Balwantray C Chauhan1, Neil O'Leary2, Faisal A AlMobarak3, Alexandre S C Reis4, Hongli Yang5, Glen P Sharpe2, Donna M Hutchison2, Marcelo T Nicolela2, Claude F Burgoyne5. 1. Department of Ophthalmology and Visual Sciences, Dalhousie University, Halifax, Nova Scotia, Canada. Electronic address: bal@dal.ca. 2. Department of Ophthalmology and Visual Sciences, Dalhousie University, Halifax, Nova Scotia, Canada. 3. Department of Ophthalmology and Visual Sciences, Dalhousie University, Halifax, Nova Scotia, Canada; Department of Ophthalmology, College of Medicine, King Saud University, Riyadh, Saudi Arabia. 4. Department of Ophthalmology and Visual Sciences, Dalhousie University, Halifax, Nova Scotia, Canada; Department of Ophthalmology, University of São Paulo, São Paulo, Brazil. 5. Devers Eye Institute, Portland, Oregon.
Abstract
OBJECTIVE: Neuroretinal rim assessment based on the clinical optic disc margin (DM) lacks a sound anatomic basis for 2 reasons: (1) The DM is not reliable as the outer border of rim tissue because of clinically and photographically invisible extensions of Bruch's membrane (BM) inside the DM and (2) nonaccountability of rim tissue orientation in the optic nerve head (ONH). The BM opening-minimum rim width (BMO-MRW) is a parameter that quantifies the rim from its true anatomic outer border, BMO, and accounts for its variable orientation. We report the diagnostic capability of BMO-MRW. DESIGN: Case control. PARTICIPANTS: Patients with open-angle glaucoma (n = 107) and healthy controls (n = 48). METHODS: Spectral-domain optical coherence tomography (SD-OCT) with 24 radial and 1 circumpapillary B-scans, centered on the ONH, and confocal scanning laser tomography (CSLT) were performed. The internal limiting membrane (ILM) and BMO were manually segmented in each radial B-scan. Three SD-OCT parameters were computed globally and sectorally: (1) circumpapillary retinal nerve fiber layer thickness (RNFLT); (2) BMO-horizontal rim width (BMO-HRW), the distance between BMO and ILM in the BMO reference plane; and (3) BMO-MRW, the minimum distance between BMO and ILM. Moorfields Regression Analysis (MRA) with CLST was performed globally and sectorally to yield MRA1 and MRA2, where "borderline" was classified as normal and abnormal, respectively. MAIN OUTCOME MEASURES: Sensitivity, specificity, and likelihood ratios (LRs) for positive and negative test results (LR+/LR-). RESULTS: The median (interquartile range) age and mean deviation of patients and controls were 69.9 (64.3-76.9) and 65.0 (58.1-74.3) years and -3.92 (-7.87 to -1.62) and 0.33 (-0.32 to 0.98) dB, respectively. Globally, BMO-MRW yielded better diagnostic performance than the other parameters. At 95% specificity, the sensitivity of RNFLT, BMO-HRW, and BMO-MRW was 70%, 51%, and 81%, respectively. The corresponding LR+/LR- was 14.0/0.3, 10.2/0.5, and 16.2/0.2. Sectorally, at 95% specificity, the sensitivity of RNFLT ranged from 31% to 59%, of BMO-HRW ranged from 35% to 64%, and of BMO-MRW ranged from 54% to 79%. Globally and in all sectors, BMO-MRW performed better than MRA1 or MRA2. CONCLUSIONS: The higher sensitivity at 95% specificity in early glaucoma of BMO-MRW compared with current BMO methods is significant, indicating a new structural marker for the detection and risk profiling of glaucoma.
OBJECTIVE:Neuroretinal rim assessment based on the clinical optic disc margin (DM) lacks a sound anatomic basis for 2 reasons: (1) The DM is not reliable as the outer border of rim tissue because of clinically and photographically invisible extensions of Bruch's membrane (BM) inside the DM and (2) nonaccountability of rim tissue orientation in the optic nerve head (ONH). The BM opening-minimum rim width (BMO-MRW) is a parameter that quantifies the rim from its true anatomic outer border, BMO, and accounts for its variable orientation. We report the diagnostic capability of BMO-MRW. DESIGN: Case control. PARTICIPANTS: Patients with open-angle glaucoma (n = 107) and healthy controls (n = 48). METHODS: Spectral-domain optical coherence tomography (SD-OCT) with 24 radial and 1 circumpapillary B-scans, centered on the ONH, and confocal scanning laser tomography (CSLT) were performed. The internal limiting membrane (ILM) and BMO were manually segmented in each radial B-scan. Three SD-OCT parameters were computed globally and sectorally: (1) circumpapillary retinal nerve fiber layer thickness (RNFLT); (2) BMO-horizontal rim width (BMO-HRW), the distance between BMO and ILM in the BMO reference plane; and (3) BMO-MRW, the minimum distance between BMO and ILM. Moorfields Regression Analysis (MRA) with CLST was performed globally and sectorally to yield MRA1 and MRA2, where "borderline" was classified as normal and abnormal, respectively. MAIN OUTCOME MEASURES: Sensitivity, specificity, and likelihood ratios (LRs) for positive and negative test results (LR+/LR-). RESULTS: The median (interquartile range) age and mean deviation of patients and controls were 69.9 (64.3-76.9) and 65.0 (58.1-74.3) years and -3.92 (-7.87 to -1.62) and 0.33 (-0.32 to 0.98) dB, respectively. Globally, BMO-MRW yielded better diagnostic performance than the other parameters. At 95% specificity, the sensitivity of RNFLT, BMO-HRW, and BMO-MRW was 70%, 51%, and 81%, respectively. The corresponding LR+/LR- was 14.0/0.3, 10.2/0.5, and 16.2/0.2. Sectorally, at 95% specificity, the sensitivity of RNFLT ranged from 31% to 59%, of BMO-HRW ranged from 35% to 64%, and of BMO-MRW ranged from 54% to 79%. Globally and in all sectors, BMO-MRW performed better than MRA1 or MRA2. CONCLUSIONS: The higher sensitivity at 95% specificity in early glaucoma of BMO-MRW compared with current BMO methods is significant, indicating a new structural marker for the detection and risk profiling of glaucoma.
Authors: Balwantray C Chauhan; Donna M Hutchison; Paul H Artes; Joseph Caprioli; Jost B Jonas; Raymond P LeBlanc; Marcelo T Nicolela Journal: Invest Ophthalmol Vis Sci Date: 2008-12-05 Impact factor: 4.799
Authors: Nicholas G Strouthidis; Hongli Yang; J Crawford Downs; Claude F Burgoyne Journal: Invest Ophthalmol Vis Sci Date: 2009-01-10 Impact factor: 4.799
Authors: Boris Povazay; Bernd Hofer; Boris Hermann; Angelika Unterhuber; James E Morgan; Carl Glittenberg; Susanne Binder; Wolfgang Drexler Journal: J Biomed Opt Date: 2007 Jul-Aug Impact factor: 3.170
Authors: Harsha L Rao; Mauro T Leite; Robert N Weinreb; Linda M Zangwill; Luciana M Alencar; Pamela A Sample; Felipe A Medeiros Journal: Invest Ophthalmol Vis Sci Date: 2011-03-10 Impact factor: 4.799
Authors: Michael D Abràmoff; Kyungmoo Lee; Meindert Niemeijer; Wallace L M Alward; Emily C Greenlee; Mona K Garvin; Milan Sonka; Young H Kwon Journal: Invest Ophthalmol Vis Sci Date: 2009-07-15 Impact factor: 4.799
Authors: N M Jansonius; J Nevalainen; B Selig; L M Zangwill; P A Sample; W M Budde; J B Jonas; W A Lagrèze; P J Airaksinen; R Vonthein; L A Levin; J Paetzold; U Schiefer Journal: Vision Res Date: 2009-06-16 Impact factor: 1.886
Authors: Nicholas G Strouthidis; Hongli Yang; Brad Fortune; J Crawford Downs; Claude F Burgoyne Journal: Invest Ophthalmol Vis Sci Date: 2008-08-08 Impact factor: 4.799
Authors: Kyungmoo Lee; Meindert Niemeijer; Mona K Garvin; Young H Kwon; Milan Sonka; Michael D Abramoff Journal: IEEE Trans Med Imaging Date: 2009-09-15 Impact factor: 10.048
Authors: Lin He; Hongli Yang; Stuart K Gardiner; Galen Williams; Christy Hardin; Nicholas G Strouthidis; Brad Fortune; Claude F Burgoyne Journal: Invest Ophthalmol Vis Sci Date: 2014-01-29 Impact factor: 4.799
Authors: Tin A Tun; Eray Atalay; Mani Baskaran; Monisha E Nongpiur; Hla M Htoon; David Goh; Ching-Yu Cheng; Shamira A Perera; Tin Aung; Nicholas G Strouthidis; Michaël J A Girard Journal: JAMA Ophthalmol Date: 2018-02-01 Impact factor: 7.389
Authors: Grace M Richter; Xinbo Zhang; Ou Tan; Brian A Francis; Vikas Chopra; David S Greenfield; Rohit Varma; Joel S Schuman; David Huang Journal: J Glaucoma Date: 2016-08 Impact factor: 2.503
Authors: Akram Belghith; Christopher Bowd; Felipe A Medeiros; Madhusudhanan Balasubramanian; Robert N Weinreb; Linda M Zangwill Journal: J Med Imaging (Bellingham) Date: 2014-12-29