INTRODUCTION: The work described here involved the use of a modified fundus camera to obtain sequential hyperspectral images of the retina in 14 normal volunteers and in 1 illustrative patient with a retinal vascular occlusion. METHODS: The paper describes analysis techniques, which allow oximetry within retinal vessels; these results are presented as retinal oximetry maps. RESULTS: Using spectral images, with wavelengths between 556 and 650 nm, the mean oxygen saturation (OS) value in temporal retinal arterioles in normal volunteers was 104.3 (± 16.7), and in normal temporal retinal venules was 34.8 (± 17.8). These values are comparable to those quoted in the literature, although, the venular saturations are slightly lower than those values found by other authors; explanations are offered for these differences. DISCUSSION: The described imaging and analysis techniques produce a clinically useful map of retinal oximetric values. The results from normal volunteers and from one illustrative patient are presented. Further developments, including the recent development of a 'snapshot' spectral camera, promises enhanced non-invasive retinal vessel oximetry mapping.
INTRODUCTION: The work described here involved the use of a modified fundus camera to obtain sequential hyperspectral images of the retina in 14 normal volunteers and in 1 illustrative patient with a retinal vascular occlusion. METHODS: The paper describes analysis techniques, which allow oximetry within retinal vessels; these results are presented as retinal oximetry maps. RESULTS: Using spectral images, with wavelengths between 556 and 650 nm, the mean oxygen saturation (OS) value in temporal retinal arterioles in normal volunteers was 104.3 (± 16.7), and in normal temporal retinal venules was 34.8 (± 17.8). These values are comparable to those quoted in the literature, although, the venular saturations are slightly lower than those values found by other authors; explanations are offered for these differences. DISCUSSION: The described imaging and analysis techniques produce a clinically useful map of retinal oximetric values. The results from normal volunteers and from one illustrative patient are presented. Further developments, including the recent development of a 'snapshot' spectral camera, promises enhanced non-invasive retinal vessel oximetry mapping.
Authors: J R Harish Kumar; Chandra Sekhar Seelamantula; Ashwin Mohan; Rohit Shetty; T J M Berendschot; Carroll A B Webers Journal: PLoS One Date: 2020-05-18 Impact factor: 3.240
Authors: Yuehong Tong; Tal Ben Ami; Sungmin Hong; Rainer Heintzmann; Guido Gerig; Zsolt Ablonczy; Christine A Curcio; Thomas Ach; R Theodore Smith Journal: Retina Date: 2016-12 Impact factor: 4.256
Authors: Samuel Ortega; Himar Fabelo; Rafael Camacho; María de la Luz Plaza; Gustavo M Callicó; Roberto Sarmiento Journal: Biomed Opt Express Date: 2018-01-25 Impact factor: 3.732