz / Vaquero / Pleasanton / Orlando / Burlingame / Newton / Boston / Vaudreuil / Oberkochen / Indorf / /
Company
Carl Zeiss Inc. / Boston Micromachines Corporation / Cambridge University Press / Vector Laboratories / Adobe Systems Inc. / Clarity Medical Systems Inc. / Donnelly / 4Optos plc / Shroff SA / Bayer / Adobe / Burns SA / Optos / Thorlabs Inc. / Unicon Corporation / /
Country
Japan / Canada / United Kingdom / Scotland / Germany / United States / Ireland / / /
Event
Natural Disaster / /
Facility
University of Houston / University of California at Berkeley / Laser Institute of America / Scale bar / University of California / University Committee / University of Rochester / Meliora Hall / /
IndustryTerm
in vivo cellular imaging / deviation image processing technique / subsequent imaging / vivo autofluorescence imaging / optics imaging / deviation image processing / retinal imaging experiments / high resolution retinal imaging / In vivo imaging resolution / twophoton imaging / in vivo imaging sessions / retinal imaging / fAOSLO imaging / ophthalmic devices / fluorescence imaging / imaging / Slit lamp imaging / High resolution imaging / confocal imaging / adaptive optics imaging / In vivo imaging / faster solution / digital imaging camera / in vivo imaging techniques / maximum achievable imaging field size / reflectance imaging / In vivo fluorescent imaging / similar imaging method / In vivo confocal imaging / vivo imaging / high-resolution fAOSLO imaging / ganglion cell imaging / In vivo time-lapse fluorescence imaging / high-resolution fluorescence imaging / Real-time imaging / distinguished using adaptive optics imaging / In vivo fluorescence imaging / cellular and subcellular imaging / maximum imaging field sizes / scanner control electronics / capillary network / in vivo imaging parameters / typical devices / in vivo fAOSLO imaging / images using graphics editing software / /
MedicalCondition
myopia / individual retinal ganglion / rhodamine-labeled macaque retinal ganglion / individual ganglion / JE / studies using rodent disease / refractive errors / rat retinal ganglion / Progressive ganglion / larger average refractive errors / also imaged ganglion / Large ganglion / stroke / To image ganglion / ganglion / fluorescently labeled ganglion / retinal ganglion cells / DBA/2J glaucoma / large refractive error / Power (D) Average Refractive Error / refractive error / ocular hypertension / astigmatism / glaucoma / Caprioli J. Retinal ganglion / murine retinal ganglion / Foundation Fighting Blindness / herpes / stroke MEMS / experimental glaucoma / retinal ganglion / single ganglion / large hyperopic refractive error / disease / infectious titer / human retinal degeneration / retinal disease / eGFP-labeled ganglion / primate retinal ganglion / neurodegenerative diseases / cataract / human disease / /
MedicalTreatment
gene therapy / drug therapies / /
Organization
Cambridge University / University of California / Laser Institute of America / Center for Adaptive Optics / Association for Research / Optical Society of America / University of Rochester / Rochester / National Science Foundation / University of Houston / Houston / Burroughs Welcome Fund / University Committee on Animal Resources / /
Person
Ying Geng / Rowland M. Prevalence / Richard T. Libby / Lana Nagy / None / Gene Ther / Alfredo Dubra / Mu ¨ller / Benjamin Masella / Marcos S. Optical / Andrew Winterborn / Lu Yin / Stephen Burns / Joseph Stamm / Terry Schaefer / William H. Merigan / Wendy Bates / Arch Ophthalmol / Mina Chung / Wayne Rasband / / /
Position
RT / Corresponding author / Hunter / animal model for human retinal degeneration / J.J. Hunter / /
Product
soma / DV / tropicamide / isoflurane / RGCs Intravitreal injections / indocyanine green / /
In Vivo Imaging of Microscopic Structures in the Rat Retina Ying Geng,1,2 Kenneth P. Greenberg,3 Robert Wolfe,1 Daniel C. Gray,4 Jennifer J. Hunter,1 Alfredo Dubra,1 John G. Flannery,3 David R. Williams,1 and Jason Porte