PURPOSE: Aberrant growth of blood vessels in the eye is a major cause of vision loss, occurring as a complication of diabetic retinopathy, age-related macular degeneration, and retinal vascular occlusions, among others. Whereas in humans, in vivo angiography is routinely used to image such diseases, many animal models of ocular vascular disease and development rely on dissected tissues that may not accurately represent in vivo conditions and require enucleation of the eye, the death of the animal, or both. METHODS: A method of three-dimensional imaging of blood vessels was used in the living mouse eye that involved scanning laser confocal microscopy and computer-aided image reconstruction. RESULTS: This minimally invasive technique was used to collect three-dimensional images of intraocular vessels in vivo during development. The retinal and choroidal vasculature was studied during development and disease, in models of retinal degeneration, central retinal vein occlusion, and oxygen-induced retinopathy. To aid in investigations into cell-based therapies for retinal disease, two-color imaging was used to localize transplanted cells in relation to the vasculature. This technique was used to perform serial imaging of the ocular vasculature over time, when developmental regression of vessels was observed. CONCLUSIONS: This in vivo vascular imaging approach is valuable in monitoring normal development, disease progression, and efficacy of experimental treatments in mouse models of ocular vascular disease and may have broader applications to the field of angiogenesis by using the readily visualized ocular vascular bed as a surrogate to test pro- and antiangiogenic compounds.
PURPOSE: Aberrant growth of blood vessels in the eye is a major cause of vision loss, occurring as a complication of diabetic retinopathy, age-related macular degeneration, and retinal vascular occlusions, among others. Whereas in humans, in vivo angiography is routinely used to image such diseases, many animal models of ocular vascular disease and development rely on dissected tissues that may not accurately represent in vivo conditions and require enucleation of the eye, the death of the animal, or both. METHODS: A method of three-dimensional imaging of blood vessels was used in the living mouse eye that involved scanning laser confocal microscopy and computer-aided image reconstruction. RESULTS: This minimally invasive technique was used to collect three-dimensional images of intraocular vessels in vivo during development. The retinal and choroidal vasculature was studied during development and disease, in models of retinal degeneration, central retinal vein occlusion, and oxygen-induced retinopathy. To aid in investigations into cell-based therapies for retinal disease, two-color imaging was used to localize transplanted cells in relation to the vasculature. This technique was used to perform serial imaging of the ocular vasculature over time, when developmental regression of vessels was observed. CONCLUSIONS: This in vivo vascular imaging approach is valuable in monitoring normal development, disease progression, and efficacy of experimental treatments in mouse models of ocular vascular disease and may have broader applications to the field of angiogenesis by using the readily visualized ocular vascular bed as a surrogate to test pro- and antiangiogenic compounds.
Authors: Andreas Stahl; Kip M Connor; Przemyslaw Sapieha; Jing Chen; Roberta J Dennison; Nathan M Krah; Molly R Seaward; Keirnan L Willett; Christopher M Aderman; Karen I Guerin; Jing Hua; Chatarina Löfqvist; Ann Hellström; Lois E H Smith Journal: Invest Ophthalmol Vis Sci Date: 2010-06 Impact factor: 4.799
Authors: Patrycja Nowak-Sliwinska; Kari Alitalo; Elizabeth Allen; Andrey Anisimov; Alfred C Aplin; Robert Auerbach; Hellmut G Augustin; David O Bates; Judy R van Beijnum; R Hugh F Bender; Gabriele Bergers; Andreas Bikfalvi; Joyce Bischoff; Barbara C Böck; Peter C Brooks; Federico Bussolino; Bertan Cakir; Peter Carmeliet; Daniel Castranova; Anca M Cimpean; Ondine Cleaver; George Coukos; George E Davis; Michele De Palma; Anna Dimberg; Ruud P M Dings; Valentin Djonov; Andrew C Dudley; Neil P Dufton; Sarah-Maria Fendt; Napoleone Ferrara; Marcus Fruttiger; Dai Fukumura; Bart Ghesquière; Yan Gong; Robert J Griffin; Adrian L Harris; Christopher C W Hughes; Nan W Hultgren; M Luisa Iruela-Arispe; Melita Irving; Rakesh K Jain; Raghu Kalluri; Joanna Kalucka; Robert S Kerbel; Jan Kitajewski; Ingeborg Klaassen; Hynda K Kleinmann; Pieter Koolwijk; Elisabeth Kuczynski; Brenda R Kwak; Koen Marien; Juan M Melero-Martin; Lance L Munn; Roberto F Nicosia; Agnes Noel; Jussi Nurro; Anna-Karin Olsson; Tatiana V Petrova; Kristian Pietras; Roberto Pili; Jeffrey W Pollard; Mark J Post; Paul H A Quax; Gabriel A Rabinovich; Marius Raica; Anna M Randi; Domenico Ribatti; Curzio Ruegg; Reinier O Schlingemann; Stefan Schulte-Merker; Lois E H Smith; Jonathan W Song; Steven A Stacker; Jimmy Stalin; Amber N Stratman; Maureen Van de Velde; Victor W M van Hinsbergh; Peter B Vermeulen; Johannes Waltenberger; Brant M Weinstein; Hong Xin; Bahar Yetkin-Arik; Seppo Yla-Herttuala; Mervin C Yoder; Arjan W Griffioen Journal: Angiogenesis Date: 2018-08 Impact factor: 9.596
Authors: Jacek K Pijanka; Elizabeth C Kimball; Mary E Pease; Ahmed Abass; Thomas Sorensen; Thao D Nguyen; Harry A Quigley; Craig Boote Journal: Invest Ophthalmol Vis Sci Date: 2014-09-16 Impact factor: 4.799
Authors: Ross A Poché; Irina V Larina; Melissa L Scott; Jennifer E Saik; Jennifer L West; Mary E Dickinson Journal: Dev Dyn Date: 2009-09 Impact factor: 3.780
Authors: Anne C Bachg; Markus Horsthemke; Boris V Skryabin; Tim Klasen; Nina Nagelmann; Cornelius Faber; Emma Woodham; Laura M Machesky; Sandra Bachg; Richard Stange; Hyun-Woo Jeong; Ralf H Adams; Martin Bähler; Peter J Hanley Journal: Sci Rep Date: 2019-01-24 Impact factor: 4.379