PURPOSE: To elucidate the relation between optical coherence tomography (OCT) scans and retinal histology in normal and retinal degeneration (rd) chickens. METHODS: Retinas from adult normal and rd chickens were examined in vivo with OCT at 850 nm and compared quantitatively with stained cryosections of unfixed retinas from the same locations. RESULTS: The nerve fiber layer (NFL) and inner plexiform layer (IPL) show homogeneous backscatter throughout their thicknesses. NFL reflectivity is approximately 0.6 log units higher than that of the IPL. The inner nuclear layer shows a low reflectivity; the properties of reflections from ganglion cell and outer nuclear layers are indeterminate. The outer retina and choroid form a large reflective complex. Photoreceptor inner segments produce the highest of these reflections in normal chicken retinas, approximately 1.5 log units higher than that of the IPL. The retinal pigment epithelium also has a relatively large backscatter coefficient and is the dominant reflector in rd retinas that lack photoreceptors. Choroidal pigment produces an intermediate level of backscatter and is the largest attenuator of signal at 850 nm. CONCLUSIONS: Quantified OCT signals have a predictable relationship to histology and pathology in chicken retinas. The results from rd retinas represent a first step toward in vivo quantitation of retinal structure in retinal degenerative disease.
PURPOSE: To elucidate the relation between optical coherence tomography (OCT) scans and retinal histology in normal and retinal degeneration (rd) chickens. METHODS: Retinas from adult normal and rd chickens were examined in vivo with OCT at 850 nm and compared quantitatively with stained cryosections of unfixed retinas from the same locations. RESULTS: The nerve fiber layer (NFL) and inner plexiform layer (IPL) show homogeneous backscatter throughout their thicknesses. NFL reflectivity is approximately 0.6 log units higher than that of the IPL. The inner nuclear layer shows a low reflectivity; the properties of reflections from ganglion cell and outer nuclear layers are indeterminate. The outer retina and choroid form a large reflective complex. Photoreceptor inner segments produce the highest of these reflections in normal chicken retinas, approximately 1.5 log units higher than that of the IPL. The retinal pigment epithelium also has a relatively large backscatter coefficient and is the dominant reflector in rd retinas that lack photoreceptors. Choroidal pigment produces an intermediate level of backscatter and is the largest attenuator of signal at 850 nm. CONCLUSIONS: Quantified OCT signals have a predictable relationship to histology and pathology in chicken retinas. The results from rd retinas represent a first step toward in vivo quantitation of retinal structure in retinal degenerative disease.
Authors: Marco Ruggeri; James C Major; Craig McKeown; Robert W Knighton; Carmen A Puliafito; Shuliang Jiao Journal: Invest Ophthalmol Vis Sci Date: 2010-06-16 Impact factor: 4.799
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Authors: Wei Chieh Huang; Artur V Cideciyan; Alejandro J Roman; Alexander Sumaroka; Rebecca Sheplock; Sharon B Schwartz; Edwin M Stone; Samuel G Jacobson Journal: Invest Ophthalmol Vis Sci Date: 2014-03-20 Impact factor: 4.799