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Editors Selection IGR 23-4
List of Editor's Selection comments by
Andrew Tatham
Princess Alexandra Eye Pavilion and Department of Ophthalmology, University of Edinburgh, Edinburgh, UK
Laser Treatment: Latanoprost, SLT and Circadian IOP (24-1, April 2024) on:
109941 24-Hour efficacy of single primary selective laser trabeculoplasty versus latanoprost eye drops for Naïve primary open-angle glaucoma and ocular hypertension patients
Shi Y; Zhang Y; Sun W et al.
Scientific reports 2023; 13: 12179
Medical Treatment: Impact of Low Vision on Medical Treatment (23-4, October 2023) on:
108441 Patients with Low-vision Struggle with Placing Eye Drops and Benefit from an Eye Drop Aid
Grissom N; Gardiner SK; Rees JP et al. et al.
Ophthalmology. Glaucoma 2023; 6: 501-508
Laser Treatment: Does Anti-Inflammatory treatment affect SLT outcomes? (22-3, April 2022) on:
96210 Effects of anti-inflammatory treatment on efficacy of selective laser trabeculoplasty: a systematic review and meta-analysis
Chen YS; Hung HT; Guo SP et al. et al.
Expert Review of Clinical Pharmacology 2021; 0: 1-8
Clinical Examination Methods: Diurnal IOP patterns (22-1, October 2021) on:
92798 24-h intraocular pressure patterns measured by Icare PRO rebound in habitual position of open-angle glaucoma eyes
Fang Z; Wang X; Qiu S et al.
Graefe's Archive for Clinical and Experimental Ophthalmology 2021; 259: 2327-2335
Medical Treatment: Netarsudil for Glaucoma (21-4, June 2021) on:
90997 Pooled Efficacy and Safety Profile of Netarsudil Ophthalmic Solution 0.02% in Patients With Open-angle Glaucoma or Ocular Hypertension
Singh IP; Fechtner RD; Myers JS et al.
Journal of Glaucoma 2020; 29: 878-884
Clinical Examination Methods: Corneal Thickness and IOP (21-1, November 2020) on:
84094 Modified Goldmann prism intraocular pressure measurement accuracy and correlation to corneal biomechanical metrics: multicentre randomised clinical trial
McCafferty SJ; Tetrault K; McColgin A et al.
British Journal of Ophthalmology 2019; 103: 1840-1844
Clinical Examination Methods: Artificial Intelligence applications III (20-4, June 2020) on:
82788 Deep Learning Approaches Predict Glaucomatous Visual Field Damage from OCT Optic Nerve Head En Face Images and Retinal Nerve Fiber Layer Thickness Maps
Christopher M; Bowd C; Belghith A et al.
Ophthalmology 2020; 127: 346-356
Surgical Treatment: Drainage Devices II (20-3, March 2020) on:
80503 Optical coherence tomography analysis of filtering blebs after long-term, functioning trabeculectomy and XEN® stent implant
Teus MA; Paz Moreno-Arrones J; Castaño B et al.
Graefe's Archive for Clinical and Experimental Ophthalmology 2019; 257: 1005-1011
Miscellaneous: Glaucoma and Driving (20-3, March 2020) on:
81404 Eye Movements of Drivers with Glaucoma on a Visual Recognition Slide Test
Lee SS; Black AA; Wood JM
Optometry and Vision Science 2019; 96: 484-491
Clinical Examination Methods: Home-based Monitoring (20-2, November 2019) on:
79572 Home-based visual field test for glaucoma screening comparison with Humphrey perimeter
Tsapakis S; Papaconstantinou D; Diagourtas A et al.
Clinical Ophthalmology 2018; 12: 2597-2606
Anatomical Structures: Macular structure and function (20-1, July 2019) on:
79073 Improving Visual Field Examination of the Macula Using Structural Information
Montesano G; Rossetti LM; Allegrini D et al.
Translational vision science & technology 2018; 7: 36
Clinical Examination Methods: Structural disease progression (20-1, July 2019) on:
78995 Serial Combined Wide-Field Optical Coherence Tomography Maps for Detection of Early Glaucomatous Structural Progression
Lee WJ; Kim TJ; Kim YK et al.
JAMA ophthalmology 2018; 136: 1121-1127
Anatomical Structures: Posterior pole Vascularization and Structural Progression (19-4, March 2019) on:
77939 Macular and Optic Nerve Head Vessel Density and Progressive Retinal Nerve Fiber Layer Loss in Glaucoma
Moghimi S; Zangwill LM; Penteado RC et al.
Ophthalmology 2018; 125: 1720-1728
Anatomical Structures: Detecting Macular Damage in Glaucoma (19-3, December 2018) on:
76858 Evaluation of a Region-of-Interest Approach for Detecting Progressive Glaucomatous Macular Damage on Optical Coherence Tomography
Wu Z; Weng DSD; Weng DSD; Weng DSD; Thenappan A et al.
Translational vision science & technology 2018; 7: 14
Prevention and Screening: Raising Glaucoma Awareness (19-2, September 2018) on:
76015 The effect of a short animated educational video on knowledge among glaucoma patients
Al Owaifeer AM; Alrefaie SM; Alsawah ZM et al.
Clinical Ophthalmology 2018; 12: 805-810
Clinical Examination Methods: Function: Relation Between Reliability Index and Sensitivity (19-1, May 2018) on:
74300 The Effect of Testing Reliability on Visual Field Sensitivity in Normal Eyes: The Singapore Chinese Eye Study
Tan NYQ; Tham YC; Koh V et al.
Ophthalmology 2018; 125: 15-21
Quality of Life: Macular Damage and Quality of Life (18-4, December 2017) on:
72705 Comparison of self-measured diurnal intraocular pressure profiles using rebound tonometry between primary angle closure glaucoma and primary open angle glaucoma patients
Tan S; Baig N; Hansapinyo L et al.
PLoS ONE 2017; 12: e0173905
Clinical Examination Methods: Diurnal IOP Patterns in POAG and PACG (18-4, December 2017) on:
73244 Association of Glaucoma-Related, Optical Coherence Tomography-Measured Macular Damage With Vision-Related Quality of Life
Prager AJ; Hood DC; Liebmann JM et al.
JAMA ophthalmology 2017; 135: 783-788
Anatomical Structures: RNFL thinning rate topography (18-3, July 2017) on:
71410 Trend-Based Progression Analysis for Examination of the Topography of Rates of Retinal Nerve Fiber Layer Thinning in Glaucoma
Lin C; Mak H; Yu M et al.
JAMA ophthalmology 2017; 135: 189-195
Miscellaneous: A statistical model to help detect visual field progression (18-1, February 2017) on:
69493 A Statistical Model to Analyze Clinician Expert Consensus on Glaucoma Progression using Spatially Correlated Visual Field Data
Warren JL; Mwanza JC; Tanna AP et al.
Translational vision science & technology 2016; 5: 14
Anatomical Structures: Bruch's membrane opening (17-4, September 2016) on:
66747 Does the Location of Bruch's Membrane Opening Change Over Time? Longitudinal Analysis Using San Diego Automated Layer Segmentation Algorithm (SALSA)
Belghith A; Bowd C; Medeiros FA et al.
Investigative Ophthalmology and Visual Science 2016; 57: 675-682
Anatomical Structures: Laminar structure and field loss (17-4, September 2016) on:
67171 Prelamina and Lamina Cribrosa in Glaucoma Patients With Unilateral Visual Field Loss
Kim DW; Jeoung JW; Kim YW et al.
Investigative Ophthalmology and Visual Science 2016; 57: 1662-1670
Anatomical Structures: Lamina Cribrosa Mechanics in an Animal Model (17-3, June 2016) on:
65845 Phase-contrast Micro-computed Tomography Measurements of the Intraocular Pressure-induced Deformation of the Porcine Lamina Cribrosa
Coudrillier B; Geraldes D; Vo N et al.
IEEE Transactions on Medical Imaging 2016; 35: 988-999
Medical Treatment: Prostaglandins, Eyelids and Eyelid Muscles (17-1, January 2016) on:
61498 Prostaglandin Eyedrops Are Associated With Decreased Thicknesses of Eyelid Dermis and Orbicularis Oculi Muscle: Ultrasonographic Findings
Goh AS; Nassiri N; Kohn JC et al.
Ophthalmic Plastic and Reconstructive Surgery 2016; 32: 337-341
Anatomical Structures: Lamina Cribrosa in Normal Pressure Glaucoma (16-4, September 2015) on:
60790 3D Evaluation of the Lamina Cribrosa with Swept-Source Optical Coherence Tomography in Normal Tension Glaucoma
Omodaka K; Horii T; Takahashi S et al.
PLoS ONE 2015; 10: e0122347
Clinical Examination Methods: Preperimetric diagnosis by OCT (15-4, September 2014) on:
55188 Ability of different scanning protocols of spectral domain optical coherence tomography to diagnose preperimetric glaucoma
Rao HL; Addepalli UK; Chaudhary S et al.
Investigative Ophthalmology and Visual Science 2013; 54: 7252-7257
Clinical Forms of Glaucoma: Glaucoma diagnosis in high-myopia eyes (15-2, December 2013) on:
53937 Macular Imaging in Highly Myopic Eyes With and Without Glaucoma
Nakano N; Hangai M; Noma H et al.
American Journal of Ophthalmology 2013; 156: 511-523
