PURPOSE: To test the reproducibility of spectral-domain optical coherence tomography (SD-OCT) total retinal thickness (TRT) measurements in mice. METHODS: C57Bl/6 mice were anesthetized, and three repeated volumetric images were acquired in both eyes with SD-OCT (250 A-scans × 250 frames × 1024 samplings), centered on the optic nerve head (ONH). The mice were repositioned between scans. TRT was automatically measured within a sampling band of retinal thickness with radii of 55 to 70 pixels, centered on the ONH by using custom segmentation software. The first volumetric image acquired in a given eye was used to register the remaining two SD-OCT images by manually aligning the en face images with respect to rotation and linear translation. Linear mixed-effects models were fitted to global and quadrant thicknesses, taking into account the clustering between eyes, to assess imprecision (measurement reproducibility). RESULTS: Twenty-six eyes of 13 adult mice (age 13 weeks) were imaged. The mean global TRT across all eyes was 298.21 μm, with a mouse heterogeneity standard deviation (SD) of 4.88 μm (coefficient of variation [CV] = 0.016), an eye SD of 3.32 μm (CV = 0.011), and a device-related imprecision SD of 2.33 μm (CV = 0.008). The superior quadrant had the thickest mean TRT measurement (310.38 μm) and the highest (worst) imprecision SD (3.13 μm; CV = 0.010), and the inferior quadrant had the thinnest mean TRT (291.55 μm). The quadrant with the lowest (best) imprecision SD was in the nasal one (2.06 μm; CV = 0.007). CONCLUSIONS: Good reproducibility was observed for SD-OCT retinal thickness measurements in mice. SD-OCT may be useful for in vivo longitudinal studies in mice.
PURPOSE: To test the reproducibility of spectral-domain optical coherence tomography (SD-OCT) total retinal thickness (TRT) measurements in mice. METHODS: C57Bl/6 mice were anesthetized, and three repeated volumetric images were acquired in both eyes with SD-OCT (250 A-scans × 250 frames × 1024 samplings), centered on the optic nerve head (ONH). The mice were repositioned between scans. TRT was automatically measured within a sampling band of retinal thickness with radii of 55 to 70 pixels, centered on the ONH by using custom segmentation software. The first volumetric image acquired in a given eye was used to register the remaining two SD-OCT images by manually aligning the en face images with respect to rotation and linear translation. Linear mixed-effects models were fitted to global and quadrant thicknesses, taking into account the clustering between eyes, to assess imprecision (measurement reproducibility). RESULTS: Twenty-six eyes of 13 adult mice (age 13 weeks) were imaged. The mean global TRT across all eyes was 298.21 μm, with a mouse heterogeneity standard deviation (SD) of 4.88 μm (coefficient of variation [CV] = 0.016), an eye SD of 3.32 μm (CV = 0.011), and a device-related imprecision SD of 2.33 μm (CV = 0.008). The superior quadrant had the thickest mean TRT measurement (310.38 μm) and the highest (worst) imprecision SD (3.13 μm; CV = 0.010), and the inferior quadrant had the thinnest mean TRT (291.55 μm). The quadrant with the lowest (best) imprecision SD was in the nasal one (2.06 μm; CV = 0.007). CONCLUSIONS: Good reproducibility was observed for SD-OCT retinal thickness measurements in mice. SD-OCT may be useful for in vivo longitudinal studies in mice.
Authors: Lelia A Paunescu; Joel S Schuman; Lori Lyn Price; Paul C Stark; Siobahn Beaton; Hiroshi Ishikawa; Gadi Wollstein; James G Fujimoto Journal: Invest Ophthalmol Vis Sci Date: 2004-06 Impact factor: 4.799
Authors: Q Li; A M Timmers; K Hunter; C Gonzalez-Pola; A S Lewin; D H Reitze; W W Hauswirth Journal: Invest Ophthalmol Vis Sci Date: 2001-11 Impact factor: 4.799
Authors: Colleen M Cebulla; Marco Ruggeri; Timothy G Murray; William J Feuer; Eleut Hernandez Journal: Exp Eye Res Date: 2010-01-28 Impact factor: 3.467
Authors: Gadi Wollstein; Joel S Schuman; Lori L Price; Ali Aydin; Paul C Stark; Ellen Hertzmark; Edward Lai; Hiroshi Ishikawa; Cynthia Mattox; James G Fujimoto; Lelia A Paunescu Journal: Arch Ophthalmol Date: 2005-04
Authors: Hiroshi Ishikawa; Daniel M Stein; Gadi Wollstein; Siobahn Beaton; James G Fujimoto; Joel S Schuman Journal: Invest Ophthalmol Vis Sci Date: 2005-06 Impact factor: 4.799
Authors: Peter Charbel Issa; Mandeep S Singh; Daniel M Lipinski; Ngaihang V Chong; François C Delori; Alun R Barnard; Robert E MacLaren Journal: Invest Ophthalmol Vis Sci Date: 2012-02-29 Impact factor: 4.799
Authors: Bhavna J Antony; Michael D Abràmoff; Matthew M Harper; Woojin Jeong; Elliott H Sohn; Young H Kwon; Randy Kardon; Mona K Garvin Journal: Biomed Opt Express Date: 2013-11-01 Impact factor: 3.732
Authors: Michelle L Gabriele; Gadi Wollstein; Hiroshi Ishikawa; Larry Kagemann; Juan Xu; Lindsey S Folio; Joel S Schuman Journal: Invest Ophthalmol Vis Sci Date: 2011-04-14 Impact factor: 4.799
Authors: Robert A Avery; Avital Cnaan; Joel S Schuman; Chieh-Li Chen; Natalie C Glaug; Roger J Packer; Graham E Quinn; Hiroshi Ishikawa Journal: Am J Ophthalmol Date: 2014-06-28 Impact factor: 5.258
Authors: Maren Engelhardt; Chinatsu Tosha; Vanda S Lopes; Bryan Chen; Lisa Nguyen; Steven Nusinowitz; David S Williams Journal: Vis Neurosci Date: 2012-03-06 Impact factor: 3.241