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List of abstracts related to

Listed by Classification

6.9.1.1 Confocal Scanning Laser Ophthalmoscopy (844 abstracts found)

94827 Glaucoma Diagnostic Testing: The Influence of Optic Disc Size
Scheuble P
Klinische Monatsblätter für Augenheilkunde 2022; 239: 1043-1051 (IGR: 22-2)

94909 Glaucoma classification based on scanning laser ophthalmoscopic images using a deep learning ensemble method
Sułot D
PLoS ONE 2021; 16: e0252339 (IGR: 22-2)

94519 Interpreting Retinal Nerve Fiber Layer Reflectance Defects Based on Presence of Retinal Nerve Fiber Bundles
Swanson WH; King BJ
Optometry and Vision Science 2021; 98: 531-541 (IGR: 22-2)

94909 Glaucoma classification based on scanning laser ophthalmoscopic images using a deep learning ensemble method
Alonso-Caneiro D
PLoS ONE 2021; 16: e0252339 (IGR: 22-2)

94827 Glaucoma Diagnostic Testing: The Influence of Optic Disc Size
Petrak M
Klinische Monatsblätter für Augenheilkunde 2022; 239: 1043-1051 (IGR: 22-2)

94909 Glaucoma classification based on scanning laser ophthalmoscopic images using a deep learning ensemble method
Ksieniewicz P
PLoS ONE 2021; 16: e0252339 (IGR: 22-2)

94519 Interpreting Retinal Nerve Fiber Layer Reflectance Defects Based on Presence of Retinal Nerve Fiber Bundles
Burns SA
Optometry and Vision Science 2021; 98: 531-541 (IGR: 22-2)

94827 Glaucoma Diagnostic Testing: The Influence of Optic Disc Size
Brinkmann CK
Klinische Monatsblätter für Augenheilkunde 2022; 239: 1043-1051 (IGR: 22-2)

94909 Glaucoma classification based on scanning laser ophthalmoscopic images using a deep learning ensemble method
Krzyzanowska-Berkowska P; Iskander DR
PLoS ONE 2021; 16: e0252339 (IGR: 22-2)

92264 Diagnostic capability of different morphological parameters for primary open-angle glaucoma in the Chinese population
Li R; Wang X; Wei Y; Fang Y; Tian T; Kang L; Li M; Cai Y; Pan Y
BMC Ophthalmology 2021; 21: 151 (IGR: 22-1)

91230 Evaluation of the external validity of a joint structure-function model for monitoring glaucoma progression
Abu SL
Scientific reports 2020; 10: 19701 (IGR: 21-4)

91750 A comparison of optic disc area measured by confocal scanning laser tomography versus Bruch's membrane opening area measured using optical coherence tomography
Cazana IM
BMC Ophthalmology 2021; 21: 31 (IGR: 21-4)

91230 Evaluation of the external validity of a joint structure-function model for monitoring glaucoma progression
KhalafAllah MT
Scientific reports 2020; 10: 19701 (IGR: 21-4)

91750 A comparison of optic disc area measured by confocal scanning laser tomography versus Bruch's membrane opening area measured using optical coherence tomography
Böhringer D; Reinhard T
BMC Ophthalmology 2021; 21: 31 (IGR: 21-4)

91230 Evaluation of the external validity of a joint structure-function model for monitoring glaucoma progression
Racette L
Scientific reports 2020; 10: 19701 (IGR: 21-4)

91750 A comparison of optic disc area measured by confocal scanning laser tomography versus Bruch's membrane opening area measured using optical coherence tomography
Evers C; Engesser D; Anton A; Lübke J
BMC Ophthalmology 2021; 21: 31 (IGR: 21-4)

90592 Presumed activated retinal astrocytes and Müller cells in healthy and glaucomatous eyes detected by spectral domain optical coherence tomography
Cheung H; King BJ; Gast TJ
Ophthalmic and Physiological Optics 2020; 40: 738-751 (IGR: 21-3)

84957 Diagnostic performance of modern imaging instruments in glaucoma screening
Karvonen E
British Journal of Ophthalmology 2020; 104: 1399-1405 (IGR: 21-1)

84492 Relationship between pattern electroretinogram and optic disc morphology in glaucoma
Jeon SJ; Park HL
PLoS ONE 2019; 14: e0220992 (IGR: 21-1)

84957 Diagnostic performance of modern imaging instruments in glaucoma screening
Stoor K
British Journal of Ophthalmology 2020; 104: 1399-1405 (IGR: 21-1)

84492 Relationship between pattern electroretinogram and optic disc morphology in glaucoma
Jung KI
PLoS ONE 2019; 14: e0220992 (IGR: 21-1)

84957 Diagnostic performance of modern imaging instruments in glaucoma screening
Luodonpää M
British Journal of Ophthalmology 2020; 104: 1399-1405 (IGR: 21-1)

84492 Relationship between pattern electroretinogram and optic disc morphology in glaucoma
Park CK
PLoS ONE 2019; 14: e0220992 (IGR: 21-1)

84957 Diagnostic performance of modern imaging instruments in glaucoma screening
Hägg P; Lintonen T; Liinamaa J; Tuulonen A; Saarela V
British Journal of Ophthalmology 2020; 104: 1399-1405 (IGR: 21-1)

82593 Influence of Inflammation in Uveitis on Confocal Scanning Laser Tomography and Optical Coherence Tomography Measurements
Kriegel MF
Ocular Immunology and Inflammation 2019; 0: 1-7 (IGR: 20-4)

82768 Changes on Confocal Scanning Laser Ophthalmoscopy with the Heidelberg Retinal Tomography after a Cardiac Catheterism in a Patient with Progressive Glaucoma
Valera-Cornejo DA
Case Reports in Ophthalmology 2019; 10: 256-266 (IGR: 20-4)

82160 The ocular surface after successful glaucoma filtration surgery: a clinical, in vivo confocal microscopy, and immune-cytology study
Agnifili L
Scientific reports 2019; 9: 11299 (IGR: 20-4)

82716 Ab Externo Imaging of Human Episcleral Vessels Using Fiberoptic Confocal Laser Endomicroscopy
Y Lin K; Mosaed S
Journal of ophthalmic & vision research 2019; 14: 275-284 (IGR: 20-4)

82593 Influence of Inflammation in Uveitis on Confocal Scanning Laser Tomography and Optical Coherence Tomography Measurements
Heiligenhaus A
Ocular Immunology and Inflammation 2019; 0: 1-7 (IGR: 20-4)

82768 Changes on Confocal Scanning Laser Ophthalmoscopy with the Heidelberg Retinal Tomography after a Cardiac Catheterism in a Patient with Progressive Glaucoma
Loayza-Gamboa W
Case Reports in Ophthalmology 2019; 10: 256-266 (IGR: 20-4)

82160 The ocular surface after successful glaucoma filtration surgery: a clinical, in vivo confocal microscopy, and immune-cytology study
Brescia L; Oddone F
Scientific reports 2019; 9: 11299 (IGR: 20-4)

82593 Influence of Inflammation in Uveitis on Confocal Scanning Laser Tomography and Optical Coherence Tomography Measurements
Rothaus K
Ocular Immunology and Inflammation 2019; 0: 1-7 (IGR: 20-4)

82768 Changes on Confocal Scanning Laser Ophthalmoscopy with the Heidelberg Retinal Tomography after a Cardiac Catheterism in a Patient with Progressive Glaucoma
Herrera-Quiroz J
Case Reports in Ophthalmology 2019; 10: 256-266 (IGR: 20-4)

82593 Influence of Inflammation in Uveitis on Confocal Scanning Laser Tomography and Optical Coherence Tomography Measurements
Rothaus K
Ocular Immunology and Inflammation 2019; 0: 1-7 (IGR: 20-4)

82160 The ocular surface after successful glaucoma filtration surgery: a clinical, in vivo confocal microscopy, and immune-cytology study
Sacchi M
Scientific reports 2019; 9: 11299 (IGR: 20-4)

82768 Changes on Confocal Scanning Laser Ophthalmoscopy with the Heidelberg Retinal Tomography after a Cardiac Catheterism in a Patient with Progressive Glaucoma
Alvarado-Villacorta R
Case Reports in Ophthalmology 2019; 10: 256-266 (IGR: 20-4)

82593 Influence of Inflammation in Uveitis on Confocal Scanning Laser Tomography and Optical Coherence Tomography Measurements
Heinz C
Ocular Immunology and Inflammation 2019; 0: 1-7 (IGR: 20-4)

82768 Changes on Confocal Scanning Laser Ophthalmoscopy with the Heidelberg Retinal Tomography after a Cardiac Catheterism in a Patient with Progressive Glaucoma
Córdova-Crisanto L
Case Reports in Ophthalmology 2019; 10: 256-266 (IGR: 20-4)

82160 The ocular surface after successful glaucoma filtration surgery: a clinical, in vivo confocal microscopy, and immune-cytology study
D'Ugo E; Di Marzio G
Scientific reports 2019; 9: 11299 (IGR: 20-4)

82768 Changes on Confocal Scanning Laser Ophthalmoscopy with the Heidelberg Retinal Tomography after a Cardiac Catheterism in a Patient with Progressive Glaucoma
Valderrama-Albino V; Pantoja-Dávalos N
Case Reports in Ophthalmology 2019; 10: 256-266 (IGR: 20-4)

82160 The ocular surface after successful glaucoma filtration surgery: a clinical, in vivo confocal microscopy, and immune-cytology study
Perna F; Costagliola C; Mastropasqua R
Scientific reports 2019; 9: 11299 (IGR: 20-4)

80854 Comparison of Blue and Green Confocal Scanning Laser Ophthalmoscope Imaging to Detect Retinal Nerve Fiber Layer Defects
Joung JY; Lee WJ; Lee BR
Korean Journal of Ophthalmology 2019; 33: 131-137 (IGR: 20-3)

79930 Agreement study between color and IR retinal images based on retinal vasculature morphological parameters
Ajaz A; Aliahmad B; Kumar H; Sarossy M; Kumar DK
BMC Ophthalmology 2019; 19: 27 (IGR: 20-2)

78008 Diagnostic accuracy of macular ganglion cell-inner plexiform layer thickness for glaucoma detection in a population-based study: Comparison with optic nerve head imaging parameters
Koh V
PLoS ONE 2018; 13: e0199134 (IGR: 19-4)

78124 Scanning laser ophthalmoscopy in an elderly Indian population
Srinivasan G
Ophthalmic Epidemiology 2018; 25: 345-350 (IGR: 19-4)

77765 Deep-learning Classifier With an Ultrawide-field Scanning Laser Ophthalmoscope Detects Glaucoma Visual Field Severity
Masumoto H; Tabuchi H
Journal of Glaucoma 2018; 27: 647-652 (IGR: 19-4)

78124 Scanning laser ophthalmoscopy in an elderly Indian population
Murthy GVS
Ophthalmic Epidemiology 2018; 25: 345-350 (IGR: 19-4)

78008 Diagnostic accuracy of macular ganglion cell-inner plexiform layer thickness for glaucoma detection in a population-based study: Comparison with optic nerve head imaging parameters
Tham YC; Cheung CY
PLoS ONE 2018; 13: e0199134 (IGR: 19-4)

77765 Deep-learning Classifier With an Ultrawide-field Scanning Laser Ophthalmoscope Detects Glaucoma Visual Field Severity
Nakakura S
Journal of Glaucoma 2018; 27: 647-652 (IGR: 19-4)

78124 Scanning laser ophthalmoscopy in an elderly Indian population
Mohan S
Ophthalmic Epidemiology 2018; 25: 345-350 (IGR: 19-4)

77765 Deep-learning Classifier With an Ultrawide-field Scanning Laser Ophthalmoscope Detects Glaucoma Visual Field Severity
Ishitobi N
Journal of Glaucoma 2018; 27: 647-652 (IGR: 19-4)

78008 Diagnostic accuracy of macular ganglion cell-inner plexiform layer thickness for glaucoma detection in a population-based study: Comparison with optic nerve head imaging parameters
Mani B
PLoS ONE 2018; 13: e0199134 (IGR: 19-4)

78124 Scanning laser ophthalmoscopy in an elderly Indian population
Mani K; Vashist P
Ophthalmic Epidemiology 2018; 25: 345-350 (IGR: 19-4)

78008 Diagnostic accuracy of macular ganglion cell-inner plexiform layer thickness for glaucoma detection in a population-based study: Comparison with optic nerve head imaging parameters
Wong TY
PLoS ONE 2018; 13: e0199134 (IGR: 19-4)

77765 Deep-learning Classifier With an Ultrawide-field Scanning Laser Ophthalmoscope Detects Glaucoma Visual Field Severity
Miki M
Journal of Glaucoma 2018; 27: 647-652 (IGR: 19-4)

78124 Scanning laser ophthalmoscopy in an elderly Indian population
John N
Ophthalmic Epidemiology 2018; 25: 345-350 (IGR: 19-4)

77765 Deep-learning Classifier With an Ultrawide-field Scanning Laser Ophthalmoscope Detects Glaucoma Visual Field Severity
Enno H
Journal of Glaucoma 2018; 27: 647-652 (IGR: 19-4)

78008 Diagnostic accuracy of macular ganglion cell-inner plexiform layer thickness for glaucoma detection in a population-based study: Comparison with optic nerve head imaging parameters
Aung T
PLoS ONE 2018; 13: e0199134 (IGR: 19-4)

78124 Scanning laser ophthalmoscopy in an elderly Indian population
Gupta V
Ophthalmic Epidemiology 2018; 25: 345-350 (IGR: 19-4)

78008 Diagnostic accuracy of macular ganglion cell-inner plexiform layer thickness for glaucoma detection in a population-based study: Comparison with optic nerve head imaging parameters
Cheng CY
PLoS ONE 2018; 13: e0199134 (IGR: 19-4)

78124 Scanning laser ophthalmoscopy in an elderly Indian population
Sihota R
Ophthalmic Epidemiology 2018; 25: 345-350 (IGR: 19-4)

77260 Real-Time Imaging of Retinal Cell Apoptosis by Confocal Scanning Laser Ophthalmoscopy and Its Role in Glaucoma
Yang E
Frontiers in neurology 2018; 9: 338 (IGR: 19-3)

76191 Secondary glaucoma in uveitis: comparison of the optic nerve head morphology among a nonmydriatic fundus camera, HRT, and SD-OCT
Pahlitzsch M
European Journal of Ophthalmology 2018; 28: 299-305 (IGR: 19-3)

76779 Evaluation of two-dimensional Bruch's membrane opening minimum rim area for glaucoma diagnostics in a large patient cohort
Enders P
Acta Ophthalmologica 2018; 0: (IGR: 19-3)

76191 Secondary glaucoma in uveitis: comparison of the optic nerve head morphology among a nonmydriatic fundus camera, HRT, and SD-OCT
Klamann MKJ
European Journal of Ophthalmology 2018; 28: 299-305 (IGR: 19-3)

77260 Real-Time Imaging of Retinal Cell Apoptosis by Confocal Scanning Laser Ophthalmoscopy and Its Role in Glaucoma
Al-Mugheiry TS
Frontiers in neurology 2018; 9: 338 (IGR: 19-3)

76779 Evaluation of two-dimensional Bruch's membrane opening minimum rim area for glaucoma diagnostics in a large patient cohort
Adler W; Kiessling D
Acta Ophthalmologica 2018; 0: (IGR: 19-3)

77260 Real-Time Imaging of Retinal Cell Apoptosis by Confocal Scanning Laser Ophthalmoscopy and Its Role in Glaucoma
Normando EM
Frontiers in neurology 2018; 9: 338 (IGR: 19-3)

76191 Secondary glaucoma in uveitis: comparison of the optic nerve head morphology among a nonmydriatic fundus camera, HRT, and SD-OCT
Jacob S
European Journal of Ophthalmology 2018; 28: 299-305 (IGR: 19-3)

77260 Real-Time Imaging of Retinal Cell Apoptosis by Confocal Scanning Laser Ophthalmoscopy and Its Role in Glaucoma
Cordeiro MF
Frontiers in neurology 2018; 9: 338 (IGR: 19-3)

76191 Secondary glaucoma in uveitis: comparison of the optic nerve head morphology among a nonmydriatic fundus camera, HRT, and SD-OCT
Erb C
European Journal of Ophthalmology 2018; 28: 299-305 (IGR: 19-3)

76779 Evaluation of two-dimensional Bruch's membrane opening minimum rim area for glaucoma diagnostics in a large patient cohort
Weber V; Schaub F
Acta Ophthalmologica 2018; 0: (IGR: 19-3)

76191 Secondary glaucoma in uveitis: comparison of the optic nerve head morphology among a nonmydriatic fundus camera, HRT, and SD-OCT
Winterhalter S; Torun N
European Journal of Ophthalmology 2018; 28: 299-305 (IGR: 19-3)

76779 Evaluation of two-dimensional Bruch's membrane opening minimum rim area for glaucoma diagnostics in a large patient cohort
Hermann MM
Acta Ophthalmologica 2018; 0: (IGR: 19-3)

76191 Secondary glaucoma in uveitis: comparison of the optic nerve head morphology among a nonmydriatic fundus camera, HRT, and SD-OCT
Maier AB
European Journal of Ophthalmology 2018; 28: 299-305 (IGR: 19-3)

76779 Evaluation of two-dimensional Bruch's membrane opening minimum rim area for glaucoma diagnostics in a large patient cohort
Dietlein T; Cursiefen C
Acta Ophthalmologica 2018; 0: (IGR: 19-3)

76191 Secondary glaucoma in uveitis: comparison of the optic nerve head morphology among a nonmydriatic fundus camera, HRT, and SD-OCT
Bertelmann E
European Journal of Ophthalmology 2018; 28: 299-305 (IGR: 19-3)

76779 Evaluation of two-dimensional Bruch's membrane opening minimum rim area for glaucoma diagnostics in a large patient cohort
Heindl LM
Acta Ophthalmologica 2018; 0: (IGR: 19-3)

74313 Variations in optic nerve head morphology by intraocular pressure in open-angle glaucoma
Wong A
Graefe's Archive for Clinical and Experimental Ophthalmology 2017; 255: 2219-2226 (IGR: 19-1)

74564 Spontaneous Retinal Venous Pulsation in Unilateral Primary Open-angle Glaucoma With Low Intraocular Pressure
Lee E
Journal of Glaucoma 2017; 26: 896-901 (IGR: 19-1)

74743 Three-dimensional Laser Scanning Confocal Analysis of Conjunctival Microcysts in Glaucomatous Patients Before and After Trabeculectomy
Di Staso S
In vivo (Athens, Greece) 2017; 31: 1081-1088 (IGR: 19-1)

74791 Relationship between anterior segment and optic nerve head parameters in healthy subjects
Cankaya AB
Arquivos Brasileiros de Oftalmologia 2017; 80: 285-289 (IGR: 19-1)

74274 Association of intraocular pressure-related factors and retinal vessel diameter with optic disc rim area in subjects with and without primary open angle glaucoma
Zhang Q
Clinical and Experimental Ophthalmology 2018; 46: 389-399 (IGR: 19-1)

74743 Three-dimensional Laser Scanning Confocal Analysis of Conjunctival Microcysts in Glaucomatous Patients Before and After Trabeculectomy
Agnifili L
In vivo (Athens, Greece) 2017; 31: 1081-1088 (IGR: 19-1)

74791 Relationship between anterior segment and optic nerve head parameters in healthy subjects
Ozates S
Arquivos Brasileiros de Oftalmologia 2017; 80: 285-289 (IGR: 19-1)

74274 Association of intraocular pressure-related factors and retinal vessel diameter with optic disc rim area in subjects with and without primary open angle glaucoma
Jan C
Clinical and Experimental Ophthalmology 2018; 46: 389-399 (IGR: 19-1)

74313 Variations in optic nerve head morphology by intraocular pressure in open-angle glaucoma
Matheos K
Graefe's Archive for Clinical and Experimental Ophthalmology 2017; 255: 2219-2226 (IGR: 19-1)

74564 Spontaneous Retinal Venous Pulsation in Unilateral Primary Open-angle Glaucoma With Low Intraocular Pressure
Kim TW; Kim JA
Journal of Glaucoma 2017; 26: 896-901 (IGR: 19-1)

74743 Three-dimensional Laser Scanning Confocal Analysis of Conjunctival Microcysts in Glaucomatous Patients Before and After Trabeculectomy
DI Gregorio A
In vivo (Athens, Greece) 2017; 31: 1081-1088 (IGR: 19-1)

74274 Association of intraocular pressure-related factors and retinal vessel diameter with optic disc rim area in subjects with and without primary open angle glaucoma
Guo CY
Clinical and Experimental Ophthalmology 2018; 46: 389-399 (IGR: 19-1)

74313 Variations in optic nerve head morphology by intraocular pressure in open-angle glaucoma
Prime Z
Graefe's Archive for Clinical and Experimental Ophthalmology 2017; 255: 2219-2226 (IGR: 19-1)

74274 Association of intraocular pressure-related factors and retinal vessel diameter with optic disc rim area in subjects with and without primary open angle glaucoma
Wang FH
Clinical and Experimental Ophthalmology 2018; 46: 389-399 (IGR: 19-1)

74313 Variations in optic nerve head morphology by intraocular pressure in open-angle glaucoma
Danesh-Meyer HV
Graefe's Archive for Clinical and Experimental Ophthalmology 2017; 255: 2219-2226 (IGR: 19-1)

74743 Three-dimensional Laser Scanning Confocal Analysis of Conjunctival Microcysts in Glaucomatous Patients Before and After Trabeculectomy
Climastone H
In vivo (Athens, Greece) 2017; 31: 1081-1088 (IGR: 19-1)

74274 Association of intraocular pressure-related factors and retinal vessel diameter with optic disc rim area in subjects with and without primary open angle glaucoma
Liang YB
Clinical and Experimental Ophthalmology 2018; 46: 389-399 (IGR: 19-1)

74564 Spontaneous Retinal Venous Pulsation in Unilateral Primary Open-angle Glaucoma With Low Intraocular Pressure
Kim H
Journal of Glaucoma 2017; 26: 896-901 (IGR: 19-1)

74743 Three-dimensional Laser Scanning Confocal Analysis of Conjunctival Microcysts in Glaucomatous Patients Before and After Trabeculectomy
Galassi E; Fasanella V
In vivo (Athens, Greece) 2017; 31: 1081-1088 (IGR: 19-1)

74274 Association of intraocular pressure-related factors and retinal vessel diameter with optic disc rim area in subjects with and without primary open angle glaucoma
Cao K; Zhang Z
Clinical and Experimental Ophthalmology 2018; 46: 389-399 (IGR: 19-1)

74743 Three-dimensional Laser Scanning Confocal Analysis of Conjunctival Microcysts in Glaucomatous Patients Before and After Trabeculectomy
Ciancaglini M
In vivo (Athens, Greece) 2017; 31: 1081-1088 (IGR: 19-1)

74274 Association of intraocular pressure-related factors and retinal vessel diameter with optic disc rim area in subjects with and without primary open angle glaucoma
Yang DY; Thomas R; Wang NL;
Clinical and Experimental Ophthalmology 2018; 46: 389-399 (IGR: 19-1)

73464 Progression of Local Glaucomatous Damage Near Fixation as Seen with Adaptive Optics Imaging
Hood DC
Translational vision science & technology 2017; 6: 6 (IGR: 18-4)

72820 Reflectance Spectrum and Birefringence of the Retinal Nerve Fiber Layer With Hypertensive Damage of Axonal Cytoskeleton
Huang XR
Investigative Ophthalmology and Visual Science 2017; 58: 2118-2129 (IGR: 18-4)

72838 Comparison of Ethnic-specific Databases in Heidelberg Retina Tomography-3 to Discriminate Between Early Glaucoma and Normal Chinese Eyes
Tan XL
Open Ophthalmology Journal 2017; 11: 40-46 (IGR: 18-4)

72843 Nasalised distribution of peripapillary retinal nerve fibre layers in large discs
Lee EJ
British Journal of Ophthalmology 2017; 101: 1643-1648 (IGR: 18-4)

72820 Reflectance Spectrum and Birefringence of the Retinal Nerve Fiber Layer With Hypertensive Damage of Axonal Cytoskeleton
Knighton RW
Investigative Ophthalmology and Visual Science 2017; 58: 2118-2129 (IGR: 18-4)

72843 Nasalised distribution of peripapillary retinal nerve fibre layers in large discs
Han JC
British Journal of Ophthalmology 2017; 101: 1643-1648 (IGR: 18-4)

73464 Progression of Local Glaucomatous Damage Near Fixation as Seen with Adaptive Optics Imaging
Lee D
Translational vision science & technology 2017; 6: 6 (IGR: 18-4)

72838 Comparison of Ethnic-specific Databases in Heidelberg Retina Tomography-3 to Discriminate Between Early Glaucoma and Normal Chinese Eyes
Yap SC
Open Ophthalmology Journal 2017; 11: 40-46 (IGR: 18-4)

72820 Reflectance Spectrum and Birefringence of the Retinal Nerve Fiber Layer With Hypertensive Damage of Axonal Cytoskeleton
Spector YZ
Investigative Ophthalmology and Visual Science 2017; 58: 2118-2129 (IGR: 18-4)

72843 Nasalised distribution of peripapillary retinal nerve fibre layers in large discs
Kee C
British Journal of Ophthalmology 2017; 101: 1643-1648 (IGR: 18-4)

73464 Progression of Local Glaucomatous Damage Near Fixation as Seen with Adaptive Optics Imaging
Jarukasetphon R
Translational vision science & technology 2017; 6: 6 (IGR: 18-4)

72838 Comparison of Ethnic-specific Databases in Heidelberg Retina Tomography-3 to Discriminate Between Early Glaucoma and Normal Chinese Eyes
Li X; Yip LW
Open Ophthalmology Journal 2017; 11: 40-46 (IGR: 18-4)

72820 Reflectance Spectrum and Birefringence of the Retinal Nerve Fiber Layer With Hypertensive Damage of Axonal Cytoskeleton
Qiao J
Investigative Ophthalmology and Visual Science 2017; 58: 2118-2129 (IGR: 18-4)

73464 Progression of Local Glaucomatous Damage Near Fixation as Seen with Adaptive Optics Imaging
Nunez J
Translational vision science & technology 2017; 6: 6 (IGR: 18-4)

72820 Reflectance Spectrum and Birefringence of the Retinal Nerve Fiber Layer With Hypertensive Damage of Axonal Cytoskeleton
Kong W
Investigative Ophthalmology and Visual Science 2017; 58: 2118-2129 (IGR: 18-4)

73464 Progression of Local Glaucomatous Damage Near Fixation as Seen with Adaptive Optics Imaging
Mavrommatis MA; Rosen RB
Translational vision science & technology 2017; 6: 6 (IGR: 18-4)

72820 Reflectance Spectrum and Birefringence of the Retinal Nerve Fiber Layer With Hypertensive Damage of Axonal Cytoskeleton
Zhao Q
Investigative Ophthalmology and Visual Science 2017; 58: 2118-2129 (IGR: 18-4)

73464 Progression of Local Glaucomatous Damage Near Fixation as Seen with Adaptive Optics Imaging
Ritch R; Dubra A; Chui TYP
Translational vision science & technology 2017; 6: 6 (IGR: 18-4)

71340 Can Glaucomatous Visual Field Progression be Predicted by Structural and Functional Measures?
Schrems WA
Journal of Glaucoma 2017; 26: 373-382 (IGR: 18-3)

71389 A New Glaucoma Severity Score Combining Structural and Functional Defects
Wachtl J
Klinische Monatsblätter für Augenheilkunde 2017; 234: 468-473 (IGR: 18-3)

71298 Diagnostic Accuracy of Imaging Devices in Glaucoma: A Meta-Analysis
Fallon M
Survey of Ophthalmology 2017; 62: 446-461 (IGR: 18-3)

71445 Transient Peripapillary Retinoschisis in Glaucomatous Eyes
van der Schoot J
Journal of Ophthalmology 2017; 2017: 1536030 (IGR: 18-3)

71389 A New Glaucoma Severity Score Combining Structural and Functional Defects
Töteberg-Harms M
Klinische Monatsblätter für Augenheilkunde 2017; 234: 468-473 (IGR: 18-3)

71445 Transient Peripapillary Retinoschisis in Glaucomatous Eyes
Vermeer KA
Journal of Ophthalmology 2017; 2017: 1536030 (IGR: 18-3)

71298 Diagnostic Accuracy of Imaging Devices in Glaucoma: A Meta-Analysis
Valero O
Survey of Ophthalmology 2017; 62: 446-461 (IGR: 18-3)

71340 Can Glaucomatous Visual Field Progression be Predicted by Structural and Functional Measures?
Schrems-Hoesl LM
Journal of Glaucoma 2017; 26: 373-382 (IGR: 18-3)

71445 Transient Peripapillary Retinoschisis in Glaucomatous Eyes
Lemij HG
Journal of Ophthalmology 2017; 2017: 1536030 (IGR: 18-3)

71298 Diagnostic Accuracy of Imaging Devices in Glaucoma: A Meta-Analysis
Pazos M
Survey of Ophthalmology 2017; 62: 446-461 (IGR: 18-3)

71340 Can Glaucomatous Visual Field Progression be Predicted by Structural and Functional Measures?
Mardin CY
Journal of Glaucoma 2017; 26: 373-382 (IGR: 18-3)

71389 A New Glaucoma Severity Score Combining Structural and Functional Defects
Frimmel S
Klinische Monatsblätter für Augenheilkunde 2017; 234: 468-473 (IGR: 18-3)

71298 Diagnostic Accuracy of Imaging Devices in Glaucoma: A Meta-Analysis
Antón A
Survey of Ophthalmology 2017; 62: 446-461 (IGR: 18-3)

71389 A New Glaucoma Severity Score Combining Structural and Functional Defects
Kniestedt C
Klinische Monatsblätter für Augenheilkunde 2017; 234: 468-473 (IGR: 18-3)

71340 Can Glaucomatous Visual Field Progression be Predicted by Structural and Functional Measures?
Laemmer R; Kruse FE; Horn FK
Journal of Glaucoma 2017; 26: 373-382 (IGR: 18-3)

70087 Reductions in Retrobulbar and Retinal Capillary Blood Flow Strongly Correlate With Changes in Optic Nerve Head and Retinal Morphology Over 4 Years in Open-angle Glaucoma Patients of African Descent Compared With Patients of European Descent
Siesky B
Journal of Glaucoma 2016; 25: 750-757 (IGR: 18-2)

70703 Relationship between Psychophysical Measures of Retinal Ganglion Cell Density and In Vivo Measures of Cone Density in Glaucoma
Matlach J
Ophthalmology 2017; 124: 310-319 (IGR: 18-2)

70224 Bruch's Membrane Opening-Minimum Rim Width Assessment With Spectral-Domain Optical Coherence Tomography Performs Better Than Confocal Scanning Laser Ophthalmoscopy in Discriminating Early Glaucoma Patients From Control Subjects
Toshev AP
Journal of Glaucoma 2017; 26: 27-33 (IGR: 18-2)

70172 Reproducibility of optic disk evaluation in supine subjects with a Heidelberg Retina Tomograph II laser tomographic scanner
Harada Y
Clinical Ophthalmology 2016; 10: 1617-1622 (IGR: 18-2)

70365 Comparison of Heidelberg Retina Tomograph-3 glaucoma probability score and Moorfields regression analysis of optic nerve head in glaucoma patients and healthy individuals
Caglar Ç
Graefe's Archive for Clinical and Experimental Ophthalmology 2017; 255: 153-161 (IGR: 18-2)

70499 In Vivo Distribution of Corneal Epithelial Dendritic Cells in Patients With Glaucoma
Mastropasqua R
Investigative Ophthalmology and Visual Science 2016; 57: 5996-6002 (IGR: 18-2)

70384 Anterior segment configuration as a predictive factor for refractive outcome after cataract surgery in patients with glaucoma
Kim YC
BMC Ophthalmology 2016; 16: 179 (IGR: 18-2)

70431 Predictive Value of HRT Stereometric Parameters and Blue-on-Yellow Perimetry Global Indices in Glaucoma-suspected Subjects
Rallis K
Journal of Glaucoma 2016; 25: 931-938 (IGR: 18-2)

70712 Ocular characteristics associated with the location of focal lamina cribrosa defects in open-angle glaucoma patients
Park HY
Eye 2017; 31: 578-587 (IGR: 18-2)

70095 Cone Integrity in Glaucoma: An Adaptive-Optics Scanning Laser Ophthalmoscopy Study
Hasegawa T
American Journal of Ophthalmology 2016; 171: 53-66 (IGR: 18-2)

69934 Funduscopic versus HRT III Confocal Scanner Vertical Cup-Disc Ratio Assessment in Normal Tension and Primary Open Angle Glaucoma (The Leuven Eye Study)
Willekens K
Ophthalmic Research 2017; 57: 100-106 (IGR: 18-2)

70095 Cone Integrity in Glaucoma: An Adaptive-Optics Scanning Laser Ophthalmoscopy Study
Ooto S
American Journal of Ophthalmology 2016; 171: 53-66 (IGR: 18-2)

70499 In Vivo Distribution of Corneal Epithelial Dendritic Cells in Patients With Glaucoma
Agnifili L
Investigative Ophthalmology and Visual Science 2016; 57: 5996-6002 (IGR: 18-2)

70431 Predictive Value of HRT Stereometric Parameters and Blue-on-Yellow Perimetry Global Indices in Glaucoma-suspected Subjects
Kymionis GD
Journal of Glaucoma 2016; 25: 931-938 (IGR: 18-2)

69934 Funduscopic versus HRT III Confocal Scanner Vertical Cup-Disc Ratio Assessment in Normal Tension and Primary Open Angle Glaucoma (The Leuven Eye Study)
Bataillie S
Ophthalmic Research 2017; 57: 100-106 (IGR: 18-2)

70087 Reductions in Retrobulbar and Retinal Capillary Blood Flow Strongly Correlate With Changes in Optic Nerve Head and Retinal Morphology Over 4 Years in Open-angle Glaucoma Patients of African Descent Compared With Patients of European Descent
Harris A
Journal of Glaucoma 2016; 25: 750-757 (IGR: 18-2)

70224 Bruch's Membrane Opening-Minimum Rim Width Assessment With Spectral-Domain Optical Coherence Tomography Performs Better Than Confocal Scanning Laser Ophthalmoscopy in Discriminating Early Glaucoma Patients From Control Subjects
Lamparter J
Journal of Glaucoma 2017; 26: 27-33 (IGR: 18-2)

70384 Anterior segment configuration as a predictive factor for refractive outcome after cataract surgery in patients with glaucoma
Sung MS
BMC Ophthalmology 2016; 16: 179 (IGR: 18-2)

70172 Reproducibility of optic disk evaluation in supine subjects with a Heidelberg Retina Tomograph II laser tomographic scanner
Akita T
Clinical Ophthalmology 2016; 10: 1617-1622 (IGR: 18-2)

70703 Relationship between Psychophysical Measures of Retinal Ganglion Cell Density and In Vivo Measures of Cone Density in Glaucoma
Mulholland PJ
Ophthalmology 2017; 124: 310-319 (IGR: 18-2)

70712 Ocular characteristics associated with the location of focal lamina cribrosa defects in open-angle glaucoma patients
Hwang YS
Eye 2017; 31: 578-587 (IGR: 18-2)

70365 Comparison of Heidelberg Retina Tomograph-3 glaucoma probability score and Moorfields regression analysis of optic nerve head in glaucoma patients and healthy individuals
Gul A
Graefe's Archive for Clinical and Experimental Ophthalmology 2017; 255: 153-161 (IGR: 18-2)

70703 Relationship between Psychophysical Measures of Retinal Ganglion Cell Density and In Vivo Measures of Cone Density in Glaucoma
Cilkova M
Ophthalmology 2017; 124: 310-319 (IGR: 18-2)

70712 Ocular characteristics associated with the location of focal lamina cribrosa defects in open-angle glaucoma patients
Park CK
Eye 2017; 31: 578-587 (IGR: 18-2)

70431 Predictive Value of HRT Stereometric Parameters and Blue-on-Yellow Perimetry Global Indices in Glaucoma-suspected Subjects
Georgalas I
Journal of Glaucoma 2016; 25: 931-938 (IGR: 18-2)

70172 Reproducibility of optic disk evaluation in supine subjects with a Heidelberg Retina Tomograph II laser tomographic scanner
Takenaka J
Clinical Ophthalmology 2016; 10: 1617-1622 (IGR: 18-2)

70087 Reductions in Retrobulbar and Retinal Capillary Blood Flow Strongly Correlate With Changes in Optic Nerve Head and Retinal Morphology Over 4 Years in Open-angle Glaucoma Patients of African Descent Compared With Patients of European Descent
Carr J
Journal of Glaucoma 2016; 25: 750-757 (IGR: 18-2)

70365 Comparison of Heidelberg Retina Tomograph-3 glaucoma probability score and Moorfields regression analysis of optic nerve head in glaucoma patients and healthy individuals
Batur M
Graefe's Archive for Clinical and Experimental Ophthalmology 2017; 255: 153-161 (IGR: 18-2)

70384 Anterior segment configuration as a predictive factor for refractive outcome after cataract surgery in patients with glaucoma
Heo H
BMC Ophthalmology 2016; 16: 179 (IGR: 18-2)

69934 Funduscopic versus HRT III Confocal Scanner Vertical Cup-Disc Ratio Assessment in Normal Tension and Primary Open Angle Glaucoma (The Leuven Eye Study)
Sarens I
Ophthalmic Research 2017; 57: 100-106 (IGR: 18-2)

70224 Bruch's Membrane Opening-Minimum Rim Width Assessment With Spectral-Domain Optical Coherence Tomography Performs Better Than Confocal Scanning Laser Ophthalmoscopy in Discriminating Early Glaucoma Patients From Control Subjects
Pfeiffer N
Journal of Glaucoma 2017; 26: 27-33 (IGR: 18-2)

70095 Cone Integrity in Glaucoma: An Adaptive-Optics Scanning Laser Ophthalmoscopy Study
Takayama K
American Journal of Ophthalmology 2016; 171: 53-66 (IGR: 18-2)

70499 In Vivo Distribution of Corneal Epithelial Dendritic Cells in Patients With Glaucoma
Fasanella V
Investigative Ophthalmology and Visual Science 2016; 57: 5996-6002 (IGR: 18-2)

69934 Funduscopic versus HRT III Confocal Scanner Vertical Cup-Disc Ratio Assessment in Normal Tension and Primary Open Angle Glaucoma (The Leuven Eye Study)
Odent S
Ophthalmic Research 2017; 57: 100-106 (IGR: 18-2)

70224 Bruch's Membrane Opening-Minimum Rim Width Assessment With Spectral-Domain Optical Coherence Tomography Performs Better Than Confocal Scanning Laser Ophthalmoscopy in Discriminating Early Glaucoma Patients From Control Subjects
Hoffmann EM
Journal of Glaucoma 2017; 26: 27-33 (IGR: 18-2)

70172 Reproducibility of optic disk evaluation in supine subjects with a Heidelberg Retina Tomograph II laser tomographic scanner
Nakamura-Kadohiro Y
Clinical Ophthalmology 2016; 10: 1617-1622 (IGR: 18-2)

70095 Cone Integrity in Glaucoma: An Adaptive-Optics Scanning Laser Ophthalmoscopy Study
Makiyama Y
American Journal of Ophthalmology 2016; 171: 53-66 (IGR: 18-2)

70087 Reductions in Retrobulbar and Retinal Capillary Blood Flow Strongly Correlate With Changes in Optic Nerve Head and Retinal Morphology Over 4 Years in Open-angle Glaucoma Patients of African Descent Compared With Patients of European Descent
Verticchio Vercellin A
Journal of Glaucoma 2016; 25: 750-757 (IGR: 18-2)

70499 In Vivo Distribution of Corneal Epithelial Dendritic Cells in Patients With Glaucoma
Lappa A
Investigative Ophthalmology and Visual Science 2016; 57: 5996-6002 (IGR: 18-2)

70431 Predictive Value of HRT Stereometric Parameters and Blue-on-Yellow Perimetry Global Indices in Glaucoma-suspected Subjects
Moschos MM
Journal of Glaucoma 2016; 25: 931-938 (IGR: 18-2)

70703 Relationship between Psychophysical Measures of Retinal Ganglion Cell Density and In Vivo Measures of Cone Density in Glaucoma
Chopra R
Ophthalmology 2017; 124: 310-319 (IGR: 18-2)

70365 Comparison of Heidelberg Retina Tomograph-3 glaucoma probability score and Moorfields regression analysis of optic nerve head in glaucoma patients and healthy individuals
Yasar T
Graefe's Archive for Clinical and Experimental Ophthalmology 2017; 255: 153-161 (IGR: 18-2)

70384 Anterior segment configuration as a predictive factor for refractive outcome after cataract surgery in patients with glaucoma
Park SW
BMC Ophthalmology 2016; 16: 179 (IGR: 18-2)

70172 Reproducibility of optic disk evaluation in supine subjects with a Heidelberg Retina Tomograph II laser tomographic scanner
Tanaka J
Clinical Ophthalmology 2016; 10: 1617-1622 (IGR: 18-2)

70431 Predictive Value of HRT Stereometric Parameters and Blue-on-Yellow Perimetry Global Indices in Glaucoma-suspected Subjects
Koutsandrea C
Journal of Glaucoma 2016; 25: 931-938 (IGR: 18-2)

69934 Funduscopic versus HRT III Confocal Scanner Vertical Cup-Disc Ratio Assessment in Normal Tension and Primary Open Angle Glaucoma (The Leuven Eye Study)
Abegão Pinto L
Ophthalmic Research 2017; 57: 100-106 (IGR: 18-2)

70095 Cone Integrity in Glaucoma: An Adaptive-Optics Scanning Laser Ophthalmoscopy Study
Akagi T
American Journal of Ophthalmology 2016; 171: 53-66 (IGR: 18-2)

70087 Reductions in Retrobulbar and Retinal Capillary Blood Flow Strongly Correlate With Changes in Optic Nerve Head and Retinal Morphology Over 4 Years in Open-angle Glaucoma Patients of African Descent Compared With Patients of European Descent
Hussain RM
Journal of Glaucoma 2016; 25: 750-757 (IGR: 18-2)

70703 Relationship between Psychophysical Measures of Retinal Ganglion Cell Density and In Vivo Measures of Cone Density in Glaucoma
Shah N
Ophthalmology 2017; 124: 310-319 (IGR: 18-2)

70499 In Vivo Distribution of Corneal Epithelial Dendritic Cells in Patients With Glaucoma
Brescia L
Investigative Ophthalmology and Visual Science 2016; 57: 5996-6002 (IGR: 18-2)

70703 Relationship between Psychophysical Measures of Retinal Ganglion Cell Density and In Vivo Measures of Cone Density in Glaucoma
Redmond T
Ophthalmology 2017; 124: 310-319 (IGR: 18-2)

70499 In Vivo Distribution of Corneal Epithelial Dendritic Cells in Patients With Glaucoma
Lanzini M
Investigative Ophthalmology and Visual Science 2016; 57: 5996-6002 (IGR: 18-2)

69934 Funduscopic versus HRT III Confocal Scanner Vertical Cup-Disc Ratio Assessment in Normal Tension and Primary Open Angle Glaucoma (The Leuven Eye Study)
Vandewalle E
Ophthalmic Research 2017; 57: 100-106 (IGR: 18-2)

70095 Cone Integrity in Glaucoma: An Adaptive-Optics Scanning Laser Ophthalmoscopy Study
Ikeda HO
American Journal of Ophthalmology 2016; 171: 53-66 (IGR: 18-2)

70431 Predictive Value of HRT Stereometric Parameters and Blue-on-Yellow Perimetry Global Indices in Glaucoma-suspected Subjects
Grentzelos MA
Journal of Glaucoma 2016; 25: 931-938 (IGR: 18-2)

70172 Reproducibility of optic disk evaluation in supine subjects with a Heidelberg Retina Tomograph II laser tomographic scanner
Kiuchi Y
Clinical Ophthalmology 2016; 10: 1617-1622 (IGR: 18-2)

70087 Reductions in Retrobulbar and Retinal Capillary Blood Flow Strongly Correlate With Changes in Optic Nerve Head and Retinal Morphology Over 4 Years in Open-angle Glaucoma Patients of African Descent Compared With Patients of European Descent
Parekh Hembree P
Journal of Glaucoma 2016; 25: 750-757 (IGR: 18-2)

70095 Cone Integrity in Glaucoma: An Adaptive-Optics Scanning Laser Ophthalmoscopy Study
Nakanishi H
American Journal of Ophthalmology 2016; 171: 53-66 (IGR: 18-2)

70431 Predictive Value of HRT Stereometric Parameters and Blue-on-Yellow Perimetry Global Indices in Glaucoma-suspected Subjects
Papaconstantinou D
Journal of Glaucoma 2016; 25: 931-938 (IGR: 18-2)

70703 Relationship between Psychophysical Measures of Retinal Ganglion Cell Density and In Vivo Measures of Cone Density in Glaucoma
Dakin SC
Ophthalmology 2017; 124: 310-319 (IGR: 18-2)

69934 Funduscopic versus HRT III Confocal Scanner Vertical Cup-Disc Ratio Assessment in Normal Tension and Primary Open Angle Glaucoma (The Leuven Eye Study)
Van Keer K
Ophthalmic Research 2017; 57: 100-106 (IGR: 18-2)

70499 In Vivo Distribution of Corneal Epithelial Dendritic Cells in Patients With Glaucoma
Oddone F
Investigative Ophthalmology and Visual Science 2016; 57: 5996-6002 (IGR: 18-2)

70087 Reductions in Retrobulbar and Retinal Capillary Blood Flow Strongly Correlate With Changes in Optic Nerve Head and Retinal Morphology Over 4 Years in Open-angle Glaucoma Patients of African Descent Compared With Patients of European Descent
Wentz S
Journal of Glaucoma 2016; 25: 750-757 (IGR: 18-2)

70703 Relationship between Psychophysical Measures of Retinal Ganglion Cell Density and In Vivo Measures of Cone Density in Glaucoma
Garway-Heath DF
Ophthalmology 2017; 124: 310-319 (IGR: 18-2)

70087 Reductions in Retrobulbar and Retinal Capillary Blood Flow Strongly Correlate With Changes in Optic Nerve Head and Retinal Morphology Over 4 Years in Open-angle Glaucoma Patients of African Descent Compared With Patients of European Descent
Isaacs M
Journal of Glaucoma 2016; 25: 750-757 (IGR: 18-2)

70095 Cone Integrity in Glaucoma: An Adaptive-Optics Scanning Laser Ophthalmoscopy Study
Suda K
American Journal of Ophthalmology 2016; 171: 53-66 (IGR: 18-2)

70499 In Vivo Distribution of Corneal Epithelial Dendritic Cells in Patients With Glaucoma
Perri P
Investigative Ophthalmology and Visual Science 2016; 57: 5996-6002 (IGR: 18-2)

69934 Funduscopic versus HRT III Confocal Scanner Vertical Cup-Disc Ratio Assessment in Normal Tension and Primary Open Angle Glaucoma (The Leuven Eye Study)
Stalmans I
Ophthalmic Research 2017; 57: 100-106 (IGR: 18-2)

70499 In Vivo Distribution of Corneal Epithelial Dendritic Cells in Patients With Glaucoma
Mastropasqua L
Investigative Ophthalmology and Visual Science 2016; 57: 5996-6002 (IGR: 18-2)

70095 Cone Integrity in Glaucoma: An Adaptive-Optics Scanning Laser Ophthalmoscopy Study
Yamada H
American Journal of Ophthalmology 2016; 171: 53-66 (IGR: 18-2)

70703 Relationship between Psychophysical Measures of Retinal Ganglion Cell Density and In Vivo Measures of Cone Density in Glaucoma
Anderson RS
Ophthalmology 2017; 124: 310-319 (IGR: 18-2)

70087 Reductions in Retrobulbar and Retinal Capillary Blood Flow Strongly Correlate With Changes in Optic Nerve Head and Retinal Morphology Over 4 Years in Open-angle Glaucoma Patients of African Descent Compared With Patients of European Descent
Eckert G; Moore NA
Journal of Glaucoma 2016; 25: 750-757 (IGR: 18-2)

70095 Cone Integrity in Glaucoma: An Adaptive-Optics Scanning Laser Ophthalmoscopy Study
Uji A; Yoshimura N
American Journal of Ophthalmology 2016; 171: 53-66 (IGR: 18-2)

69473 Summary of Glaucoma Diagnostic Testing Accuracy: An Evidence-Based Meta-Analysis
Ahmed S
Journal of clinical medicine research 2016; 8: 641-649 (IGR: 18-1)

69048 Variance components in confocal scanning laser tomography measurements of neuro-retinal rim area and the effect of repeated measurements on the power to detect loss over time
Sandberg Melin C
Acta Ophthalmologica 2016; 94: 705-711 (IGR: 18-1)

69434 Repeatability of Heidelberg Retinal Tomography 3 and effect of alignment algorithm on glaucoma suspects
Yoshioka N; Wong E
Clinical and Experimental Optometry 2017; 100: 41-48 (IGR: 18-1)

69473 Summary of Glaucoma Diagnostic Testing Accuracy: An Evidence-Based Meta-Analysis
Khan Z
Journal of clinical medicine research 2016; 8: 641-649 (IGR: 18-1)

69048 Variance components in confocal scanning laser tomography measurements of neuro-retinal rim area and the effect of repeated measurements on the power to detect loss over time
Nuija E; Alm A
Acta Ophthalmologica 2016; 94: 705-711 (IGR: 18-1)

69473 Summary of Glaucoma Diagnostic Testing Accuracy: An Evidence-Based Meta-Analysis
Si F
Journal of clinical medicine research 2016; 8: 641-649 (IGR: 18-1)

69434 Repeatability of Heidelberg Retinal Tomography 3 and effect of alignment algorithm on glaucoma suspects
Kalloniatis M; Zangerl B
Clinical and Experimental Optometry 2017; 100: 41-48 (IGR: 18-1)

69048 Variance components in confocal scanning laser tomography measurements of neuro-retinal rim area and the effect of repeated measurements on the power to detect loss over time
Yu Z
Acta Ophthalmologica 2016; 94: 705-711 (IGR: 18-1)

69473 Summary of Glaucoma Diagnostic Testing Accuracy: An Evidence-Based Meta-Analysis
Mao A
Journal of clinical medicine research 2016; 8: 641-649 (IGR: 18-1)

69048 Variance components in confocal scanning laser tomography measurements of neuro-retinal rim area and the effect of repeated measurements on the power to detect loss over time
Söderberg PG
Acta Ophthalmologica 2016; 94: 705-711 (IGR: 18-1)

69473 Summary of Glaucoma Diagnostic Testing Accuracy: An Evidence-Based Meta-Analysis
Pan I; Yazdi F; Tsertsvadze A; Hutnik C; Moher D; Tingey D; Trope GE; Damji KF; Tarride JE; Goeree R; Hodge W
Journal of clinical medicine research 2016; 8: 641-649 (IGR: 18-1)

67544 Regional Image Features Model for Automatic Classification between Normal and Glaucoma in Fundus and Scanning Laser Ophthalmoscopy (SLO) Images
Haleem MS
Journal of Medical Systems 2016; 40: 132 (IGR: 17-4)

67243 Diagnostic Accuracy of Optical Coherence Tomography and Scanning Laser Tomography for Identifying Glaucoma in Myopic Eyes
Malik R
Ophthalmology 2016; 123: 1181-1189 (IGR: 17-4)

66776 Uveo-scleral outflow pathways after ultrasonic cyclocoagulation in refractory glaucoma: an anterior segment optical coherence tomography and in vivo confocal study
Mastropasqua R
British Journal of Ophthalmology 2016; 100: 1668-1675 (IGR: 17-4)

67212 Can Automated Imaging for Optic Disc and Retinal Nerve Fiber Layer Analysis Aid Glaucoma Detection?
Banister K
Ophthalmology 2016; 123: 930-938 (IGR: 17-4)

67495 Neuroretinal rim in non-glaucomatous large optic nerve heads: a comparison of confocal scanning laser tomography and spectral domain optical coherence tomography
Enders P
British Journal of Ophthalmology 2017; 101: 138-142 (IGR: 17-4)

67098 Optic nerve head parameters of high-definition optical coherence tomography and Heidelberg retina tomogram in perimetric and preperimetric glaucoma
Begum VU
Indian Journal of Ophthalmology 2016; 64: 277-284 (IGR: 17-4)

67475 Glaucoma diagnostic capacity of optic nerve head haemoglobin measures compared with spectral domain OCT and HRT III confocal tomography
Mendez-Hernandez C
Acta Ophthalmologica 2016; 94: 697-704 (IGR: 17-4)

67495 Neuroretinal rim in non-glaucomatous large optic nerve heads: a comparison of confocal scanning laser tomography and spectral domain optical coherence tomography
Schaub F
British Journal of Ophthalmology 2017; 101: 138-142 (IGR: 17-4)

66776 Uveo-scleral outflow pathways after ultrasonic cyclocoagulation in refractory glaucoma: an anterior segment optical coherence tomography and in vivo confocal study
Agnifili L
British Journal of Ophthalmology 2016; 100: 1668-1675 (IGR: 17-4)

67243 Diagnostic Accuracy of Optical Coherence Tomography and Scanning Laser Tomography for Identifying Glaucoma in Myopic Eyes
Belliveau AC
Ophthalmology 2016; 123: 1181-1189 (IGR: 17-4)

67212 Can Automated Imaging for Optic Disc and Retinal Nerve Fiber Layer Analysis Aid Glaucoma Detection?
Boachie C
Ophthalmology 2016; 123: 930-938 (IGR: 17-4)

67098 Optic nerve head parameters of high-definition optical coherence tomography and Heidelberg retina tomogram in perimetric and preperimetric glaucoma
Addepalli UK
Indian Journal of Ophthalmology 2016; 64: 277-284 (IGR: 17-4)

67544 Regional Image Features Model for Automatic Classification between Normal and Glaucoma in Fundus and Scanning Laser Ophthalmoscopy (SLO) Images
Han L
Journal of Medical Systems 2016; 40: 132 (IGR: 17-4)

67475 Glaucoma diagnostic capacity of optic nerve head haemoglobin measures compared with spectral domain OCT and HRT III confocal tomography
Rodriguez-Uña I
Acta Ophthalmologica 2016; 94: 697-704 (IGR: 17-4)

67243 Diagnostic Accuracy of Optical Coherence Tomography and Scanning Laser Tomography for Identifying Glaucoma in Myopic Eyes
Sharpe GP
Ophthalmology 2016; 123: 1181-1189 (IGR: 17-4)

67495 Neuroretinal rim in non-glaucomatous large optic nerve heads: a comparison of confocal scanning laser tomography and spectral domain optical coherence tomography
Hermann MM
British Journal of Ophthalmology 2017; 101: 138-142 (IGR: 17-4)

67212 Can Automated Imaging for Optic Disc and Retinal Nerve Fiber Layer Analysis Aid Glaucoma Detection?
Bourne R
Ophthalmology 2016; 123: 930-938 (IGR: 17-4)

67098 Optic nerve head parameters of high-definition optical coherence tomography and Heidelberg retina tomogram in perimetric and preperimetric glaucoma
Senthil S
Indian Journal of Ophthalmology 2016; 64: 277-284 (IGR: 17-4)

67475 Glaucoma diagnostic capacity of optic nerve head haemoglobin measures compared with spectral domain OCT and HRT III confocal tomography
Gonzalez-de-la Rosa M
Acta Ophthalmologica 2016; 94: 697-704 (IGR: 17-4)

67544 Regional Image Features Model for Automatic Classification between Normal and Glaucoma in Fundus and Scanning Laser Ophthalmoscopy (SLO) Images
Hemert Jv
Journal of Medical Systems 2016; 40: 132 (IGR: 17-4)

66776 Uveo-scleral outflow pathways after ultrasonic cyclocoagulation in refractory glaucoma: an anterior segment optical coherence tomography and in vivo confocal study
Fasanella V
British Journal of Ophthalmology 2016; 100: 1668-1675 (IGR: 17-4)

67495 Neuroretinal rim in non-glaucomatous large optic nerve heads: a comparison of confocal scanning laser tomography and spectral domain optical coherence tomography
Cursiefen C
British Journal of Ophthalmology 2017; 101: 138-142 (IGR: 17-4)

67098 Optic nerve head parameters of high-definition optical coherence tomography and Heidelberg retina tomogram in perimetric and preperimetric glaucoma
Garudadri CS
Indian Journal of Ophthalmology 2016; 64: 277-284 (IGR: 17-4)

67544 Regional Image Features Model for Automatic Classification between Normal and Glaucoma in Fundus and Scanning Laser Ophthalmoscopy (SLO) Images
Fleming A
Journal of Medical Systems 2016; 40: 132 (IGR: 17-4)

67475 Glaucoma diagnostic capacity of optic nerve head haemoglobin measures compared with spectral domain OCT and HRT III confocal tomography
Arribas-Pardo P
Acta Ophthalmologica 2016; 94: 697-704 (IGR: 17-4)

66776 Uveo-scleral outflow pathways after ultrasonic cyclocoagulation in refractory glaucoma: an anterior segment optical coherence tomography and in vivo confocal study
Toto L
British Journal of Ophthalmology 2016; 100: 1668-1675 (IGR: 17-4)

67212 Can Automated Imaging for Optic Disc and Retinal Nerve Fiber Layer Analysis Aid Glaucoma Detection?
Cook J
Ophthalmology 2016; 123: 930-938 (IGR: 17-4)

67243 Diagnostic Accuracy of Optical Coherence Tomography and Scanning Laser Tomography for Identifying Glaucoma in Myopic Eyes
Shuba LM
Ophthalmology 2016; 123: 1181-1189 (IGR: 17-4)

67212 Can Automated Imaging for Optic Disc and Retinal Nerve Fiber Layer Analysis Aid Glaucoma Detection?
Burr JM
Ophthalmology 2016; 123: 930-938 (IGR: 17-4)

67098 Optic nerve head parameters of high-definition optical coherence tomography and Heidelberg retina tomogram in perimetric and preperimetric glaucoma
Rao HL
Indian Journal of Ophthalmology 2016; 64: 277-284 (IGR: 17-4)

67495 Neuroretinal rim in non-glaucomatous large optic nerve heads: a comparison of confocal scanning laser tomography and spectral domain optical coherence tomography
Heindl LM
British Journal of Ophthalmology 2017; 101: 138-142 (IGR: 17-4)

67544 Regional Image Features Model for Automatic Classification between Normal and Glaucoma in Fundus and Scanning Laser Ophthalmoscopy (SLO) Images
Pasquale LR
Journal of Medical Systems 2016; 40: 132 (IGR: 17-4)

67243 Diagnostic Accuracy of Optical Coherence Tomography and Scanning Laser Tomography for Identifying Glaucoma in Myopic Eyes
Chauhan BC
Ophthalmology 2016; 123: 1181-1189 (IGR: 17-4)

67475 Glaucoma diagnostic capacity of optic nerve head haemoglobin measures compared with spectral domain OCT and HRT III confocal tomography
Garcia-Feijoo J
Acta Ophthalmologica 2016; 94: 697-704 (IGR: 17-4)

66776 Uveo-scleral outflow pathways after ultrasonic cyclocoagulation in refractory glaucoma: an anterior segment optical coherence tomography and in vivo confocal study
Brescia L
British Journal of Ophthalmology 2016; 100: 1668-1675 (IGR: 17-4)

67243 Diagnostic Accuracy of Optical Coherence Tomography and Scanning Laser Tomography for Identifying Glaucoma in Myopic Eyes
Nicolela MT
Ophthalmology 2016; 123: 1181-1189 (IGR: 17-4)

67544 Regional Image Features Model for Automatic Classification between Normal and Glaucoma in Fundus and Scanning Laser Ophthalmoscopy (SLO) Images
Silva PS
Journal of Medical Systems 2016; 40: 132 (IGR: 17-4)

67212 Can Automated Imaging for Optic Disc and Retinal Nerve Fiber Layer Analysis Aid Glaucoma Detection?
Ramsay C
Ophthalmology 2016; 123: 930-938 (IGR: 17-4)

66776 Uveo-scleral outflow pathways after ultrasonic cyclocoagulation in refractory glaucoma: an anterior segment optical coherence tomography and in vivo confocal study
Di Staso S
British Journal of Ophthalmology 2016; 100: 1668-1675 (IGR: 17-4)

67544 Regional Image Features Model for Automatic Classification between Normal and Glaucoma in Fundus and Scanning Laser Ophthalmoscopy (SLO) Images
Song BJ
Journal of Medical Systems 2016; 40: 132 (IGR: 17-4)

66776 Uveo-scleral outflow pathways after ultrasonic cyclocoagulation in refractory glaucoma: an anterior segment optical coherence tomography and in vivo confocal study
Doronzo E
British Journal of Ophthalmology 2016; 100: 1668-1675 (IGR: 17-4)

67212 Can Automated Imaging for Optic Disc and Retinal Nerve Fiber Layer Analysis Aid Glaucoma Detection?
Garway-Heath D; Gray J
Ophthalmology 2016; 123: 930-938 (IGR: 17-4)

66776 Uveo-scleral outflow pathways after ultrasonic cyclocoagulation in refractory glaucoma: an anterior segment optical coherence tomography and in vivo confocal study
Marchini G
British Journal of Ophthalmology 2016; 100: 1668-1675 (IGR: 17-4)

67544 Regional Image Features Model for Automatic Classification between Normal and Glaucoma in Fundus and Scanning Laser Ophthalmoscopy (SLO) Images
Aiello LP
Journal of Medical Systems 2016; 40: 132 (IGR: 17-4)

67212 Can Automated Imaging for Optic Disc and Retinal Nerve Fiber Layer Analysis Aid Glaucoma Detection?
McMeekin P; Hernández R; Azuara-Blanco A
Ophthalmology 2016; 123: 930-938 (IGR: 17-4)

66272 Association Between Alzheimer's Disease and Glaucoma: A Study Based on Heidelberg Retinal Tomography and Frequency Doubling Technology Perimetry
Cesareo M
Frontiers in neuroscience 2015; 9: 479 (IGR: 17-3)

66300 Neuroretinal Rim Area Change in Glaucoma Patients With Visual Field Progression Endpoints and Intraocular Pressure Reduction. The Canadian Glaucoma Study: 4
Malik R
American Journal of Ophthalmology 2016; 163: 140-147.e1 (IGR: 17-3)

65908 Influence of optic disc leakage on objective optic nerve head assessment in patients with uveitis
Heinz C
Graefe's Archive for Clinical and Experimental Ophthalmology 2016; 254: 361-364 (IGR: 17-3)

66477 Between-Subject Variability in Healthy Eyes as a Primary Source of Structural-Functional Discordance in Patients With Glaucoma
Ashimatey BS
Investigative Ophthalmology and Visual Science 2016; 57: 502-507 (IGR: 17-3)

66337 Correlations between corneal and optic nerve head variables in healthy subjects and patients with primary open angle glaucoma
Saenz-Frances F
International Journal of Ophthalmology 2015; 8: 1156-1161 (IGR: 17-3)

65872 Optic nerve head and fibre layer imaging for diagnosing glaucoma
Michelessi M
Cochrane Database of Systematic Reviews 2015; 11: CD008803 (IGR: 17-3)

66256 Evaluation of Agreement between HRT III and iVue OCT in Glaucoma and Ocular Hypertension Patients
Perdicchi A
Journal of Ophthalmology 2015; 2015: 691031 (IGR: 17-3)

66239 Automated imaging technologies for the diagnosis of glaucoma: a comparative diagnostic study for the evaluation of the diagnostic accuracy, performance as triage tests and cost-effectiveness (GATE study)
Azuara-Blanco A; Banister K
Health Technol Assess 2016; 20: 1-168 (IGR: 17-3)

66256 Evaluation of Agreement between HRT III and iVue OCT in Glaucoma and Ocular Hypertension Patients
Iester M
Journal of Ophthalmology 2015; 2015: 691031 (IGR: 17-3)

66337 Correlations between corneal and optic nerve head variables in healthy subjects and patients with primary open angle glaucoma
Jañez L
International Journal of Ophthalmology 2015; 8: 1156-1161 (IGR: 17-3)

65872 Optic nerve head and fibre layer imaging for diagnosing glaucoma
Lucenteforte E
Cochrane Database of Systematic Reviews 2015; 11: CD008803 (IGR: 17-3)

66300 Neuroretinal Rim Area Change in Glaucoma Patients With Visual Field Progression Endpoints and Intraocular Pressure Reduction. The Canadian Glaucoma Study: 4
O'Leary N
American Journal of Ophthalmology 2016; 163: 140-147.e1 (IGR: 17-3)

65908 Influence of optic disc leakage on objective optic nerve head assessment in patients with uveitis
Kogelboom K
Graefe's Archive for Clinical and Experimental Ophthalmology 2016; 254: 361-364 (IGR: 17-3)

66477 Between-Subject Variability in Healthy Eyes as a Primary Source of Structural-Functional Discordance in Patients With Glaucoma
Swanson WH
Investigative Ophthalmology and Visual Science 2016; 57: 502-507 (IGR: 17-3)

66272 Association Between Alzheimer's Disease and Glaucoma: A Study Based on Heidelberg Retinal Tomography and Frequency Doubling Technology Perimetry
Martucci A
Frontiers in neuroscience 2015; 9: 479 (IGR: 17-3)

66337 Correlations between corneal and optic nerve head variables in healthy subjects and patients with primary open angle glaucoma
Borrego-Sanz L
International Journal of Ophthalmology 2015; 8: 1156-1161 (IGR: 17-3)

66256 Evaluation of Agreement between HRT III and iVue OCT in Glaucoma and Ocular Hypertension Patients
Iacovello D
Journal of Ophthalmology 2015; 2015: 691031 (IGR: 17-3)

66239 Automated imaging technologies for the diagnosis of glaucoma: a comparative diagnostic study for the evaluation of the diagnostic accuracy, performance as triage tests and cost-effectiveness (GATE study)
Boachie C
Health Technol Assess 2016; 20: 1-168 (IGR: 17-3)

66272 Association Between Alzheimer's Disease and Glaucoma: A Study Based on Heidelberg Retinal Tomography and Frequency Doubling Technology Perimetry
Ciuffoletti E
Frontiers in neuroscience 2015; 9: 479 (IGR: 17-3)

65872 Optic nerve head and fibre layer imaging for diagnosing glaucoma
Oddone F
Cochrane Database of Systematic Reviews 2015; 11: CD008803 (IGR: 17-3)

66300 Neuroretinal Rim Area Change in Glaucoma Patients With Visual Field Progression Endpoints and Intraocular Pressure Reduction. The Canadian Glaucoma Study: 4
Mikelberg FS
American Journal of Ophthalmology 2016; 163: 140-147.e1 (IGR: 17-3)

65908 Influence of optic disc leakage on objective optic nerve head assessment in patients with uveitis
Heiligenhaus A
Graefe's Archive for Clinical and Experimental Ophthalmology 2016; 254: 361-364 (IGR: 17-3)

66337 Correlations between corneal and optic nerve head variables in healthy subjects and patients with primary open angle glaucoma
Berrozpe-Villabona C
International Journal of Ophthalmology 2015; 8: 1156-1161 (IGR: 17-3)

66239 Automated imaging technologies for the diagnosis of glaucoma: a comparative diagnostic study for the evaluation of the diagnostic accuracy, performance as triage tests and cost-effectiveness (GATE study)
McMeekin P
Health Technol Assess 2016; 20: 1-168 (IGR: 17-3)

65872 Optic nerve head and fibre layer imaging for diagnosing glaucoma
Brazzelli M
Cochrane Database of Systematic Reviews 2015; 11: CD008803 (IGR: 17-3)

66300 Neuroretinal Rim Area Change in Glaucoma Patients With Visual Field Progression Endpoints and Intraocular Pressure Reduction. The Canadian Glaucoma Study: 4
Balazsi AG
American Journal of Ophthalmology 2016; 163: 140-147.e1 (IGR: 17-3)

66272 Association Between Alzheimer's Disease and Glaucoma: A Study Based on Heidelberg Retinal Tomography and Frequency Doubling Technology Perimetry
Mancino R
Frontiers in neuroscience 2015; 9: 479 (IGR: 17-3)

66256 Evaluation of Agreement between HRT III and iVue OCT in Glaucoma and Ocular Hypertension Patients
Cutini A; Balestrieri M
Journal of Ophthalmology 2015; 2015: 691031 (IGR: 17-3)

66300 Neuroretinal Rim Area Change in Glaucoma Patients With Visual Field Progression Endpoints and Intraocular Pressure Reduction. The Canadian Glaucoma Study: 4
Leblanc RP
American Journal of Ophthalmology 2016; 163: 140-147.e1 (IGR: 17-3)

65872 Optic nerve head and fibre layer imaging for diagnosing glaucoma
Parravano M
Cochrane Database of Systematic Reviews 2015; 11: CD008803 (IGR: 17-3)

66337 Correlations between corneal and optic nerve head variables in healthy subjects and patients with primary open angle glaucoma
Martinez-de-la-Casa JM
International Journal of Ophthalmology 2015; 8: 1156-1161 (IGR: 17-3)

66272 Association Between Alzheimer's Disease and Glaucoma: A Study Based on Heidelberg Retinal Tomography and Frequency Doubling Technology Perimetry
Cerulli A
Frontiers in neuroscience 2015; 9: 479 (IGR: 17-3)

66239 Automated imaging technologies for the diagnosis of glaucoma: a comparative diagnostic study for the evaluation of the diagnostic accuracy, performance as triage tests and cost-effectiveness (GATE study)
Gray J; Burr J
Health Technol Assess 2016; 20: 1-168 (IGR: 17-3)

66272 Association Between Alzheimer's Disease and Glaucoma: A Study Based on Heidelberg Retinal Tomography and Frequency Doubling Technology Perimetry
Sorge RP
Frontiers in neuroscience 2015; 9: 479 (IGR: 17-3)

66256 Evaluation of Agreement between HRT III and iVue OCT in Glaucoma and Ocular Hypertension Patients
Mutolo MG
Journal of Ophthalmology 2015; 2015: 691031 (IGR: 17-3)

66337 Correlations between corneal and optic nerve head variables in healthy subjects and patients with primary open angle glaucoma
Morales-Fernandez L
International Journal of Ophthalmology 2015; 8: 1156-1161 (IGR: 17-3)

66300 Neuroretinal Rim Area Change in Glaucoma Patients With Visual Field Progression Endpoints and Intraocular Pressure Reduction. The Canadian Glaucoma Study: 4
Lesk MR
American Journal of Ophthalmology 2016; 163: 140-147.e1 (IGR: 17-3)

65872 Optic nerve head and fibre layer imaging for diagnosing glaucoma
Franchi S
Cochrane Database of Systematic Reviews 2015; 11: CD008803 (IGR: 17-3)

66272 Association Between Alzheimer's Disease and Glaucoma: A Study Based on Heidelberg Retinal Tomography and Frequency Doubling Technology Perimetry
Martorana A
Frontiers in neuroscience 2015; 9: 479 (IGR: 17-3)

66239 Automated imaging technologies for the diagnosis of glaucoma: a comparative diagnostic study for the evaluation of the diagnostic accuracy, performance as triage tests and cost-effectiveness (GATE study)
Bourne R
Health Technol Assess 2016; 20: 1-168 (IGR: 17-3)

66300 Neuroretinal Rim Area Change in Glaucoma Patients With Visual Field Progression Endpoints and Intraocular Pressure Reduction. The Canadian Glaucoma Study: 4
Nicolela MT
American Journal of Ophthalmology 2016; 163: 140-147.e1 (IGR: 17-3)

65872 Optic nerve head and fibre layer imaging for diagnosing glaucoma
Ng SM
Cochrane Database of Systematic Reviews 2015; 11: CD008803 (IGR: 17-3)

66256 Evaluation of Agreement between HRT III and iVue OCT in Glaucoma and Ocular Hypertension Patients
Ferreras A
Journal of Ophthalmology 2015; 2015: 691031 (IGR: 17-3)

66337 Correlations between corneal and optic nerve head variables in healthy subjects and patients with primary open angle glaucoma
Garcia-Sanchez J; Santos-Bueso E
International Journal of Ophthalmology 2015; 8: 1156-1161 (IGR: 17-3)

66272 Association Between Alzheimer's Disease and Glaucoma: A Study Based on Heidelberg Retinal Tomography and Frequency Doubling Technology Perimetry
Sancesario G
Frontiers in neuroscience 2015; 9: 479 (IGR: 17-3)

65872 Optic nerve head and fibre layer imaging for diagnosing glaucoma
Virgili G
Cochrane Database of Systematic Reviews 2015; 11: CD008803 (IGR: 17-3)

66300 Neuroretinal Rim Area Change in Glaucoma Patients With Visual Field Progression Endpoints and Intraocular Pressure Reduction. The Canadian Glaucoma Study: 4
Trope GE
American Journal of Ophthalmology 2016; 163: 140-147.e1 (IGR: 17-3)

66239 Automated imaging technologies for the diagnosis of glaucoma: a comparative diagnostic study for the evaluation of the diagnostic accuracy, performance as triage tests and cost-effectiveness (GATE study)
Garway-Heath D
Health Technol Assess 2016; 20: 1-168 (IGR: 17-3)

66256 Evaluation of Agreement between HRT III and iVue OCT in Glaucoma and Ocular Hypertension Patients
Contestabile MT
Journal of Ophthalmology 2015; 2015: 691031 (IGR: 17-3)

66239 Automated imaging technologies for the diagnosis of glaucoma: a comparative diagnostic study for the evaluation of the diagnostic accuracy, performance as triage tests and cost-effectiveness (GATE study)
Batterbury M
Health Technol Assess 2016; 20: 1-168 (IGR: 17-3)

66256 Evaluation of Agreement between HRT III and iVue OCT in Glaucoma and Ocular Hypertension Patients
Recupero SM
Journal of Ophthalmology 2015; 2015: 691031 (IGR: 17-3)

66337 Correlations between corneal and optic nerve head variables in healthy subjects and patients with primary open angle glaucoma
Garcia-Feijoo J
International Journal of Ophthalmology 2015; 8: 1156-1161 (IGR: 17-3)

66272 Association Between Alzheimer's Disease and Glaucoma: A Study Based on Heidelberg Retinal Tomography and Frequency Doubling Technology Perimetry
Nucci C
Frontiers in neuroscience 2015; 9: 479 (IGR: 17-3)

66300 Neuroretinal Rim Area Change in Glaucoma Patients With Visual Field Progression Endpoints and Intraocular Pressure Reduction. The Canadian Glaucoma Study: 4
Chauhan BC
American Journal of Ophthalmology 2016; 163: 140-147.e1 (IGR: 17-3)

66239 Automated imaging technologies for the diagnosis of glaucoma: a comparative diagnostic study for the evaluation of the diagnostic accuracy, performance as triage tests and cost-effectiveness (GATE study)
Hernández R
Health Technol Assess 2016; 20: 1-168 (IGR: 17-3)

66300 Neuroretinal Rim Area Change in Glaucoma Patients With Visual Field Progression Endpoints and Intraocular Pressure Reduction. The Canadian Glaucoma Study: 4

American Journal of Ophthalmology 2016; 163: 140-147.e1 (IGR: 17-3)

66239 Automated imaging technologies for the diagnosis of glaucoma: a comparative diagnostic study for the evaluation of the diagnostic accuracy, performance as triage tests and cost-effectiveness (GATE study)
McPherson G; Ramsay C; Cook J
Health Technol Assess 2016; 20: 1-168 (IGR: 17-3)

61009 HRT for the Diagnosis and Detection of Glaucoma Progression
Maslin JS
Open Ophthalmology Journal 2015; 9: 58-67 (IGR: 17-1)

61037 Imaging Glaucomatous Damage Across the Temporal Raphe
Huang G
Investigative Ophthalmology and Visual Science 2015; 56: 3496-3504 (IGR: 17-1)

61079 Morphological characteristics of the optic nerve evaluated by confocal laser tomography (HRT3) and laser polarimetry (GDx-VCC) in a normal population from the city of Barcelona
Fallon M
Archivos de la Sociedad Española de Oftalmologia 2015; 90: 507-516 (IGR: 17-1)

61483 Flicker defined form, standard perimetry and Heidelberg retinal tomography: Structure-function relationships
Ichhpujani P
Canadian Journal of Ophthalmology 2015; 50: 290-296 (IGR: 17-1)

61737 Sensitivity and Specificity of the Nerve Fibre Imaging Using Scanning Laser Ophthalmoscopy and of Optic Nerve Analysis Using Heidelberg Retina Tomography in Glaucoma
Hirsch T
Klinische Monatsblätter für Augenheilkunde 2015; 232: 1279-1283 (IGR: 17-1)

61516 Value of Heidelberg retinal tomography in glaucoma diagnostics
Hoffmann EM
Ophthalmologe 2015; 112: 646-653 (IGR: 17-1)

61626 Retinal Nerve Fiber Layer Converges More Convexly on Normal Smaller Optic Nerve Head
Jung KI
Journal of Glaucoma 2015; 24: 448-454 (IGR: 17-1)

61365 Correlations Between the Individual Risk for Glaucoma and RNFL and Optic Disc Morphometrical Evaluations in Ocular Hypertensive Patients
Colombo L
Journal of Glaucoma 2016; 25: e455-e462 (IGR: 17-1)

61045 Effect of age and disc size on rim order rules by Heidelberg Retina Tomograph
Nayak NV
Journal of Glaucoma 2015; 24: 377-382 (IGR: 17-1)

61483 Flicker defined form, standard perimetry and Heidelberg retinal tomography: Structure-function relationships
Lo DC
Canadian Journal of Ophthalmology 2015; 50: 290-296 (IGR: 17-1)

61037 Imaging Glaucomatous Damage Across the Temporal Raphe
Luo T
Investigative Ophthalmology and Visual Science 2015; 56: 3496-3504 (IGR: 17-1)

61365 Correlations Between the Individual Risk for Glaucoma and RNFL and Optic Disc Morphometrical Evaluations in Ocular Hypertensive Patients
Bertuzzi F
Journal of Glaucoma 2016; 25: e455-e462 (IGR: 17-1)

61045 Effect of age and disc size on rim order rules by Heidelberg Retina Tomograph
Berezina TL
Journal of Glaucoma 2015; 24: 377-382 (IGR: 17-1)

61626 Retinal Nerve Fiber Layer Converges More Convexly on Normal Smaller Optic Nerve Head
Shin JA
Journal of Glaucoma 2015; 24: 448-454 (IGR: 17-1)

61079 Morphological characteristics of the optic nerve evaluated by confocal laser tomography (HRT3) and laser polarimetry (GDx-VCC) in a normal population from the city of Barcelona
Pazos M
Archivos de la Sociedad Española de Oftalmologia 2015; 90: 507-516 (IGR: 17-1)

61737 Sensitivity and Specificity of the Nerve Fibre Imaging Using Scanning Laser Ophthalmoscopy and of Optic Nerve Analysis Using Heidelberg Retina Tomography in Glaucoma
Hirsch F
Klinische Monatsblätter für Augenheilkunde 2015; 232: 1279-1283 (IGR: 17-1)

61009 HRT for the Diagnosis and Detection of Glaucoma Progression
Mansouri K
Open Ophthalmology Journal 2015; 9: 58-67 (IGR: 17-1)

61045 Effect of age and disc size on rim order rules by Heidelberg Retina Tomograph
Fechtner RD
Journal of Glaucoma 2015; 24: 377-382 (IGR: 17-1)

61079 Morphological characteristics of the optic nerve evaluated by confocal laser tomography (HRT3) and laser polarimetry (GDx-VCC) in a normal population from the city of Barcelona
Morilla A
Archivos de la Sociedad Española de Oftalmologia 2015; 90: 507-516 (IGR: 17-1)

61483 Flicker defined form, standard perimetry and Heidelberg retinal tomography: Structure-function relationships
Cvintal V
Canadian Journal of Ophthalmology 2015; 50: 290-296 (IGR: 17-1)

61737 Sensitivity and Specificity of the Nerve Fibre Imaging Using Scanning Laser Ophthalmoscopy and of Optic Nerve Analysis Using Heidelberg Retina Tomography in Glaucoma
Koch EC
Klinische Monatsblätter für Augenheilkunde 2015; 232: 1279-1283 (IGR: 17-1)

61626 Retinal Nerve Fiber Layer Converges More Convexly on Normal Smaller Optic Nerve Head
Park HY
Journal of Glaucoma 2015; 24: 448-454 (IGR: 17-1)

61365 Correlations Between the Individual Risk for Glaucoma and RNFL and Optic Disc Morphometrical Evaluations in Ocular Hypertensive Patients
Rulli E
Journal of Glaucoma 2016; 25: e455-e462 (IGR: 17-1)

61037 Imaging Glaucomatous Damage Across the Temporal Raphe
Gast TJ
Investigative Ophthalmology and Visual Science 2015; 56: 3496-3504 (IGR: 17-1)

61009 HRT for the Diagnosis and Detection of Glaucoma Progression
Dorairaj SK
Open Ophthalmology Journal 2015; 9: 58-67 (IGR: 17-1)

61737 Sensitivity and Specificity of the Nerve Fibre Imaging Using Scanning Laser Ophthalmoscopy and of Optic Nerve Analysis Using Heidelberg Retina Tomography in Glaucoma
Fuest M
Klinische Monatsblätter für Augenheilkunde 2015; 232: 1279-1283 (IGR: 17-1)

61626 Retinal Nerve Fiber Layer Converges More Convexly on Normal Smaller Optic Nerve Head
Park CK
Journal of Glaucoma 2015; 24: 448-454 (IGR: 17-1)

61045 Effect of age and disc size on rim order rules by Heidelberg Retina Tomograph
Sinai MJ
Journal of Glaucoma 2015; 24: 377-382 (IGR: 17-1)

61079 Morphological characteristics of the optic nerve evaluated by confocal laser tomography (HRT3) and laser polarimetry (GDx-VCC) in a normal population from the city of Barcelona
Sebastián MA
Archivos de la Sociedad Española de Oftalmologia 2015; 90: 507-516 (IGR: 17-1)

61365 Correlations Between the Individual Risk for Glaucoma and RNFL and Optic Disc Morphometrical Evaluations in Ocular Hypertensive Patients
Miglior S
Journal of Glaucoma 2016; 25: e455-e462 (IGR: 17-1)

61037 Imaging Glaucomatous Damage Across the Temporal Raphe
Burns SA
Investigative Ophthalmology and Visual Science 2015; 56: 3496-3504 (IGR: 17-1)

61483 Flicker defined form, standard perimetry and Heidelberg retinal tomography: Structure-function relationships
Waisbourd M
Canadian Journal of Ophthalmology 2015; 50: 290-296 (IGR: 17-1)

61079 Morphological characteristics of the optic nerve evaluated by confocal laser tomography (HRT3) and laser polarimetry (GDx-VCC) in a normal population from the city of Barcelona
Xancó R
Archivos de la Sociedad Española de Oftalmologia 2015; 90: 507-516 (IGR: 17-1)

61737 Sensitivity and Specificity of the Nerve Fibre Imaging Using Scanning Laser Ophthalmoscopy and of Optic Nerve Analysis Using Heidelberg Retina Tomography in Glaucoma
Plange N
Klinische Monatsblätter für Augenheilkunde 2015; 232: 1279-1283 (IGR: 17-1)

61483 Flicker defined form, standard perimetry and Heidelberg retinal tomography: Structure-function relationships
Averbuch A
Canadian Journal of Ophthalmology 2015; 50: 290-296 (IGR: 17-1)

61037 Imaging Glaucomatous Damage Across the Temporal Raphe
Malinovsky VE
Investigative Ophthalmology and Visual Science 2015; 56: 3496-3504 (IGR: 17-1)

61045 Effect of age and disc size on rim order rules by Heidelberg Retina Tomograph
Khouri AS
Journal of Glaucoma 2015; 24: 377-382 (IGR: 17-1)

61079 Morphological characteristics of the optic nerve evaluated by confocal laser tomography (HRT3) and laser polarimetry (GDx-VCC) in a normal population from the city of Barcelona
Mora C
Archivos de la Sociedad Española de Oftalmologia 2015; 90: 507-516 (IGR: 17-1)

61037 Imaging Glaucomatous Damage Across the Temporal Raphe
Swanson WH
Investigative Ophthalmology and Visual Science 2015; 56: 3496-3504 (IGR: 17-1)

61483 Flicker defined form, standard perimetry and Heidelberg retinal tomography: Structure-function relationships
Leiby BE
Canadian Journal of Ophthalmology 2015; 50: 290-296 (IGR: 17-1)

61079 Morphological characteristics of the optic nerve evaluated by confocal laser tomography (HRT3) and laser polarimetry (GDx-VCC) in a normal population from the city of Barcelona
Calderón B
Archivos de la Sociedad Española de Oftalmologia 2015; 90: 507-516 (IGR: 17-1)

61483 Flicker defined form, standard perimetry and Heidelberg retinal tomography: Structure-function relationships
Myers JS
Canadian Journal of Ophthalmology 2015; 50: 290-296 (IGR: 17-1)

61079 Morphological characteristics of the optic nerve evaluated by confocal laser tomography (HRT3) and laser polarimetry (GDx-VCC) in a normal population from the city of Barcelona
Vega Z
Archivos de la Sociedad Española de Oftalmologia 2015; 90: 507-516 (IGR: 17-1)

61483 Flicker defined form, standard perimetry and Heidelberg retinal tomography: Structure-function relationships
Spaeth GL; Katz LJ
Canadian Journal of Ophthalmology 2015; 50: 290-296 (IGR: 17-1)

61079 Morphological characteristics of the optic nerve evaluated by confocal laser tomography (HRT3) and laser polarimetry (GDx-VCC) in a normal population from the city of Barcelona
Antón A
Archivos de la Sociedad Española de Oftalmologia 2015; 90: 507-516 (IGR: 17-1)

60755 Automated Registration of Multimodal Optic Disc Images: Clinical Assessment of Alignment Accuracy
Ng WS
Journal of Glaucoma 2016; 25: 397-402 (IGR: 16-4)

60121 Comparison study of OCT, HRT and VF findings among normal controls and patients with pseudoexfoliation, with or without increased IOP
Riga F
Clinical Ophthalmology 2014; 8: 2441-2447 (IGR: 16-4)

60476 Evaluation of subjects with a moderate cup to disc ratio using optical coherence tomography and Heidelberg retina tomograph 3: impact of the disc area
Ulas F
Indian Journal of Ophthalmology 2015; 63: 3-8 (IGR: 16-4)

60241 Adaptive optics imaging of healthy and abnormal regions of retinal nerve fiber bundles of patients with glaucoma
Chen MF
Investigative Ophthalmology and Visual Science 2015; 56: 674-681 (IGR: 16-4)

60736 Cup-to-Disc Ratio From Heidelberg Retina Tomograph 3 and High-Definition Optical Coherence Tomography Agrees Poorly With Clinical Assessment
Perera SA
Journal of Glaucoma 2016; 25: 198-202 (IGR: 16-4)

60116 Enhanced structure-function relationship in glaucoma with an anatomically and geometrically accurate neuroretinal rim measurement
Danthurebandara VM
Investigative Ophthalmology and Visual Science 2015; 56: 98-105 (IGR: 16-4)

60685 Morphological features and important parameters of large optic discs for diagnosing glaucoma
Okimoto S
PLoS ONE 2015; 10: e0118920 (IGR: 16-4)

60364 Ethnic differences in trabecular meshwork height by optical coherence tomography
Chen RI
JAMA ophthalmology 2015; 133: 437-441 (IGR: 16-4)

60404 Detecting the progression of normal tension glaucoma: a comparison of perimetry, optic coherence tomography, and Heidelberg retinal tomography
Yoon JY
Korean Journal of Ophthalmology 2015; 29: 31-39 (IGR: 16-4)

60656 Comparison of Three Types of Images for the Detection of Retinal Nerve Fiber Layer Defects
Bae HW
Optometry and Vision Science 2015; 0: (IGR: 16-4)

60316 Evaluation of Corneal Microstructure in Pseudoexfoliation Syndrome and Glaucoma: In Vivo Scanning Laser Confocal Microscopic Study
Yüksel N
Current Eye Research 2015; 0: 1-7 (IGR: 16-4)

60551 Structure-Function Correlation Using Confocal Laser Ophthalmoscope in Primary Open-Angle Glaucoma and Pseudoexfoliative Glaucoma
Pappas T
Journal of Glaucoma 2016; 25: 377-382 (IGR: 16-4)

60693 Compass: clinical evaluation of a new instrument for the diagnosis of glaucoma
Rossetti L
PLoS ONE 2015; 10: e0122157 (IGR: 16-4)

60602 Corneoscleral limbus in glaucoma patients: in vivo confocal microscopy and immunocytological study
Mastropasqua R
Investigative Ophthalmology and Visual Science 2015; 56: 2050-2058 (IGR: 16-4)

60476 Evaluation of subjects with a moderate cup to disc ratio using optical coherence tomography and Heidelberg retina tomograph 3: impact of the disc area
Dogan Ü
Indian Journal of Ophthalmology 2015; 63: 3-8 (IGR: 16-4)

60316 Evaluation of Corneal Microstructure in Pseudoexfoliation Syndrome and Glaucoma: In Vivo Scanning Laser Confocal Microscopic Study
Emre E
Current Eye Research 2015; 0: 1-7 (IGR: 16-4)

60551 Structure-Function Correlation Using Confocal Laser Ophthalmoscope in Primary Open-Angle Glaucoma and Pseudoexfoliative Glaucoma
Founti P
Journal of Glaucoma 2016; 25: 377-382 (IGR: 16-4)

60693 Compass: clinical evaluation of a new instrument for the diagnosis of glaucoma
Digiuni M
PLoS ONE 2015; 10: e0122157 (IGR: 16-4)

60404 Detecting the progression of normal tension glaucoma: a comparison of perimetry, optic coherence tomography, and Heidelberg retinal tomography
Na JK
Korean Journal of Ophthalmology 2015; 29: 31-39 (IGR: 16-4)

60656 Comparison of Three Types of Images for the Detection of Retinal Nerve Fiber Layer Defects
Lee N
Optometry and Vision Science 2015; 0: (IGR: 16-4)

60736 Cup-to-Disc Ratio From Heidelberg Retina Tomograph 3 and High-Definition Optical Coherence Tomography Agrees Poorly With Clinical Assessment
Foo LL
Journal of Glaucoma 2016; 25: 198-202 (IGR: 16-4)

60121 Comparison study of OCT, HRT and VF findings among normal controls and patients with pseudoexfoliation, with or without increased IOP
Georgalas I
Clinical Ophthalmology 2014; 8: 2441-2447 (IGR: 16-4)

60755 Automated Registration of Multimodal Optic Disc Images: Clinical Assessment of Alignment Accuracy
Legg P
Journal of Glaucoma 2016; 25: 397-402 (IGR: 16-4)

60241 Adaptive optics imaging of healthy and abnormal regions of retinal nerve fiber bundles of patients with glaucoma
Chui TY
Investigative Ophthalmology and Visual Science 2015; 56: 674-681 (IGR: 16-4)

60685 Morphological features and important parameters of large optic discs for diagnosing glaucoma
Yamashita K
PLoS ONE 2015; 10: e0118920 (IGR: 16-4)

60602 Corneoscleral limbus in glaucoma patients: in vivo confocal microscopy and immunocytological study
Agnifili L
Investigative Ophthalmology and Visual Science 2015; 56: 2050-2058 (IGR: 16-4)

60116 Enhanced structure-function relationship in glaucoma with an anatomically and geometrically accurate neuroretinal rim measurement
Sharpe GP
Investigative Ophthalmology and Visual Science 2015; 56: 98-105 (IGR: 16-4)

60364 Ethnic differences in trabecular meshwork height by optical coherence tomography
Barbosa DT
JAMA ophthalmology 2015; 133: 437-441 (IGR: 16-4)

60404 Detecting the progression of normal tension glaucoma: a comparison of perimetry, optic coherence tomography, and Heidelberg retinal tomography
Park CK
Korean Journal of Ophthalmology 2015; 29: 31-39 (IGR: 16-4)

60693 Compass: clinical evaluation of a new instrument for the diagnosis of glaucoma
Rosso A
PLoS ONE 2015; 10: e0122157 (IGR: 16-4)

60656 Comparison of Three Types of Images for the Detection of Retinal Nerve Fiber Layer Defects
Kim CY
Optometry and Vision Science 2015; 0: (IGR: 16-4)

60685 Morphological features and important parameters of large optic discs for diagnosing glaucoma
Shibata T
PLoS ONE 2015; 10: e0118920 (IGR: 16-4)

60116 Enhanced structure-function relationship in glaucoma with an anatomically and geometrically accurate neuroretinal rim measurement
Hutchison DM
Investigative Ophthalmology and Visual Science 2015; 56: 98-105 (IGR: 16-4)

60364 Ethnic differences in trabecular meshwork height by optical coherence tomography
Hsu CH
JAMA ophthalmology 2015; 133: 437-441 (IGR: 16-4)

60121 Comparison study of OCT, HRT and VF findings among normal controls and patients with pseudoexfoliation, with or without increased IOP
Tsikripis P
Clinical Ophthalmology 2014; 8: 2441-2447 (IGR: 16-4)

60241 Adaptive optics imaging of healthy and abnormal regions of retinal nerve fiber bundles of patients with glaucoma
Alhadeff P
Investigative Ophthalmology and Visual Science 2015; 56: 674-681 (IGR: 16-4)

60316 Evaluation of Corneal Microstructure in Pseudoexfoliation Syndrome and Glaucoma: In Vivo Scanning Laser Confocal Microscopic Study
Pirhan D
Current Eye Research 2015; 0: 1-7 (IGR: 16-4)

60736 Cup-to-Disc Ratio From Heidelberg Retina Tomograph 3 and High-Definition Optical Coherence Tomography Agrees Poorly With Clinical Assessment
Cheung CY
Journal of Glaucoma 2016; 25: 198-202 (IGR: 16-4)

60602 Corneoscleral limbus in glaucoma patients: in vivo confocal microscopy and immunocytological study
Fasanella V
Investigative Ophthalmology and Visual Science 2015; 56: 2050-2058 (IGR: 16-4)

60755 Automated Registration of Multimodal Optic Disc Images: Clinical Assessment of Alignment Accuracy
Avadhanam V
Journal of Glaucoma 2016; 25: 397-402 (IGR: 16-4)

60551 Structure-Function Correlation Using Confocal Laser Ophthalmoscope in Primary Open-Angle Glaucoma and Pseudoexfoliative Glaucoma
Yin XJ
Journal of Glaucoma 2016; 25: 377-382 (IGR: 16-4)

60476 Evaluation of subjects with a moderate cup to disc ratio using optical coherence tomography and Heidelberg retina tomograph 3: impact of the disc area
Kaymaz A
Indian Journal of Ophthalmology 2015; 63: 3-8 (IGR: 16-4)

60241 Adaptive optics imaging of healthy and abnormal regions of retinal nerve fiber bundles of patients with glaucoma
Rosen RB
Investigative Ophthalmology and Visual Science 2015; 56: 674-681 (IGR: 16-4)

60656 Comparison of Three Types of Images for the Detection of Retinal Nerve Fiber Layer Defects
Choi M
Optometry and Vision Science 2015; 0: (IGR: 16-4)

60551 Structure-Function Correlation Using Confocal Laser Ophthalmoscope in Primary Open-Angle Glaucoma and Pseudoexfoliative Glaucoma
Koskosas A
Journal of Glaucoma 2016; 25: 377-382 (IGR: 16-4)

60364 Ethnic differences in trabecular meshwork height by optical coherence tomography
Porco TC
JAMA ophthalmology 2015; 133: 437-441 (IGR: 16-4)

60755 Automated Registration of Multimodal Optic Disc Images: Clinical Assessment of Alignment Accuracy
Aye K
Journal of Glaucoma 2016; 25: 397-402 (IGR: 16-4)

60693 Compass: clinical evaluation of a new instrument for the diagnosis of glaucoma
Riva R
PLoS ONE 2015; 10: e0122157 (IGR: 16-4)

60476 Evaluation of subjects with a moderate cup to disc ratio using optical coherence tomography and Heidelberg retina tomograph 3: impact of the disc area
Çelik F
Indian Journal of Ophthalmology 2015; 63: 3-8 (IGR: 16-4)

60116 Enhanced structure-function relationship in glaucoma with an anatomically and geometrically accurate neuroretinal rim measurement
Denniss J
Investigative Ophthalmology and Visual Science 2015; 56: 98-105 (IGR: 16-4)

60602 Corneoscleral limbus in glaucoma patients: in vivo confocal microscopy and immunocytological study
Curcio C
Investigative Ophthalmology and Visual Science 2015; 56: 2050-2058 (IGR: 16-4)

60685 Morphological features and important parameters of large optic discs for diagnosing glaucoma
Kiuchi Y
PLoS ONE 2015; 10: e0118920 (IGR: 16-4)

60736 Cup-to-Disc Ratio From Heidelberg Retina Tomograph 3 and High-Definition Optical Coherence Tomography Agrees Poorly With Clinical Assessment
Allen JC
Journal of Glaucoma 2016; 25: 198-202 (IGR: 16-4)

60121 Comparison study of OCT, HRT and VF findings among normal controls and patients with pseudoexfoliation, with or without increased IOP
Papaconstantinou D
Clinical Ophthalmology 2014; 8: 2441-2447 (IGR: 16-4)

60693 Compass: clinical evaluation of a new instrument for the diagnosis of glaucoma
Barbaro G
PLoS ONE 2015; 10: e0122157 (IGR: 16-4)

60755 Automated Registration of Multimodal Optic Disc Images: Clinical Assessment of Alignment Accuracy
Evans SH
Journal of Glaucoma 2016; 25: 397-402 (IGR: 16-4)

60602 Corneoscleral limbus in glaucoma patients: in vivo confocal microscopy and immunocytological study
Brescia L
Investigative Ophthalmology and Visual Science 2015; 56: 2050-2058 (IGR: 16-4)

60116 Enhanced structure-function relationship in glaucoma with an anatomically and geometrically accurate neuroretinal rim measurement
Nicolela MT
Investigative Ophthalmology and Visual Science 2015; 56: 98-105 (IGR: 16-4)

60241 Adaptive optics imaging of healthy and abnormal regions of retinal nerve fiber bundles of patients with glaucoma
Ritch R
Investigative Ophthalmology and Visual Science 2015; 56: 674-681 (IGR: 16-4)

60364 Ethnic differences in trabecular meshwork height by optical coherence tomography
Lin SC
JAMA ophthalmology 2015; 133: 437-441 (IGR: 16-4)

60551 Structure-Function Correlation Using Confocal Laser Ophthalmoscope in Primary Open-Angle Glaucoma and Pseudoexfoliative Glaucoma
Anastasopoulos E
Journal of Glaucoma 2016; 25: 377-382 (IGR: 16-4)

60656 Comparison of Three Types of Images for the Detection of Retinal Nerve Fiber Layer Defects
Hong S
Optometry and Vision Science 2015; 0: (IGR: 16-4)

60476 Evaluation of subjects with a moderate cup to disc ratio using optical coherence tomography and Heidelberg retina tomograph 3: impact of the disc area
Çelebi S
Indian Journal of Ophthalmology 2015; 63: 3-8 (IGR: 16-4)

60736 Cup-to-Disc Ratio From Heidelberg Retina Tomograph 3 and High-Definition Optical Coherence Tomography Agrees Poorly With Clinical Assessment
Chua D
Journal of Glaucoma 2016; 25: 198-202 (IGR: 16-4)

60602 Corneoscleral limbus in glaucoma patients: in vivo confocal microscopy and immunocytological study
Lanzini M
Investigative Ophthalmology and Visual Science 2015; 56: 2050-2058 (IGR: 16-4)

60736 Cup-to-Disc Ratio From Heidelberg Retina Tomograph 3 and High-Definition Optical Coherence Tomography Agrees Poorly With Clinical Assessment
Tham YC
Journal of Glaucoma 2016; 25: 198-202 (IGR: 16-4)

60755 Automated Registration of Multimodal Optic Disc Images: Clinical Assessment of Alignment Accuracy
North RV
Journal of Glaucoma 2016; 25: 397-402 (IGR: 16-4)

60551 Structure-Function Correlation Using Confocal Laser Ophthalmoscope in Primary Open-Angle Glaucoma and Pseudoexfoliative Glaucoma
Salonikiou A
Journal of Glaucoma 2016; 25: 377-382 (IGR: 16-4)

60116 Enhanced structure-function relationship in glaucoma with an anatomically and geometrically accurate neuroretinal rim measurement
McKendrick AM
Investigative Ophthalmology and Visual Science 2015; 56: 98-105 (IGR: 16-4)

60656 Comparison of Three Types of Images for the Detection of Retinal Nerve Fiber Layer Defects
Seong GJ
Optometry and Vision Science 2015; 0: (IGR: 16-4)

60693 Compass: clinical evaluation of a new instrument for the diagnosis of glaucoma
Smolek MK
PLoS ONE 2015; 10: e0122157 (IGR: 16-4)

60241 Adaptive optics imaging of healthy and abnormal regions of retinal nerve fiber bundles of patients with glaucoma
Dubra A
Investigative Ophthalmology and Visual Science 2015; 56: 674-681 (IGR: 16-4)

60602 Corneoscleral limbus in glaucoma patients: in vivo confocal microscopy and immunocytological study
Fresina M
Investigative Ophthalmology and Visual Science 2015; 56: 2050-2058 (IGR: 16-4)

60693 Compass: clinical evaluation of a new instrument for the diagnosis of glaucoma
Orzalesi N
PLoS ONE 2015; 10: e0122157 (IGR: 16-4)

60755 Automated Registration of Multimodal Optic Disc Images: Clinical Assessment of Alignment Accuracy
Marshall AD
Journal of Glaucoma 2016; 25: 397-402 (IGR: 16-4)

60551 Structure-Function Correlation Using Confocal Laser Ophthalmoscope in Primary Open-Angle Glaucoma and Pseudoexfoliative Glaucoma
Kilintzis V
Journal of Glaucoma 2016; 25: 377-382 (IGR: 16-4)

60116 Enhanced structure-function relationship in glaucoma with an anatomically and geometrically accurate neuroretinal rim measurement
Turpin A
Investigative Ophthalmology and Visual Science 2015; 56: 98-105 (IGR: 16-4)

60241 Adaptive optics imaging of healthy and abnormal regions of retinal nerve fiber bundles of patients with glaucoma
Hood DC
Investigative Ophthalmology and Visual Science 2015; 56: 674-681 (IGR: 16-4)

60736 Cup-to-Disc Ratio From Heidelberg Retina Tomograph 3 and High-Definition Optical Coherence Tomography Agrees Poorly With Clinical Assessment
Loon SC
Journal of Glaucoma 2016; 25: 198-202 (IGR: 16-4)

60551 Structure-Function Correlation Using Confocal Laser Ophthalmoscope in Primary Open-Angle Glaucoma and Pseudoexfoliative Glaucoma
Antoniadis A
Journal of Glaucoma 2016; 25: 377-382 (IGR: 16-4)

60116 Enhanced structure-function relationship in glaucoma with an anatomically and geometrically accurate neuroretinal rim measurement
Chauhan BC
Investigative Ophthalmology and Visual Science 2015; 56: 98-105 (IGR: 16-4)

60736 Cup-to-Disc Ratio From Heidelberg Retina Tomograph 3 and High-Definition Optical Coherence Tomography Agrees Poorly With Clinical Assessment
Wong TY
Journal of Glaucoma 2016; 25: 198-202 (IGR: 16-4)

60755 Automated Registration of Multimodal Optic Disc Images: Clinical Assessment of Alignment Accuracy
Rosin P
Journal of Glaucoma 2016; 25: 397-402 (IGR: 16-4)

60602 Corneoscleral limbus in glaucoma patients: in vivo confocal microscopy and immunocytological study
Mastropasqua L
Investigative Ophthalmology and Visual Science 2015; 56: 2050-2058 (IGR: 16-4)

60693 Compass: clinical evaluation of a new instrument for the diagnosis of glaucoma
De Cilla' S
PLoS ONE 2015; 10: e0122157 (IGR: 16-4)

60602 Corneoscleral limbus in glaucoma patients: in vivo confocal microscopy and immunocytological study
Marchini G
Investigative Ophthalmology and Visual Science 2015; 56: 2050-2058 (IGR: 16-4)

60736 Cup-to-Disc Ratio From Heidelberg Retina Tomograph 3 and High-Definition Optical Coherence Tomography Agrees Poorly With Clinical Assessment
Aung T
Journal of Glaucoma 2016; 25: 198-202 (IGR: 16-4)

60755 Automated Registration of Multimodal Optic Disc Images: Clinical Assessment of Alignment Accuracy
Morgan JE
Journal of Glaucoma 2016; 25: 397-402 (IGR: 16-4)

60693 Compass: clinical evaluation of a new instrument for the diagnosis of glaucoma
Autelitano A
PLoS ONE 2015; 10: e0122157 (IGR: 16-4)

60551 Structure-Function Correlation Using Confocal Laser Ophthalmoscope in Primary Open-Angle Glaucoma and Pseudoexfoliative Glaucoma
Ziakas N; Topouzis F
Journal of Glaucoma 2016; 25: 377-382 (IGR: 16-4)

60693 Compass: clinical evaluation of a new instrument for the diagnosis of glaucoma
Fogagnolo P
PLoS ONE 2015; 10: e0122157 (IGR: 16-4)

59594 Correlating cup-to-disc ratios measured by HRT-III, SD-OCT and the new color imaging Laguna ONhE procedure
Rodríguez Uña I; Méndez Hernández CD; Sáenz-Francés F; García Feijóo J
Archivos de la Sociedad Española de Oftalmologia 2015; 90: 212-219 (IGR: 16-3)

58918 Optic Nerve Head Deformation in Glaucoma: The Temporal Relationship between Optic Nerve Head Surface Depression and Retinal Nerve Fiber Layer Thinning
Xu G; Weinreb RN; Leung CK
Ophthalmology 2014; 121: 2362-2370 (IGR: 16-3)

59311 Influence of the Disc-Fovea Angle on Limits of RNFL Variability and Glaucoma Discrimination
Amini N; Nowroozizadeh S; Cirineo N; Henry S; Chang T; Chou T; Coleman AL; Caprioli J; Nouri-Mahdavi K
Investigative Ophthalmology and Visual Science 2014; 55: 7332-7342 (IGR: 16-3)

59656 Utility of Heidelberg retinal tomography as a screening tool for analyzing retinal nerve fiber layer defects
Belyea DA; Alhabshan RN; Mahesh SP; Gertner GS; Ibisevic MM; Habib AS; Dan JA
Clinical Ophthalmology 2014; 8: 2409-2414 (IGR: 16-3)

59323 Confocal Laser Scanning Tomography to Predict Visual Field Conversion in Patients With Ocular Hypertension and Early Glaucoma
Schrems-Hoesl LM; Schrems WA; Laemmer R; Horn FK; Juenemann AG; Kruse FE; Mardin CY
Journal of Glaucoma 2016; 25: 371-376 (IGR: 16-3)

58984 Comparison of Optic Nerve Head Topographic Parameters in Patients With Primary Open-Angle Glaucoma With and Without Diabetes Mellitus
Akkaya S; Can E; Oztürk F
Journal of Glaucoma 2016; 25: 49-53 (IGR: 16-3)

59603 Advanced Imaging for Glaucoma Study: Design, Baseline Characteristics, and Inter-Site Comparison
Le PV; Zhang X; Francis BA; Varma R; Greenfield DS; Schuman JS; Loewen N; Huang D;
American Journal of Ophthalmology 2015; 159: 393-403.e2 (IGR: 16-3)

59285 Confocal scanning laser tomography of the optic nerve head on the patients with Alzheimer's disease compared to glaucoma and control
Kurna SA; Akar G; Altun A; Agirman Y; Gozke E; Sengor T
International Ophthalmology 2014; 34: 1203-1211 (IGR: 16-3)

59537 Inter-test reference height variability - a major error factor in Heidelberg Retina Tomography glaucoma progression analysis based on stereometric parameters changes
Dascalu A; Stana D; Duta S; Ardeleanu I; Savlovschi C; Serban D; Cherecheanu A
Journal of medicine and life 2014; 7: 408-411 (IGR: 16-3)

59615 Predictive Value of Heidelberg Retina Tomograph Parameters for the Development of Glaucoma in the European Glaucoma Prevention Study
Miglior S; Zeyen T; Hoffmann EM; Torri V; Rulli E; Floriani I; Poli D; Aliyeva S; Cunha-Vaz J; Pfeiffer N
American Journal of Ophthalmology 2015; 159: 265-76.e1 (IGR: 16-3)

58922 Assessment of the optic disc morphology using spectral-domain optical coherence tomography and scanning laser ophthalmoscopy
Calvo P; Ferreras A; Abadia B; Ara M; Figus M; Pablo LE; Frezzotti P
BioMed research international 2014; 2014: 275654 (IGR: 16-3)

59404 Agreement among graders on Heidelberg retina tomograph (HRT) topographic change analysis (TCA) glaucoma progression interpretation
Iester MM; Wollstein G; Bilonick RA; Xu J; Ishikawa H; Kagemann L; Schuman JS
British Journal of Ophthalmology 2015; 99: 519-523 (IGR: 16-3)

59330 Combined assessment of early-stage primary open-angle glaucoma progression
Shpak AA; Sevost'ianova MK; Usol'tseva EA; Abdusadykova AK
Vestnik Oftalmologii 2014; 130: 14-17 (IGR: 16-3)

59210 Differences in Optic Disc Characteristics of Primary Congenital Glaucoma, Juvenile, and Adult Onset Open Angle Glaucoma Patients
Gupta V; James MK; Singh A; Kumar S; Gupta S; Sharma A; Sihota R; Kennedy DJ
Journal of Glaucoma 2016; 25: 239-243 (IGR: 16-3)

59086 In Vivo Confocal Microscopic Evaluation of Corneas in Patients With Exfoliation Syndrome
Kocabeyoglu S; Mocan MC; Irkec M; Karakaya J
Journal of Glaucoma 2016; 25: 193-197 (IGR: 16-3)

59477 Comparison of Optic Disc Morphology of Optic Nerve Atrophy between Compressive Optic Neuropathy and Glaucomatous Optic Neuropathy
Hata M; Miyamoto K; Oishi A; Makiyama Y; Gotoh N; Kimura Y; Akagi T; Yoshimura N
PLoS ONE 2014; 9: e112403 (IGR: 16-3)

57111 Does the ISNT Rule Apply to the Retinal Nerve Fiber Layer?
Pradhan ZS; Braganza A; Abraham LM
Journal of Glaucoma 2016; 25: e1-e4 (IGR: 16-2)

57521 Detecting abnormality in optic nerve head images using a feature extraction analysis
Zhu H; Poostchi A; Vernon SA; Crabb DP
Biomedical optics express 2014; 5: 2215-2230 (IGR: 16-2)

57020 Optic nerve head assessment: comparison of Cirrus optic coherence tomography and Heidelberg Retinal Tomograph 3
Kratz A; Lim R; Goldberg I
Clinical and Experimental Ophthalmology 2014; 42: 734-744 (IGR: 16-2)

57483 Optic disc tilt direction determines the location of initial glaucomatous damage
Choi JA; Park HY; Shin HY; Park CK
Investigative Ophthalmology and Visual Science 2014; 55: 4991-4998 (IGR: 16-2)

57249 Imaging of the optic disk in caring for patients with glaucoma: ophthalmoscopy and photography remain the gold standard
Spaeth GL; Reddy SC
Survey of Ophthalmology 2014; 59: 454-458 (IGR: 16-2)

57467 Reducing variability in visual field assessment for glaucoma through filtering that combines structural and functional information
Deng L; Demirel S; Gardiner SK
Investigative Ophthalmology and Visual Science 2014; 55: 4593-4602 (IGR: 16-2)

56992 Spontaneous retinal venous pulsation and disc hemorrhage in open-angle glaucoma
Kim M; Kim TW; Weinreb RN; Lee EJ; Seo JH
Investigative Ophthalmology and Visual Science 2014; 55: 2822-2826 (IGR: 16-2)

57516 Assessment of β-zone peripapillary atrophy by optical coherence tomography and scanning laser ophthalmoscopy imaging in glaucoma patients
Seidensticker F; Reznicek L; Mann T; Hübert I; Kampik A; Ulbig M; Hirneiss C; Neubauer AS; Kernt M
Clinical Ophthalmology 2014; 8: 1233-1239 (IGR: 16-2)

57265 Can an inexperienced observer accurately plot disc contours using Heidelberg retinal Tomograph?
Koh V; Wee S; Lim M; Wong WL; Wong TY; Aung T; Loon SC
Canadian Journal of Ophthalmology 2014; 49: 249-255 (IGR: 16-2)

57227 Comparison of Laser Scanning Diagnostic Devices for Early Glaucoma Detection
Schulze A; Lamparter J; Pfeiffer N; Berisha F; Schmidtmann I; Hoffmann EM
Journal of Glaucoma 2015; 24: 442-447 (IGR: 16-2)

57455 Optic nerve head morphology in glaucoma patients of African descent is strongly correlated to retinal blood flow
Kanakamedala P; Harris A; Siesky B; Tyring A; Muchnik M; Eckert G; Abrams Tobe L
British Journal of Ophthalmology 2014; 98: 1551-1554 (IGR: 16-2)

56998 Glaucoma Detection in High Myopia with the Heidelberg Retina Tomograph 3
Lee NY; Park HY; Park CK
Seminars in Ophthalmology 2015; 0: 6-jan (IGR: 16-2)

56910 Combining multiple HRT parameters using the 'Random Forests' method improves the diagnostic accuracy of glaucoma in emmetropic and highly myopic eyes
Asaoka R; Iwase A; Tsutsumi T; Saito H; Otani S; Miyata K; Murata H; Mayama C; Araie M
Investigative Ophthalmology and Visual Science 2014; 55: 2482-2490 (IGR: 16-2)

57176 Topographical Analysis of Non-Glaucomatous Myopic Optic Discs Using a Confocal Scanning Laser Ophthalmoscope (TopSS)
Oh SH; Chung SK; Lee NY
Seminars in Ophthalmology 2015; 0: 13-jan (IGR: 16-2)

57462 Agreement in identification of glaucomatous progression between the optic disc photography and Heidelberg retina tomography in young glaucomatous patients
Hentova-Sencanic P; Sencanic I; Trajković G; Bozic M; Bjelovic N
International Journal of Ophthalmology 2014; 7: 474-479 (IGR: 16-2)

56441 Rates of Retinal Nerve Fiber Layer Thinning in Glaucoma Suspect Eyes
Miki A; Medeiros FA; Weinreb RN; Jain S; He F; Sharpsten L; Khachatryan N; Hammel N; Liebmann JM; Girkin CA; Sample PA; Zangwill LM
Ophthalmology 2014; 121: 1350-1358 (IGR: 16-1)

55981 Longitudinal detection of optic nerve head changes by spectral domain optical coherence tomography in early experimental glaucoma
He L; Yang H; Gardiner SK; Williams G; Hardin C; Strouthidis NG; Fortune B; Burgoyne CF
Investigative Ophthalmology and Visual Science 2014; 55: 574-586 (IGR: 16-1)

56364 In Vivo Laser Scanning Confocal Microscopy of the Ocular Surface in Glaucoma
Mastropasqua L; Agnifili L; Mastropasqua R; Fasanella V; Nubile M; Toto L; Carpineto P; Ciancaglini M
Microscopy and microanalysis : the official journal of Microscopy Society of America, Microbeam Analysis Society, Microscopical Society of Canada 2014; 0: 1-16 (IGR: 16-1)

56614 Characteristics of optic disc parameters and its association in normal Chinese population: the Handan Eye Study
Zhang Q; Li S; Liang Y; Wang F; Chen W; Wang N
Chinese Medical Journal 2014; 127: 1702-1709 (IGR: 16-1)

56477 Comparing Optic Nerve Head Analysis Between Confocal Scanning Laser Ophthalmoscopy and Spectral Domain Optical Coherence Tomography
Roberti G; Centofanti M; Oddone F; Tanga L; Michelessi M; Manni G
Current Eye Research 2014; 39: 1026-1032 (IGR: 16-1)

56550 A unified framework for glaucoma progression detection using Heidelberg Retina Tomograph images
Belghith A; Balasubramanian M; Bowd C; Weinreb RN; Zangwill LM
Computerized Medical Imaging and Graphics 2014; 38: 411-420 (IGR: 16-1)

56035 Corneal biomechanical properties and glaucoma-related quantitative traits in the EPIC-Norfolk Eye Study
Khawaja AP; Chan MP; Broadway DC; Garway-Heath DF; Luben R; Yip JL; Hayat S; Khaw KT; Foster PJ
Investigative Ophthalmology and Visual Science 2014; 55: 117-124 (IGR: 16-1)

56267 Detecting glaucoma progression from localized rates of retinal changes in parametric and nonparametric statistical framework with type I error control
Balasubramanian M; Arias-Castro E; Medeiros FA; Kriegman DJ; Bowd C; Weinreb RN; Holst M; Sample PA; Zangwill LM
Investigative Ophthalmology and Visual Science 2014; 55: 1684-1695 (IGR: 16-1)

56599 Heidelberg Retina Tomography II parameters in evaluating high- and normal-pressure glaucoma progression
Risović D; Gvozdenović R; Marjanović I; Abazi Z; Stamenković M
Vojnosanitetski pregled. Military-medical and pharmaceutical review 2014; 71: 341-345 (IGR: 16-1)

56145 Bimatoprost 0.01% vs bimatoprost 0.03%: a 12-month prospective trial of clinical and in vivo confocal microscopy in glaucoma patients
Figus M; Nardi M; Piaggi P; Sartini M; Guidi G; Martini L; Lazzeri S
Eye 2014; 28: 422-429 (IGR: 16-1)

55197 Correlating perimetric indices with three nerve fiber layer thickness measures
Goren D; Demirel S; Fortune B; Gardiner SK
Optometry and Vision Science 2013; 90: 1353-1360 (IGR: 15-4)

55511 Evaluation of eye movements pattern during reading process in patients with glaucoma: a microperimeter study
Cerulli A; Cesareo M; Ciuffoletti E; Montanaro ML; Mancino R; Mirisola C; Sorge R; Cedrone C; Nucci C; Cerulli L
European Journal of Ophthalmology 2014; 24: 358-363 (IGR: 15-4)

55722 Clinical significance of optic disc progression by topographic change analysis maps in glaucoma: an 8-year follow-up study
Kourkoutas D; Buys YM; Flanagan JG; Karamaounas N; Georgopoulos G; Iliakis E; Moschos MM; Trope GE
Journal of Ophthalmology 2014; 2014: 987389 (IGR: 15-4)

55626 Glaucoma-induced optic disc morphometric changes and glaucoma diagnostic ability of Heidelberg Retina Tomograph II in highly myopic eyes
Mayama C; Tsutsumi T; Saito H; Asaoka R; Tomidokoro A; Iwase A; Otani S; Miyata K; Araie M
PLoS ONE 2014; 9: e86417 (IGR: 15-4)

55591 Imaging of the optic nerve and retinal nerve fiber layer: An essential part of glaucoma diagnosis and monitoring
Kotowski J; Wollstein G; Ishikawa H; Schuman JS
Survey of Ophthalmology 2014; 59: 458-467 (IGR: 15-4)

55117 Laser scanning tomography in the EPIC-Norfolk Eye Study: principal components and associations
Khawaja AP; Chan MP; Broadway DC; Garway-Heath DF; Luben R; Yip JL; Hayat S; Khaw KT; Foster PJ
Investigative Ophthalmology and Visual Science 2013; 54: 6638-6645 (IGR: 15-4)

55643 Logistic regression analysis in the combination of diagnostic methods in glaucoma
Fasolo LR; Melo LA; Barbosa AS; Fernandes RA; Prata JA
Arquivos Brasileiros de Oftalmologia 2013; 76: 341-344 (IGR: 15-4)

55513 Detecting an event of progression using glaucoma probability score and the stereometric parameters of Heidelberg Retina Tomograph 3
Saarela V; Falck A; Tuulonen A
European Journal of Ophthalmology 2013; 0: 0 (IGR: 15-4)

55666 Assessment of the optic nerve head parameters using Heidelberg retinal tomography III in preterm children
Alshaarawi S; Shatriah I; Zunaina E; Wan Hitam WH
PLoS ONE 2014; 9: e88056 (IGR: 15-4)

54578 Evaluation of Progressive Neuroretinal Rim Loss as a Surrogate End Point for Development of Visual Field Loss in Glaucoma
Medeiros FA; Lisboa R; Zangwill LM; Liebmann JM; Girkin CA; Bowd C; Weinreb RN
Ophthalmology 2014; 121: 100-109 (IGR: 15-3)

54753 Variability and reproducibility of 3 methods for measuring the thickness of the nerve fiber layer
Sá,nchez-Garcí,a M; Rodrí,guez de la Vega R; Gonzá,lez-Herná,ndez M; Gonzá,lez de la Rosa M
Archivos de la Sociedad Española de Oftalmologia 2013; 88: 393-397 (IGR: 15-3)

54669 Comparison of Heidelberg retina tomography, optical coherence tomography and Humphrey visual field in early glaucoma diagnosis
Wang H; Tao Y; Sun XL; Zhuang K
Journal of International Medical Research 2013; 41: 1594-1605 (IGR: 15-3)

54742 Diagnostic Performance of the ISNT Rule for Glaucoma Based on the Heidelberg Retinal Tomograph
Chan EW; Liao J; Wong R; Loon SC; Aung T; Wong TY; Cheng CY
Translational vision science & technology 2013; 2: 2 (IGR: 15-3)

54787 Cirrus High-definition Optical Coherence Tomography Versus Spectral Optical Coherence Tomography/Scanning Laser Ophthalmoscopy in the Diagnosis of Glaucoma
Koh KM; Jin S; Hwang YH
Current Eye Research 2014; 39: 62-68 (IGR: 15-3)

54838 Optic disc topography of normal tension glaucoma patients in Malaysia
Adlina AR; Shatriah I; Liza Sharmini AT; Ahmad MS
Medical Journal of Malaysia 2013; 68: 338-342 (IGR: 15-3)

54761 Effects of optic disc size on progression of visual field defects in normal-tension glaucoma
Hayamizu F; Yamazaki Y
Nippon Ganka Gakkai Zasshi 2013; 117: 609-615 (IGR: 15-3)

54048 3D modeling to characterize lamina cribrosa surface and pore geometries using in vivo images from normal and glaucomatous eyes
Sredar N; Ivers KM; Queener HM; Zouridakis G; Porter J
Biomedical optics express 2013; 4: 1153-1165 (IGR: 15-2)

54038 Comparison of reliability of the eye optic disc cup and pallor areas in glaucoma diagnostics
Pluhácek F; Wagner J
Collegium Antropologicum 2013; 37: 59-63 (IGR: 15-2)

53929 Specifity of Optic Disc Evaluation in Healthy Subjects with Large Optic Discs and Physiologic Cupping Using Confocal Scanning Laser Ophthalmoscopy
Plange N; Hirsch T; Bienert M; Remky A
Klinische Monatsblätter für Augenheilkunde 2014; 231: 164-169 (IGR: 15-2)

53791 The Heidelberg retina tomograph ancillary study to the European glaucoma prevention study: study design and baseline factors
Hoffmann EM; Miglior S; Zeyen T; Torri V; Rulli E; Aliyeva S; Floriani I; Cunha-Vaz J; Pfeiffer N
Acta Ophthalmologica 2013; 91: e612-e619 (IGR: 15-2)

53584 Retinal nerve fibre layer imaging: comparison of Cirrus optical coherence tomography and Heidelberg retinal tomograph 3
Kratz A; Lim R; Rush R; Sheth S; Goldberg I
Clinical and Experimental Ophthalmology 2013; 41: 853-863 (IGR: 15-2)

53654 Optic Nerve Diffusion Tensor Imaging Parameters and Their Correlation With Optic Disc Topography and Disease Severity in Adult Glaucoma Patients and Controls
Chang ST; Xu J; Trinkaus K; Pekmezci M; Arthur SN; Song SK; Barnett EM
Journal of Glaucoma 2014; 23: 513-520 (IGR: 15-2)

53763 Corneal changes assessed using confocal microscopy in patients with unilateral buphthalmos
Mahelková G; Filous A; Odehnal M; Cendelín J
Investigative Ophthalmology and Visual Science 2013; 54: 4048-4053 (IGR: 15-2)

53650 Evaluation of the Effect of Pan Retinal Photocoagulation on Optic Nerve Head Parameters Using HRT3
Singh H; Garg S; Sharma R; Venkatesh P; Saxena R; Dada T
Journal of Glaucoma 2014; 23: 467-470 (IGR: 15-2)

52728 Comparison of functional and morphological diagnostics in glaucoma patients and healthy subjects
Klamann MK; Grünert A; Maier AK; Gonnermann J; Joussen AM; Huber KK
Ophthalmic Research 2013; 49: 192-198 (IGR: 15-1)

52807 Agreement between frequency-doubling technology perimetry and Heidelberg retinal tomography 3
Lee NY; Chung HJ; Park CK
Japanese Journal of Ophthalmology 2013; 57: 252-256 (IGR: 15-1)

52888 Oculus-Spark perimetry compared with 3 procedures of glaucoma morphologic analysis (GDx, HRT, and OCT)
Gonzalez de la Rosa M; Gonzalez-Hernandez M; Sanchez-Garcia M; Rodriguez de la Vega R; Diaz-Aleman T; Pareja Rios A
European Journal of Ophthalmology 2013; 23: 316-323 (IGR: 15-1)

52872 The role of confocal scanning laser ophthalmoscopy in stereometric differentiation of eye papilla in ocular hypertension, normal tension glaucoma and primary open-angle glaucoma
Gvozdenović R; Risović D; Marjanović I; Stamenković M; Joković Z; Abazi Z
Vojnosanitetski pregled. Military-medical and pharmaceutical review 2013; 70: 304-308 (IGR: 15-1)

53115 Linear discriminant functions to improve the glaucoma probability score analysis to detect glaucomatous optic nerve heads: a multicenter study
Iester M; Oddone F; Prato M; Centofanti M; Fogagnolo P; Rossetti L; Vaccarezza V; Manni G; Ferreras A
Journal of Glaucoma 2013; 22: 73-79 (IGR: 15-1)

53180 High-resolution imaging of retinal nerve fiber bundles in glaucoma using adaptive optics scanning laser ophthalmoscopy
Takayama K; Ooto S; Hangai M; Ueda-Arakawa N; Yoshida S; Akagi T; Ikeda HO; Nonaka A; Hanebuchi M; Inoue T; Yoshimura N
American Journal of Ophthalmology 2013; 155: 870-881 (IGR: 15-1)

53213 The rate of structural change: the confocal scanning laser ophthalmoscopy ancillary study to the ocular hypertension treatment study
Zangwill LM; Jain S; Dirkes K; He F; Medeiros FA; Trick GL; Brandt JD; Cioffi GA; Coleman AL; Liebmann JM; Piltz-Seymour JR; Gordon MO; Kass MA; Weinreb RN;
American Journal of Ophthalmology 2013; 155: 971-982 (IGR: 15-1)

53141 Relationship between diastolic perfusion pressure and progressive optic neuropathy as determined by Heidelberg retinal tomography topographic change analysis
Quaid P; Simpson T; Freddo T
Investigative Ophthalmology and Visual Science 2013; 54: 789-798 (IGR: 15-1)

52457 Morphological and functional differences between normal-tension and high-tension glaucoma
Häntzschel J; Terai N; Sorgenfrei F; Haustein M; Pillunat K; Pillunat LE
Acta Ophthalmologica 2013; 91: e386-e391 (IGR: 15-1)

53068 Branch retinal vein occlusion and optic nerve head topographic parameters: the Singapore Indian eye study
Chan EW; Wong TY; Liao J; Cheung CY; Zheng YF; Wang JJ; Mitchell P; Loon SC; Saw SM; Aung T; Cheng CY
British Journal of Ophthalmology 2013; 97: 611-616 (IGR: 15-1)

52431 Optic Disc and Retinal Nerve Fiber Layer Thickness Descriptive Analysis in Megalopapilla
da Costa AM; Cronemberger S
Journal of Glaucoma 2014; 23: 368-371 (IGR: 15-1)

51710 Structure-function relationship between FDF, FDT, SAP, and scanning laser ophthalmoscopy in glaucoma patients
Lamparter J; Russell RA; Schulze A; Schuff AC; Pfeiffer N; Hoffmann EM
Investigative Ophthalmology and Visual Science 2012; 53: 7553-7559 (IGR: 14-4)

51802 Test-retest variability in structural parameters measured with glaucoma imaging devices
Araie M
Japanese Journal of Ophthalmology 2013; 57: 1-24 (IGR: 14-4)

51913 Symmetry of optic nerve head parameters measured by the heidelberg retina tomograph 3 in healthy eyes: the blue mountains eye study
Li H; Healey PR; Tariq YM; Teber E; Mitchell P
American Journal of Ophthalmology 2013; 155: 518-523.e1 (IGR: 14-4)

51750 Glaucoma diagnosis optic disc analysis comparing Cirrus spectral domain optical coherence tomography and Heidelberg retina tomograph II
Shin HY; Park HY; Jung KI; Park CK
Japanese Journal of Ophthalmology 2013; 57: 41-46 (IGR: 14-4)

51693 Evaluation of baseline structural factors for predicting glaucomatous visual-field progression using optical coherence tomography, scanning laser polarimetry and confocal scanning laser ophthalmoscopy
Sehi M; Bhardwaj N; Chung YS; Greenfield DS;
Eye 2012; 26: 1527-1535 (IGR: 14-4)

52081 Morphometric characteristics of optic disc in patients with myopia and primary open-angle glaucoma
Gvozdenović R; Risović D; Marjanović I; Vuković D; Stanković B
Vojnosanitetski pregled. Military-medical and pharmaceutical review 2013; 70: 51-56 (IGR: 14-4)

51994 In vivo confocal microscopy of meibomian glands in glaucoma
Agnifili L; Fasanella V; Costagliola C; Ciabattoni C; Mastropasqua R; Frezzotti P; Mastropasqua L
British Journal of Ophthalmology 2013; 97: 343-349 (IGR: 14-4)

50883 The relationship between subbasal nerve morphology and corneal sensation in ocular surface disease
Labbé A; Alalwani H; Van Went C; Brasnu E; Georgescu D; Baudouin C
Investigative Ophthalmology and Visual Science 2012; 53: 4926-4931 (IGR: 14-3)

50945 Optic nerve complex imaging in glaucoma Medicare beneficiaries
Swamy L; Smith S; Radcliffe NM
Ophthalmic Epidemiology 2012; 19: 249-255 (IGR: 14-3)

51190 Evaluation of Optic Nerve Head Using a Newly Developed Stereo Retinal Imaging Technique by Glaucoma Specialist and Non-Expert-Certified Orthoptist
Asakawa K; Kato S; Shoji N; Morita T; Shimizu K
Journal of Glaucoma 2013; 22: 698-706 (IGR: 14-3)

50821 Measurement of optic disc size and rim area with spectral-domain OCT and scanning laser ophthalmoscopy
Moghimi S; Hosseini H; Riddle J; Lee GY; Bitrian E; Giaconi J; Caprioli J; Nouri-Mahdavi K
Investigative Ophthalmology and Visual Science 2012; 53: 4519-4530 (IGR: 14-3)

51297 Comparative analysis of morphometric optic nerve head parameters in patients with open-angle glaucoma according to optical coherence tomography and retinal tomography
Golubina LA; Kharintseva SV; Zimina MG; Derevtsova KA
Vestnik Oftalmologii 2012; 128: 32-34 (IGR: 14-3)

50899 Characteristics of optic disc morphology in glaucoma patients with parafoveal scotoma compared to peripheral scotoma
Jung KI; Park HY; Park CK
Investigative Ophthalmology and Visual Science 2012; 53: 4813-4820 (IGR: 14-3)

51320 Glaucoma risk assessment using a non-linear multivariable regression method
Kourkoutas D; Karanasiou IS; Tsekouras GJ; Moshos M; Iliakis E; Georgopoulos G
Computer Methods and Programs in Biomedicine 2012; 108: 1149-1159 (IGR: 14-3)

51106 Diagnosing preperimetric glaucoma with spectral domain optical coherence tomography
Lisboa R; Leite MT; Zangwill LM; Tafreshi A; Weinreb RN; Medeiros FA
Ophthalmology 2012; 119: 2261-2269 (IGR: 14-3)

50666 In vivo confocal microscopy and ultrasound biomicroscopy study of filtering blebs after trabeculectomy: limbus-based versus fornix-based conjunctival flaps
Morita K; Gao Y; Saito Y; Higashide T; Kobayashi A; Ohkubo S; Sugiyama K
Journal of Glaucoma 2012; 21: 383-391 (IGR: 14-3)

50269 The effect of test variability on the structure-function relationship in early glaucoma
Gardiner SK; Johnson CA; Demirel S
Graefe's Archive for Clinical and Experimental Ophthalmology 2012; 250: 1851-1861 (IGR: 14-2)

49985 Performance of imaging devices versus optic disc and fiber layer photography in a clinical practice guideline for glaucoma diagnosis
Gü,erri N; Polo V; Larrosa JM; Ferreras A; Fuertes I; Pablo LE
European Journal of Ophthalmology 2012; 22: 554-562 (IGR: 14-2)

50382 Predictive value of confocal scanning laser for the onset of visual field loss in glaucoma suspects
Larrosa JM; Polo V; Ferreras A; Gil L; Fuertes I; Pablo LE
Ophthalmology 2012; 119: 1558-1562 (IGR: 14-2)

50485 In vivo imaging of lamina cribrosa pores by adaptive optics scanning laser ophthalmoscopy
Akagi T; Hangai M; Takayama K; Nonaka A; Ooto S; Yoshimura N
Investigative Ophthalmology and Visual Science 2012; 53: 4111-4119 (IGR: 14-2)

50394 Correlation of structural RNFL parameters and functional measures using HRT3 and Spectralis SD-OCT at different levels of glaucoma severity
Leaney J; Healey PR; Lee M; Graham SL
Clinical and Experimental Ophthalmology 2012; 40: 802-812 (IGR: 14-2)

50628 Longitudinal structure-function relationships with scanning laser ophthalmoscopy and standard achromatic perimetry
Nassiri N; Nilforushan N; Coleman AL; Law SK; Caprioli J; Nouri-Mahdavi K
Archives of Ophthalmology 2012; 130: 826-832 (IGR: 14-2)

50369 Comparison of Neuroretinal Rim Area Measurements Made by the Heidelberg Retina Tomograph I and the Heidelberg Retina Tomograph II
Wang YX; O'Leary N; Strouthidis NG; White ET; Ho TA; Garway-Heath DF
Journal of Glaucoma 2013; 22: 652-658 (IGR: 14-2)

50392 Quantitative evaluation of anterior chamber parameters using anterior segment optical coherence tomography in primary angle closure mechanisms
Shabana N; Aquino MC; See J; Ce Z; Tan AM; Nolan WP; Hitchings R; Young SM; Loon SC; Chew PT
Clinical and Experimental Ophthalmology 2012; 40: 792-801 (IGR: 14-2)

50600 Evaluation of the significance of some diagnostic parameters in making an early diagnose of primary open-angle glaucoma
Polaczek-Krupa B; Grabska-Liberek I
Medical Science Monitor 2012; 18: CR456-460 (IGR: 14-2)

50204 Localized Glaucomatous Change Detection within the Proper Orthogonal Decomposition Framework
Balasubramanian M; Kriegman DJ; Bowd C; Holst M; Weinreb RN; Sample PA; Zangwill LM
Investigative Ophthalmology and Visual Science 2012; 53: 3615-3628 (IGR: 14-2)

50361 Optic Disc Imaging with Spectral-Domain Optical Coherence Tomography: Variability and Agreement Study with Heidelberg Retinal Tomograph
Yang B; Ye C; Yu M; Liu S; Lam DS; Leung CK
Ophthalmology 2012; 119: 1852-1857 (IGR: 14-2)

50197 Choroidal thickness in open-angle glaucoma measured by spectral-domain scanning laser ophthalmoscopy/optical coherence tomography
Cennamo G; Finelli M; Iaccarino G; de Crecchio G
Ophthalmologica 2012; 228: 47-52 (IGR: 14-2)

50467 Evaluating Objective and Subjective Quantitative Parameters at the Initial Visit to Predict Future Glaucomatous Visual Field Progression
Ungar AK; Wollstein G; Ishikawa H; Folio LS; Ling Y; Bilonick RA; Noecker RJ; Xu J; Kagemann L; Mattox C; Schuman JS
Ophthalmic Surgery Lasers and Imaging 2012; 0: 1-9 (IGR: 14-2)

50439 3-T Diffusion tensor imaging of the optic nerve in subjects with glaucoma: correlation with GDx-VCC, HRT-III and Stratus optical coherence tomography findings
Nucci C; Mancino R; Martucci A; Bolacchi F; Manenti G; Cedrone C; Culasso F; Floris R; Cerulli L; Garaci FG
British Journal of Ophthalmology 2012; 96: 976-980 (IGR: 14-2)

50357 Glaucomatous optic nerve head alterations in patients with chronic heart failure
Meira-Freitas D; Melo LA; Almeida-Freitas DB; Paranhos A
Clinical Ophthalmology 2012; 6: 623-629 (IGR: 14-2)

49239 Association between corneal biomechanical properties and optic nerve head morphology in newly diagnosed glaucoma patients
Prata TS; Lima VC; Guedes LM; Biteli LG; Teixeira SH; De Moraes CG; Ritch R; Paranhos A
Clinical and Experimental Ophthalmology 2012; 40: 682-688 (IGR: 14-1)

49155 Comparison of optic nerve head parameters using Heidelberg retinal tomography 3 and spectral-domain optical coherence tomography
Sato S; Hirooka K; Baba T; Shiraga F
Clinical and Experimental Ophthalmology 2012; 40: 721-726 (IGR: 14-1)

49114 DTI parameters of axonal integrity and demyelination of the optic radiation correlate with glaucoma indices
Michelson G; Engelhorn T; Wä,rntges S; El Rafei A; Hornegger J; Doerfler A
Graefe's Archive for Clinical and Experimental Ophthalmology 2013; 251: 243-253 (IGR: 14-1)

48863 Trends in use of ancillary glaucoma tests for patients with open-angle glaucoma from 2001 to 2009
Stein JD; Talwar N; Laverne AM; Nan B; Lichter PR
Ophthalmology 2012; 119: 748-758 (IGR: 14-1)

49046 Laser-scanning-tomography in clinical routine
Burk RO
Klinische Monatsblätter für Augenheilkunde 2012; 229: 119-125 (IGR: 14-1)

49289 Factors associated with anterior chamber narrowing with age: an optical coherence tomography study
Sun JH; Sung KR; Yun SC; Cheon MH; Tchah H; Kim MJ; Kim JY
Investigative Ophthalmology and Visual Science 2012; 53: 2607-2610 (IGR: 14-1)

48569 Cup size predicts subsequent functional change in early glaucoma
Gardiner SK; Johnson CA; Demirel S
Optometry and Vision Science 2011; 88: 1470-1476 (IGR: 14-1)

48440 Combined evaluation of frequency doubling technology perimetry and scanning laser ophthalmoscopy for glaucoma detection using automated classification
Horn FK; Lä,mmer R; Mardin CY; Jü,nemann AG; Michelson G; Lausen B; Adler W
Journal of Glaucoma 2012; 21: 27-34 (IGR: 14-1)

49313 Scanning laser topography and scanning laser polarimetry: comparing both imaging methods at same distances from the optic nerve head
Kremmer S; Keienburg M; Anastassiou G; Schallenberg M; Steuhl KP; Selbach JM
Open Ophthalmology Journal 2012; 6: 6-16 (IGR: 14-1)

49269 Comparison of optic disc parameters using spectral domain cirrus high-definition optical coherence tomography and confocal scanning laser ophthalmoscopy in normal eyes
Resch H; Deak G; Pereira I; Vass C
Acta Ophthalmologica 2012; 90: e225-229 (IGR: 14-1)

49231 Predicting glaucomatous progression in glaucoma suspect eyes using relevance vector machine classifiers for combined structural and functional measurements
Bowd C; Lee I; Goldbaum MH; Balasubramanian M; Medeiros FA; Zangwill LM; Girkin CA; Liebmann JM; Weinreb RN
Investigative Ophthalmology and Visual Science 2012; 53: 2382-2389 (IGR: 14-1)

49013 Combining Structural and Functional Measurements to Improve Estimates of Rates of Glaucomatous Progression
Medeiros FA; Zangwill LM; Girkin CA; Liebmann JM; Weinreb RN
American Journal of Ophthalmology 2012; 153: 1197-1205 (IGR: 14-1)

48926 Glaucoma versus red disease: imaging and glaucoma diagnosis
Chong GT; Lee RK
Current Opinions in Ophthalmology 2012; 23: 79-88 (IGR: 14-1)

47734 Defining glaucomatous optic neuropathy from a continuous measure of optic nerve damage the optimal cut-off point for risk-factor analysis in population-based epidemiology
Ramdas WD; Rizopoulos D; Wolfs RCW; Hofman A; de Jong PTVM; Vingerling JR; Jansonius NM
Ophthalmic Epidemiology 2011; 18: 211-216 (IGR: 13-4)

48019 Conjunctival findings in hyperbaric and low-tension glaucoma: An in vivo confocal microscopy study
Agnifili L; Carpineto P; Fasanella V; Mastropasqua R; Zappacosta A; Di Staso S; Costagliola C; Mastropasqua L
Acta Ophthalmologica 2011; (IGR: 13-4)

47860 Topographic differences between large and normal optic discs: A confocal scanning laser ophthalmoscopy study
Cankaya AB; Simsek T
European Journal of Ophthalmology 2011; 22: 63-69 (IGR: 13-4)

48307 Comparison of retinal nerve fiber layer imaging by spectral domain optical coherence tomography and scanning laser ophthalmoscopy
Ye C; To E; Weinreb RN; Yu M; Liu S; Lam DS; Leung CK
Ophthalmology 2011; 118: 2196-2202 (IGR: 13-4)

47733 Heidelberg Retina Tomograph (HRT3) in population-based epidemiology: Normative values and criteria for glaucomatous optic neuropathy
Ramdas WD; Wolfs RCW; Hofman A; de Jong PTVM; Vingerling JR; Jansonius NM
Ophthalmic Epidemiology 2011; 18: 198-210 (IGR: 13-4)

48386 Optic disc classification by the Heidelberg Retina Tomograph and by physicians with varying experience of glaucoma
Andersson S; Heijl A; Bengtsson B
Eye 2011; 25: 1401-1407 (IGR: 13-4)

47765 African descent and glaucoma evaluation study: Asymmetry of structural measures in normal participants
Moore GH; Bowd C; Medeiros FA; Sample PA; Liebmann JM; Girkin CA; Leite MT; Weinreb RN; Zangwill LM
Journal of Glaucoma 2011; (IGR: 13-4)

48064 Comparison of different methods of inter-eye asymmetry of rim area and disc area analysis
Fansi AA; Boisjoly H; Chagnon M; Harasymowycz PJ
Eye 2011; 25: 1590-1597 (IGR: 13-4)

47763 Linear discriminant functions to improve the glaucoma probability score analysis to detect glaucomatous optic nerve heads: A multicenter study
Iester M; Oddone F; Prato M; Centofanti M; Fogagnolo P; Rossetti L; Vaccarezza V; Manni G; Ferreras A
Journal of Glaucoma 2011; (IGR: 13-4)

48353 The optic nerve head assessed with HRT in 5-16-year-old normal children: normal values, repeatability and interocular difference
Larsson E; Nuija E; Alm A
Acta Ophthalmologica 2011; 89: 755-758 (IGR: 13-4)

47629 Rates of Change in the Visual Field and Optic Disc in Patients with Distinct Patterns of Glaucomatous Optic Disc Damage
Reis ASC; Artes PH; Belliveau AC; Leblanc RP; Shuba LM; Chauhan BC; Nicolela MT
Ophthalmology 2011; (IGR: 13-4)

47805 Quantification of retinal nerve fiber layer thickness after unilateral acute primary angle closure in Asian Indian eyes
Mansoori T; Viswanath K; Balakrishna N
Journal of Glaucoma 2011; (IGR: 13-4)

47797 Comparison of optic disc topography in the cases with graves disease and healthy controls
Sen E; Berker D; Elgin U; Tutuncu Y; Ozturk F; Guler S
Journal of Glaucoma 2011; (IGR: 13-4)

46363 Screening for glaucoma with Moorfields regression analysis and glaucoma probability score in confocal scanning laser ophthalmoscopy
Kamdeu Fansi AA; Agoumi Y; Harasymowycz PJ
Canadian Journal of Ophthalmology 2011; 46: 254-260 (IGR: 13-3)

46364 Combining rim area to disc area asymmetry ratio and Moorfields regression analysis of confocal scanning laser ophthalmoscopy for glaucoma screening
Kamdeu Fansi AA; Boisjoly H; Chagnon M; Harasymowycz PJ
Canadian Journal of Ophthalmology 2011; 46: 261-266 (IGR: 13-3)

46814 The "iSN'T rule" in healthy participant optic nerve head by confocal scanning laser ophthalmoscopy
Iester M; Bertolotto M; Recupero SM; Perdicchi A
Journal of Glaucoma 2011; 20: 350-354 (IGR: 13-3)

47075 The relationship between central corneal thickness and optic disc size in patients with primary open-angle glaucoma in a hospital-based population
Terai N; Spoerl E; Pillunat LE; Kuhlisch E; Schmidt E; Boehm AG
Acta Ophthalmologica 2011; 89: 556-559 (IGR: 13-3)

46949 Correlation between humphrey visual field, optical coherence tomography and heidelberg retina tomograph parameters in primary open-angle glaucoma, normal-tension glaucoma and ocular hypertension
Ayhan Z; Arikan G; Gunenc U; Cingil G
Turk Oftalmoloiji Dergisi 2011; 41: 143-150 (IGR: 13-3)

46588 Evaluation of stereometric parameters of optic disc and nerve fiber layer using HRT II. Report 3: measurement error of spectral-domain optical coherence tomography compared with Heidelberg retinal tomograph III
Shak AA; Malakhanova MK; Ogorodnikova SN
Vestnik Oftalmologii 2011; 127: 46-49 (IGR: 13-3)

46828 Comparing stereometric parameters between heidelberg retinal tomography 2 and 3 in Asian eyes: The Singapore Malay eye study
Koh V; Loon SC; Wong W-L; Wong TY; Aung T
Journal of Glaucoma 2011; (IGR: 13-3)

46591 Evaluation of stereometric parameters of optic disc and nerve fiber layer using HRT III. Report 1: reproducibility and intraobserver variability coefficients
Shak AA; Malakhanova MK; Shormaz IN
Vestnik Oftalmologii 2011; 127: 40-43 (IGR: 13-3)

46589 Evaluation of stereometric parameters of optic disc and nerve fiber layer using HRT III. Report 2: factors influencing reproducibility
Shpak AA; Malakhanova MK; Shormaz IN
Vestnik Oftalmologii 2011; 127: 43-46 (IGR: 13-3)

46359 Influence of refractive error on optic disc topographic parameters: the Singapore malay eye study
Wu RY; Wong TY; Zheng YF; Cheung CY; Perera SA; Saw SM; Aung T
American Journal of Ophthalmology 2011; 152: 81-86 (IGR: 13-3)

46731 Comparison of measurement error of Cirrus HD-OCT and Heidelberg Retina Tomograph 3 in patients with early glaucomatous visual field defect
Shpak AA; Sevostyanova MK; Ogorodnikova SN; Shormaz IN
Graefe's Archive for Clinical and Experimental Ophthalmology 2011; (IGR: 13-3)

46385 Reproducibility of measuring lamina cribrosa pore geometry in human and nonhuman primates with in vivo adaptive optics imaging
Ivers KM; Li C; Patel N; Sredar N; Luo X; Queener H; Harwerth RS; Porter J
Investigative Ophthalmology and Visual Science 2011; 52: 5473-5480 (IGR: 13-3)

46487 Factors affecting the variability of the Heidelberg Retina Tomograph III measurements in newly diagnosed glaucoma patients
Prata TS; Meira-Freitas D; Lima VC; Guedes LM; Magalhaes FP; Junior AP
Arquivos Brasileiros de Oftalmologia 2010; 73: 354-357 (IGR: 13-3)

46637 Retinal Nerve Fiber Layer Imaging with Spectral Domain OCT: Comparison with Scanning Laser Tomograph Reflectance Image
Ye C; To E; Weinreb RN; Yu M; Liu S; Lam DSC; Leung CKS
Ophthalmology 2011; (IGR: 13-3)

46816 Comparison of optic disc parameters measured by RTVue-100 FDOCT versus HRT-II
Mesiwala NK; Pekmezci M; Huang J-Y; Porco TC; Lin SC
Journal of Glaucoma 2011; (IGR: 13-3)

46594 Comparative analysis of several morphometric parameters received using optic coherent tomography and scanning laser ophthalmoscopy in initial glaucoma diagnosis
Mamikonian VR; Kazarian EE; Gloian NS; Shmeleva-Demir OA
Vestnik Oftalmologii 2011; 127: 18-20 (IGR: 13-3)

46386 Visualization of fundus vessel pulsation using principal component analysis
Moret F; Poloschek CM; Lagrèze WA; Bach M
Investigative Ophthalmology and Visual Science 2011; 52: 5457-5464 (IGR: 13-3)

46630 Evaluation of retinal nerve fiber layer progression in glaucoma: A prospective analysis with neuroretinal rim and visual field progression
Leung CKS; Liu S; Weinreb RN; Lai G; Ye C; Cheung CYL; Pang CP; Tse KK; Lam DSC
Ophthalmology 2011; 118: 1551-1557 (IGR: 13-3)

46164 Evaluation of a combined index of optic nerve structure and function for glaucoma diagnosis
Boland MV; Quigley HA
BMC Ophthalmology 2011; 11: 6 (IGR: 13-2)

46196 Structure and function in patients with glaucomatous defects near fixation
Shafi A; Swanson WH; Dul MW
Optometry and Vision Science 2011; 88: 130-139 (IGR: 13-2)

46202 Agreement between the Heidelberg Retina Tomograph (HRT) stereometric parameters estimated using HRT-I and HRT-II
Balasubramanian M; Bowd C; Weinreb RN; Zangwill LM
Optometry and Vision Science 2011; 88: 140-149 (IGR: 13-2)

45863 Ability of Heidelberg Retina Tomograph III to predict progression in patients with early glaucoma or suspected primary open-angle glaucoma
Garcia-Martin E; Pablo L; Ferreras A; Idoipe M; Perez S; Pueyo V
Archivos de la Sociedad Española de Oftalmologia 2010; 85: 138-143 (IGR: 13-2)

45988 Effect of optic disc size and disease severity on the diagnostic capability of glaucoma imaging technologies in an Indian population
Garudadri CS; Rao HL; Parikh RS; Jonnadula GB; Selvaraj P; Nutheti R; Thomas R
Journal of Glaucoma 2011; (IGR: 13-2)

45508 Change in optic nerve head topography in healthy volunteers: an 11-year follow-up
Harju M; Kurvinen L; Saari J; Vesti E
British Journal of Ophthalmology 2011; 95: 818-821 (IGR: 13-2)

46008 The use of HRT with and without the aid of disc photographs
Loon SC; Tong L; Gazzard G; Chan YH; Sim EL; Aung T; Tan DTH; Healey PR; Wong TY; Koh V
Journal of Glaucoma 2011; 20: 207-210 (IGR: 13-2)

45833 Role of imaging in glaucoma diagnosis and follow-up
Vizzeri G; Kjaergaard S; Rao H; Zangwill L
Indian Journal of Ophthalmology 2011; 59: 59-68 (IGR: 13-2)

45770 Influence of Disc Size on Optic Nerve Head versus Retinal Nerve Fiber Layer Assessment for Diagnosing Glaucoma
Oddone F; Centofanti M; Tanga L; Parravano M; Michelessi M; Schiavone M; Villani CM; Fogagnolo P; Manni G
Ophthalmology 2011; 118: 1340-1347 (IGR: 13-2)

46032 Morphometric analysis and classification of glaucomatous optic neuropathy using radial polynomials
Twa MD; Parthasarathy S; Johnson CA; Bullimore MA
Journal of Glaucoma 2011; (IGR: 13-2)

46285 Correlation of optic disc morphology and ocular perfusion parameters in patients with primary open angle glaucoma
Resch H; Schmidl D; Hommer A; Rensch F; Jonas JB; Fuchsjager-Mayrl G; Garhofer G; Vass C; Schmetterer L
Acta Ophthalmologica 2011; (IGR: 13-2)

45765 Evaluation of Retinal Nerve Fiber Layer Progression in Glaucoma. A Prospective Analysis with Neuroretinal Rim and Visual Field Progression
Leung CKS; Liu S; Weinreb RN; Lai G; Ye C; Cheung CYL; Pang CP; Tse KK; Lam DSC
Ophthalmology 2011; (IGR: 13-2)

45902 Changes in retinal nerve fibre layer, optic nerve head morphology, and visual field after acute primary angle closure
Sng CCA; See JSL; Ngo CS; Singh M; Chan Y-H; Aquino MC; Tan AM; Shabana N; Chew PTK
Eye 2011; 25: 619-625 (IGR: 13-2)

45579 Patterns of Damage in Chronic Angle-Closure Glaucoma Compared to Primary Open-Angle Glaucoma
Nouri-Mahdavi K; Supawavej C; Bitrian E; Giaconi JA; Law SK; Coleman AL; Caprioli J
American Journal of Ophthalmology 2011; (IGR: 13-2)

46282 Non-contact in vivo confocal scanning laser microscopy in exfoliation syndrome, exfoliation syndrome suspect and normal eyes
Sbeity Z; Palmiero P-M; Tello C; Liebmann JM; Ritch R
Acta Ophthalmologica 2011; 89: 241-247 (IGR: 13-2)

45694 Reversal of optic disc cupping with improvement of visual field and stereometric parameters after trabeculectomy in young adult patients (two case reports)
Swinnen S; Stalmans A; Zeyen T
Bulletin de la Société Belge d'Ophtalmologie 2010; 316: 49-57 (IGR: 13-2)

27711 Retinal nerve fibre layer thickness in full-term children assessed with Heidelberg retinal tomography and optical coherence tomography: normal values and interocular asymmetry
Larsson E; Eriksson U; Alm A
Acta Ophthalmologica 2011; 89: 151-158 (IGR: 13-1)

27747 Relationship of Central Corneal Thickness with Optic Disc Parameters: The Singapore Malay Eye Study
Wu R-Y; Zheng Y-F; Wong T-Y; Cheung CY-L; Loon S-C; Chauhan BC; Aung T
Investigative Ophthalmology and Visual Science 2011; 52: 1320-1324 (IGR: 13-1)

27842 Retinal nerve fibre layer evaluation in ocular hypertensive eyes using optical coherence tomography and scanning laser polarimetry in the diagnosis of early glaucomatous defects
Pablo LE; Ferreras A; Schlottmann PG
British Journal of Ophthalmology 2011; 95: 51-55 (IGR: 13-1)

28025 Agreement between Heidelberg Retina Tomograph-I and-II in detecting glaucomatous changes using topographic change analysis
Balasubramanian M; Bowd C; Weinreb RN; Zangwill LM
Eye 2011; 25: 31-42 (IGR: 13-1)

27753 Novel Heidelberg Retina Tomograph–Based Morphological Parameters Derived from Optic Disc Cupping Surface Processing
Kilintzis V; Pappas T; Chouvarda I; Salonikiou A; Maglaveras N; Dimitrakos S; Topouzis F
Investigative Ophthalmology and Visual Science 2011; 52: 947-951 (IGR: 13-1)

27698 Assessment of optic disc parameters among healthy adult Malays by Heidelberg Retinal Tomograph II
Jusoh S; Shaharuddin B; Wan Hitam WH
Clinical and Experimental Ophthalmology 2011; 39: 15-22 (IGR: 13-1)

27977 Principles and clinical applications of fundus imaging devices
Tomidokoro A
Neuro-Ophthalmology Japan 2010; 27: 243-253 (IGR: 13-1)

27982 Comparison of the diagnostic ability of Moorfield's regression analysis and glaucoma probability score using Heidelberg retinal tomograph III in eyes with primary open angle glaucoma
Jindal S; Dada T; Sreenivas V; Gupta V; Sihota R; Panda A
Indian Journal of Ophthalmology 2010; 58: 487-492 (IGR: 13-1)

27798 Determinants of Image Quality of Heidelberg Retina Tomography II and its Association With Optic Disc Parameters in a Population-Based Setting
Zheng Y; Cheung CY; Wong TY; Wong W; Loon S-C; Aung T
American Journal of Ophthalmology 2011; 151:663-670 (IGR: 13-1)

27784 Assessment of rates of structural change in glaucoma using imaging technologies
Mansouri K; Leite MT; Medeiros FA; Leung CK; Weinreb RN
Eye 2011; 25: 269-77 (IGR: 13-1)

28141 Optic nerve head analysis of superior segmental optic hypoplasia using Heidelberg retina tomography
Miki A; Shirakashi M; Yaoeda K; Fukushima A; Takagi M; Abe H
Clinical Ophthalmology 2010; 4: 1193-1199 (IGR: 13-1)

28238 Confocal scanning laser ophthalmoscopy in glaucoma diagnosis and management
Alexandrescu C; Dascalu AM; Panca A; Sescioreanu A; Mitulescu C; Ciuluvica R; Voinea L; Celea C
Journal of medicine and life 2010; 3: 229-234 (IGR: 13-1)

28239 Heidelberg Retina Tomography analysis in optic disks with anatomic particularities
Dascalu AM; Alexandrescu C; Pascu R; Ilinca R; Popescu V; Ciuluvica R; Voinea L; Celea C
Journal of medicine and life 2010; 3: 359-364 (IGR: 13-1)

28095 Diagnostic assessment of normal and pale optic nerve heads by confocal scanning laser ophthalmoscope and stereophotography
Fogagnolo P; Romano S; Ranno S; Taibbi G; Pierrottet C; Ferreras A; Figus M; Rossetti L; Orzalesi N
Journal of Glaucoma 2011; 20: 10-14 (IGR: 13-1)

27761 Longitudinal change detected by spectral domain optical coherence tomography in the optic nerve head and peripapillary retina in experimental glaucoma
Strouthidis NG; Fortune B; Yang H; Sigal IA; Burgoyne CF
Investigative Ophthalmology and Visual Science 2011; 52: 1206-1219 (IGR: 13-1)

27770 Effect of Disease Severity and Optic Disc Size on Diagnostic Accuracy of RTVue Spectral Domain Optical Coherence Tomograph in Glaucoma
Rao HL; Leite MT; Weinreb RN; Zangwill LM; Alencar LM; Sample PA; Medeiros FA
Investigative Ophthalmology and Visual Science 2011; 52: 1290-1296 (IGR: 13-1)

28233 Basic technique and anatomically imposed limitations of confocal scanning laser Doppler flowmetry at the optic nerve head level
Sehi M
Acta Ophthalmologica 2011; 89: 1-11 (IGR: 13-1)

27808 Comparison of the correlations between optic disc rim area and retinal nerve fiber layer thickness in glaucoma and nonarteritic anterior ischemic optic neuropathy
Suh MH; Kim SH; Park KH; Kim SJ; Kim T-W; Hwang S-S; Kim DM
American Journal of Ophthalmology 2011; 151: 277-286 (IGR: 13-1)

27673 Impact of Panretinal Photocoagulation on Optic Nerve Head Parameters
Cankaya AB; Ozdamar Y; Ozalp S; Ozkan SS
Ophthalmologica 2011; 225: 193-199 (IGR: 13-1)

27021 Age-related changes of human conjunctiva on in vivo confocal microscopy.
Zhu W; Hong J; Zheng T; Le Q; Xu J; Sun X
British Journal of Ophthalmology 2010; 94: 1448-1453 (IGR: 12-4)

27014 Evaluation of prostaglandin analogue effects on corneal keratocyte density using scanning laser confocal microscopy.
Bergonzi C; Giani A; Blini M; Marchi S; Luccarelli S; Staurenghi G
Journal of Glaucoma 2010; 19: 617-621 (IGR: 12-4)

26944 Optic disc area and correlation with central corneal thickness, corneal hysteresis and ocular pulse amplitude in glaucoma patients and controls.
E Insull; S Nicholas; GS Ang; A Poostchi; K Chan; A Wells
Clinical and Experimental Ophthalmology 2010; 38: 839-844 (IGR: 12-4)

27357 Comparison of multifocal visual evoked potential and Heidelberg retinal tomography in glaucoma diagnosis
Yang X-G; Liu Z; Yu J-N; Li P; Pan A-Z; Chen Y
Chinese Ophthalmic Research 2010; 28: 739-744 (IGR: 12-4)

27242 Principles and clinical applications of fundus imaging devices
Tomidokoro A
Neuro-Ophthalmology Japan 2010; 27: 243-253 (IGR: 12-4)

27243 Problems and limitations of fundus imaging
Nakamura M
Neuro-Ophthalmology Japan 2010; 27: 286-294 (IGR: 12-4)

27065 Tracking Longitudinal Retinal Changes in Experimental Ocular Hypertension Using the cSLO and Spectral Domain-OCT.
Guo L; Normando EM; Nizari S; Lara D; Cordeiro MF
Investigative Ophthalmology and Visual Science 2010; 51: 6504-6513 (IGR: 12-4)

27499 Correlation between morphology of optic disc determined by heidelberg retina tomograph ii and visual function in eyes with open-angle glaucoma
Omodaka K; Nakazawa T; Otomo T; Nakamura M; Fuse N; Nishida K
Clinical Ophthalmology 2010; 4: 765-772 (IGR: 12-4)

27244 Imaging technology for diagnosis of glaucoma and detection of glaucoma progression
Ohkubo S
Neuro-Ophthalmology Japan 2010; 27: 268-278 (IGR: 12-4)

27017 Agreement among 3 methods of optic disc diameter measurement.
Rao HL; Puttaiah NK; Babu JG; Maheshwari R; Senthil S; Garudadri CS
Journal of Glaucoma 2010; 19: 650-654 (IGR: 12-4)

27059 An in silico model of scanning laser tomography image series: an alternative benchmark for the specificity of progression algorithms.
O'Leary N; Crabb DP; Garway-Heath DF
Investigative Ophthalmology and Visual Science 2010; 51: 6472-6482 (IGR: 12-4)

26967 In vivo assessment of retinal vascular wall dimensions.
Fischer MD; Huber G; Feng Y; Tanimoto N; Mühlfriedel R; Beck SC; Tröger E; Kernstock C; Preising MN; Lorenz B
Investigative Ophthalmology and Visual Science 2010; 51: 5254-5259 (IGR: 12-4)

27429 Optic nerve head morphology assessed by laser scanning tomography in normal Japanese subjects
Sawada Y; Ishikawa M; Sato N; Yoshitomi T
Journal of Glaucoma 2010; (IGR: 12-4)

27198 Determinants of agreement between the confocal scanning laser tomograph and standardized assessment of glaucomatous progression
Vizzeri G; Bowd C; Weinreb RN; Balasubramanian M; Medeiros FA; Sample PA; Zangwill LM
Ophthalmology 2010; 117: 1953-1959 (IGR: 12-4)

27117 Change in optic nerve head topography in healthy volunteers: An 11-year follow-up
Harju M; Kurvinen L; Saari J; Vesti E
British Journal of Ophthalmology 2010; (IGR: 12-4)

27216 Comparison of optic disc topography in non-glaucomatous eyes of children with juvenile diabetes mellitus and normal children
Elgin U; Cankaya B; Simsek T; Batman A
Journal of Pediatric Ophthalmology & Strabismus 2010; 47: 313-316 (IGR: 12-4)

26357 Optic disc damage staging system
Brusini P; Zeppieri M; Tosoni C; Parisi L; Salvetat ML
Journal of Glaucoma 2010; 19: 442-449 (IGR: 12-3)

26907 Relationship between standard automated perimetry and optic nerve head topography performed with the Heidelberg Retina Tomograph
Lopez-Pena MJ; Ferreras A; Larrosa JM; Polo V; Fogagnolo P; Honrubia FM
Archivos de la Sociedad Espanola de Oftalmologia 2009; 84: 611-624 (IGR: 12-3)

26565 Disc photography and heidelberg retinal tomography documentation of reversal of cupping following trabeculectomy
Yuen D; Buys YM
Graefe's Archive for Clinical and Experimental Ophthalmology 2010; 248: 1671-1673 (IGR: 12-3)

26327 Comparison of different spectral domain optical coherence tomography scanning areas for glaucoma diagnosis
Rao HL; Zangwill LM; Weinreb RN; Sample PA; Alencar LM; Medeiros FA
Ophthalmology 2010; 117: 1692-1699 (IGR: 12-3)

26854 Correlation of disc damage likelihood scale with the structural and functional change in optic nerve with primary open-angle glaucoma
Cui M; Chen X-M; Huang Y-Z
International Journal of Ophthalmology 2010; 10: 1140-1142 (IGR: 12-3)

26325 Predicting the onset of glaucoma the confocal scanning laser ophthalmoscopy ancillary study to the ocular hypertension treatment study
Weinreb RN; Zangwill LM; Jain S; Becerra LM; Dirkes K; Piltz-Seymour JR; Cioffi GA; Trick GL; Coleman AL; Brandt JD
Ophthalmology 2010; 117: 1674-1683 (IGR: 12-3)

26324 Diagnostic accuracy of the heidelberg retina tomograph for glaucoma a population-based assessment
Healey PR; Lee AJ; Aung T; Wong TY; Mitchell P
Ophthalmology 2010; 117: 1667-1673 (IGR: 12-3)

26458 Optic disc analysis with heidelberg retina tomography III in glaucoma with unilateral visual field defects
Xiao G-G; Wu L-L
Japanese Journal of Ophthalmology 2010; 54: 305-309 (IGR: 12-3)

26326 Retinal nerve fiber layer imaging with spectral-domain optical coherence tomography analysis of the retinal nerve fiber layer map for glaucoma detection
Leung CK; Lam S; Weinreb RN; Liu S; Ye C; Liu L; He J; Lai GW; Li T; Lam DS
Ophthalmology 2010; 117: 1684-1691 (IGR: 12-3)

26883 What is the best method for diagnosing glaucoma?
Hamzah JC; Azuara-Blanco A
Expert Review of Ophthalmology 2010; 5: 463-474 (IGR: 12-3)

26374 The effect of phacoemulsification cataract surgery on polarimetry and tomography measurements for glaucoma diagnosis
Sánchez-Cano A; Pablo LE; Larrosa JM; Polo V
Journal of Glaucoma 2010; 19: 468-474 (IGR: 12-3)

26806 Relationship of retinal vascular tortuosity with the neuroretinal rim: the singapore malay eye study
Koh V; Cheung CY; Zheng Y; Wong TY; Wong W; Aung T
Investigative Ophthalmology and Visual Science 2010; 51: 3736-3741 (IGR: 12-3)

26311 Scanning laser ophthalmoscopic parameters of eyes with exfoliation syndrome
Cankaya AB; Beyazyildiz E
Japanese Journal of Ophthalmology 2010; 54: 300-304 (IGR: 12-3)

26001 Intelligent fusion of cup-to-disc ratio determination methods for glaucoma detection in ARGALI
Wong DW; Liu J; Lim JH; Tan NM; Zhang Z; Lu S; Li H; Teo MH; Chan KL; Wong TY
Conference proceedings : Annual International Conference of the IEEE Engineering in Medicine and Biology Society 2009; 2009: 5777-5780 (IGR: 12-2)

26000 Convex hull based neuro-retinal optic cup ellipse optimization in glaucoma diagnosis
Zhang Z; Liu J; Cherian NS; Sun Y; Lim JH; Wong WK; Tan NM; Lu S; Li H; Wong TY
Conference proceedings : Annual International Conference of the IEEE Engineering in Medicine and Biology Society 2009; 2009: 1441-1444 (IGR: 12-2)

26212 Glaucomatous progression in series of stereoscopic photographs and Heidelberg retina tomograph images
O'Leary N; Crabb DP; Mansberger SL; Fortune B; Twa MD; Lloyd MJ; Kotecha A; Garway-Heath DF; Cioffi GA; Johnson CA
Archives of Ophthalmology 2010; 128: 560-568 (IGR: 12-2)

26075 Combining Functional and Structural Tests Improves the Diagnostic Accuracy of Relevance Vector Machine Classifiers
Racette L; Chiou CY; Hao J; Bowd C; Goldbaum MH; Zangwill LM; Lee TW; Weinreb RN; Sample PA
Journal of Glaucoma 2010; 19: 167-175 (IGR: 12-2)

26093 The Heidelberg retina tomograph Glaucoma Probability Score: reproducibility and measurement of progression
Strouthidis NG; Demirel S; Asaoka R; Cossio-Zuniga C; Garway-Heath DF
Ophthalmology 2010; 117: 724-729 (IGR: 12-2)

26293 Reproducibility of OCT/SLO measurements in healthy eyes
Labiris G; Giarmoukakis A; Katsanos A; Gkika MG; Fanariotis M; Pavlidou E; Kozobolis VP
European Journal of Ophthalmology 2010; 20: 552-558 (IGR: 12-2)

26186 Detection of morphological and functional progression in initial glaucoma
Gonzalez de la Rosa M; Gonzalez-Hernandez M; Sanchez-Mendez M; Medina-Mesa E; Rodriguez de la Vega R
British Journal of Ophthalmology 2010; 94: 414-418 (IGR: 12-2)

25961 Ability of optical imaging devices to detect early structural damage in ocular hypertension
Pueyo V; Polo V; Larrosa JM; Pablo LE; Ferreras A; Honrubia FM
Annals of ophthalmology (Skokie, Ill.) 2009; 41: 150-156 (IGR: 12-2)

25451 New nonlinear multivariable model shows the relationship between central corneal thickness and HRTII topographic parameters in glaucoma patients
Kourkoutas D; Georgopoulos G; Maragos A; Apostolakis I; Tsekouras G; Karanasiou I S; Papaconstantinou D; Iliakis E; Moschos M
Clinical Ophthalmology 2009; 3: 313-323 (IGR: 12-1)

25072 Pulsar perimetry in the diagnosis of early glaucoma
Zeppieri M; Brusini P; Parisi L; Johnson CA; Sampaolesi R; Salvetat ML
American Journal of Ophthalmology 2010; 149: 102-112 (IGR: 12-1)

25122 Correlation of Disc Morphology Quantified on Stereophotographs to Results by Heidelberg Retina Tomograph II, GDx Variable Corneal Compensation, and Visual Field Tests
Saito H; Tsutsumi T; Iwase A; Tomidokoro A; Araie M
Ophthalmology 2010; 117: 282-289 (IGR: 12-1)

25097 The sensitivity and specificity of Heidelberg Retina Tomograph parameters to glaucomatous progression in disc photographs
Saarela V; Falck A; Airaksinen PJ; Tuulonen A
British Journal of Ophthalmology 2010; 94: 68-73 (IGR: 12-1)

25394 Correlation between neuroretinal rim area/retinal nerve fiber layer thickness and differential light sensitivity in visual field in primary open angle glaucoma
Li L; Zhao J -L; Liu X -L
Zhongguo Yi Xue Ke Xue Yuan Xue Bao 2009; 31: 607-611 (IGR: 12-1)

25510 Ability of different optical imaging devices to discriminate between healthy and glaucomatous eyes.
Pueyo V; Polo V; Larrosa J M; Ferreras A; Alias E; Honrubia F M
Annals of ophthalmology (Skokie, Ill.) 2009; 41: 102-108 (IGR: 12-1)

25406 Scanning laser polarimetry and optical coherence tomography for detection of retinal nerve fiber layer defects.
Oh J H; Kim Y Y
Korean Journal of Ophthalmology 2009; 23: 169-175 (IGR: 12-1)

25598 Diagnostic accuracy of Heidelberg Retina Tomograph III classifications in a Turkish primary open-angle glaucoma population
Bozkurt B; Irkec M; Arslan U
Acta Ophthalmologica 2010; 88: 125-130 (IGR: 12-1)

25188 Estimating normative limits of Heidelberg Retina Tomograph optic disc rim area with quantile regression
Artes PH; Crabb DP
Investigative Ophthalmology and Visual Science 2010; 51: 355-361 (IGR: 12-1)

25094 Sensitivity of confocal laser tomography versus optical coherence tomography in detecting advanced glaucoma
Hewitt AW; Chappell AJ; Straga T; Landers J; Mills RA; Craig JE
Clinical and Experimental Ophthalmology 2009; 37: 836-841 (IGR: 12-1)

25135 Comparison of the Diagnostic Capability of the Heidelberg Retina Tomographs 2 and 3 for Glaucoma in the Indian Population
Rao HL; Babu GJ; Sekhar GC
Ophthalmology 2010; 117: 275-281 (IGR: 12-1)

25143 Sensitivity of imaging the peripheral nerve fibre layer using a confocal scanning laser ophthalmoscope to detect glaucoma
Plange N; Kaup M; Hirsch F; Arend KO; Remky A
Klinische Monatsblätter für Augenheilkunde 2010; 227: 61-66 (IGR: 12-1)

25009 Optic nerve head changes in early glaucoma: a comparison between stereophotography and Heidelberg retina tomography
Pablo LE; Ferreras A; Fogagnolo P; Figus M; Pajarin AB
Eye 2010; 24: 123-130 (IGR: 12-1)

25136 Retinal Nerve Fiber Layer Imaging with Spectral-Domain Optical Coherence Tomography A Study on Diagnostic Agreement with Heidelberg Retinal Tomograph
Leung CK; Ye C; Weinreb RN; Cheung CY; Qiu Q; Liu S; Xu G; Lam DS
Ophthalmology 2010; 117: 267-274 (IGR: 12-1)

25133 Diagnostic Ability of Heidelberg Retina Tomography in Detecting Glaucoma in a Population Setting The Singapore Malay Eye Study
Zheng Y; Wong TY; Lamoureux E; Mitchell P; Loon SC; Saw SM; Aung T
Ophthalmology 2010; 117: 290-297 (IGR: 12-1)

25029 Performance of GDx and HRT in the Finnish Evidence-Based Guideline for Open-Angle Glaucoma
Pablo LE; Larrosa JM; Polo V; Ferreras A; Alías EG; Honrubia FM
Eye 2010; 24: 297-303 (IGR: 12-1)

25218 Noninvasive visualization and analysis of parafoveal capillaries in humans
Tam J; Martin JA; Roorda A
Investigative Ophthalmology and Visual Science 2010; 51: 1691-1698 (IGR: 12-1)

25322 Improvement of the topographic parameters of the optic discs after trabeculotomy in two patients with developmental glaucoma
Yasuda M; Ando A; Otsuji T; Fukui C; Matsumura M
Journal of Pediatric Ophthalmology & Strabismus 2009; 46: 372-375 (IGR: 12-1)

25518 In vivo fluorescence mode confocal microscopy of subepithelial tissues in glaucoma filtering blebs
Wells A P; Wakely L; Birchall W
Ophthalmic Surgery Lasers and Imaging 2010; 41: 78-82 (IGR: 12-1)

24628 Evaluation of the retinal nerve fiber layer: Descriptive or predictive?
Savino PJ
Journal of Neuro-Ophthalmology 2009; 29: 245-249 (IGR: 11-4)

24898 Diffuse glaucomatous structural and functional damage in the hemifield without significant pattern loss
Grewal DS; Sehi M; Greenfield DS
Archives of Ophthalmology 2009; 127: 1442-1448 (IGR: 11-4)

24803 HRT-3 Moorfields reference plane: effect on rim area repeatability and identification of progression
Asaoka R; Strouthidis NG; Kappou V; Gardiner SK; Garway-Heath DF
British Journal of Ophthalmology 2009; 93: 1510-1513 (IGR: 11-4)

24814 Optic disk size variability between African, Asian, white, Hispanic, and Filipino Americans using Heidelberg retinal tomography
Seider MI; Lee RY; Wang D; Pekmezci M; Porco TC; Lin SC
Journal of Glaucoma 2009; 18: 595-600 (IGR: 11-4)

24606 Glaucoma diagnosis and follow-up using the Heidelberg Retina Tomograph
Hoffmann EM; Lamparter J; Schmidt T; Schulze A
Ophthalmologe 2009; 106: 687-695 (IGR: 11-4)

24743 Ability of the Heidelberg retina tomograph to detect early glaucomatous visual field loss in primary open angle glaucoma
Li J; Chen X-M
International Journal of Ophthalmology 2009; 9: 1690-1692 (IGR: 11-4)

24780 The effect of contour line position on optic nerve head analysis by Heidelberg Retina Tomograph
Iester M; Mariotti V; Lanza F; Calabria G
European Journal of Ophthalmology 2009; 19: 942-948 (IGR: 11-4)

24901 Scan quality effect on glaucoma discrimination by glaucoma imaging devices
Sung KR; Wollstein G; Schuman JS; Bilonick RA; Ishikawa H; Townsend KA; Kagemann L; Gabriele ML; Advanced Imaging in Glaucoma Study Group
British Journal of Ophthalmology 2009; 93: 1580-1584 (IGR: 11-4)

24949 Sensitivity and specificity of the Heidelberg Retina Tomograph II Version 3.0 in a population-based study: the Tajimi Study
Saito H; Tsutsumi T; Araie M; Tomidokoro A; Iwase A
Ophthalmology 2009; 116: 1854-1861 (IGR: 11-4)

24685 In-vivo imaging of retinal nerve fiber layer vasculature: imaging histology comparison
Scoles D; Gray DC; Hunter JJ; Wolfe R; Gee BP; Geng Y; Masella BD; Libby RT; Russell S; Williams DR
BMC Ophthalmology 2009; 9: 9 (IGR: 11-4)

24791 Confocal scanning laser ophthalmoscopy in high myopic eyes in a population-based setting
Tsutsumi T; Tomidokoro A; Saito H; Hashizume A; Iwase A; Araie M
Investigative Ophthalmology and Visual Science 2009; 50: 5281-5287 (IGR: 11-4)

24805 Optical coherence tomography and Heidelberg retina tomography for superior segmental optic hypoplasia
Lee HJ; Kee C
British Journal of Ophthalmology 2009; 93: 1468-1473 (IGR: 11-4)

24617 Perimetry change of primary chronic glaucoma after intraocular pressure reduction
Wang L; Wang N; Liang Y; Chen Y; Lin Z; Peng Y
Chinese Ophthalmic Research 2009; 27: 792-795 (IGR: 11-4)

24010 The spatial pattern of neuroretinal rim loss in ocular hypertension
Strouthidis NG; Gardiner SK; Sinapis C; Burgoyne CF; Garway-Heath DF
Investigative Ophthalmology and Visual Science 2009; 50: 3737-3742 (IGR: 11-3)

24138 Structure-function relationship depends on glaucoma severity
Gonzalez-Hernandez M; Pablo LE; Armas-Dominguez K; De La Vega RR; Ferreras A; de la Rosa MG
British Journal of Ophthalmology 2009; 93: 1195-1199 (IGR: 11-3)

24111 Combining ganglion cell topology and data of patients with glaucoma to determine a structure-function map
Turpin A; Sampson GP; McKendrick AM
Investigative Ophthalmology and Visual Science 2009; 50: 3249-3256 (IGR: 11-3)

24455 Topographic changes at the optic disc in 33 patients with primary open angle glaucoma
Marjanovic I; Kontic D; Hentova-Sencanic P; Markovic V; Bozic M; Milic N
International Journal of Ophthalmology 2009; 9: 1026-1029 (IGR: 11-3)

24222 Contribution and significance of Heidelberg Retinal Tomography II in diagnostics of ocular hypertension and its conversion into primary open-angle glaucoma
Markovic V; Kontic D; Hentova-Sencanic P; Bozic M; Marjanovic I; Krstic V; Kovacevic D
Vojnosanitetski pregled. Military-medical and pharmaceutical review 2009; 66: 283-289 (IGR: 11-3)

24499 Coupling of HRT II and AS-OCT to evaluate corneal endothelial cell loss and in vivo visualization of the Ahmed glaucoma valve implant
Mendrinos E; Dosso A; Sommerhalder J; Shaarawy T
Eye 2009; 23: 1836-1844 (IGR: 11-3)

24181 Noncontact in vivo scanning laser microscopy of filtering blebs
Sbeity Z; Palmiero PM; Tello C; Liebmann JM; Ritch R
Journal of Glaucoma 2009; 18: 479-483 (IGR: 11-3)

24508 Comparison of retinal nerve fiber layer thickness values using Stratus Optical Coherence Tomography and Heidelberg Retina Tomograph-III
Moreno-Montañés J; Antón A; García N; Olmo N; Morilla A; Fallon M
Journal of Glaucoma 2009; 18: 528-534 (IGR: 11-3)

24052 Optic nerve head topography in nonglaucomatous, normotensive patients with unilateral exfoliation syndrome
Puska P; Harju M
Graefe's Archive for Clinical and Experimental Ophthalmology 2009; 247: 1111-1117 (IGR: 11-3)

23713 Experimental detection of retinal ganglion cell damage in vivo
Leung CK; Weinreb RN
Experimental Eye Research 2009; 88: 831-836 (IGR: 11-2)

23976 Comparison of mean deviation with AGIS and CIGTS scores in association with structural parameters in glaucomatous eyes
Naka M; Kanamori A; Tatsumi Y; Fujioka M; Nagai-Kusuhara A; Nakamura M; Negi A
Journal of Glaucoma 2009; 18: 379-384 (IGR: 11-2)

23457 Ratio of multifocal electroretinographic to retinal tomographic parameters in patients with suspected glaucoma
Kazarian EE
Vestnik Oftalmologii 2009; 125: 39-41 (IGR: 11-2)

23688 Ophthalmic imaging today: an ophthalmic photographer's viewpoint - a review
Bennett TJ; Barry CJ
Clinical and Experimental Ophthalmology 2009; 37: 2-13 (IGR: 11-2)

23978 Influence of glaucomatous damage and optic disc size on glaucoma detection by scanning laser tomography
Hoesl LM; Mardin CY; Horn FK; Juenemann AG; Laemmer R
Journal of Glaucoma 2009; 18: 385-389 (IGR: 11-2)

23977 Optic nerve head analysis using the confocal scanning laser ophthalmoscope (CSLO) of big cups versus normal cups
Ouertani A; Tounsi L; Khammari C; Bouden J; Mili-Boussen I
Journal Français d'Ophtalmologie 2009; 32: 50-55 (IGR: 11-2)

23871 Rates of neuroretinal rim and peripapillary atrophy area change: a comparative study of glaucoma patients and normal controls
See JL; Nicolela MT; Chauhan BC
Ophthalmology 2009; 116: 840-847 (IGR: 11-2)

23971 HRT III glaucoma probability score and Moorfields regression across the glaucoma spectrum
Reddy S; Xing D; Arthur SN; Harizman N; Dorairaj S; Ritch R; Liebmann JM
Journal of Glaucoma 2009; 18: 368-372 (IGR: 11-2)

23693 Clinical use and research applications of Heidelberg retinal angiography and spectral-domain optical coherence tomography - a review
Hassenstein A; Meyer CH
Clinical and Experimental Ophthalmology 2009; 37: 130-143 (IGR: 11-2)

23601 ICA analysis of retina images for glaucoma classification
Fink F; Worle K; Gruber P; Tome AM; Gorriz-Saez JM; Puntonet CG; Lang EW
Conference proceedings : Annual International Conference of the IEEE Engineering in Medicine and Biology Society 2008; 4664-4667 (IGR: 11-2)

23955 Optic disc progression in glaucoma: comparison of confocal scanning laser tomography to optic disc photographs in a prospective study
Chauhan BC; Hutchison DM; Artes PH; Caprioli J; Jonas JB; Leblanc RP; Nicolela MT
Investigative Ophthalmology and Visual Science 2009; 50: 1682-1691 (IGR: 11-2)

23439 Evaluation on the cellular level the filtering bleb following trabeculectomy, using the HRT II Cornea Module
Jurowska-Liput J; Krzyzanowska P; Szelepin L; Nizankowska MH
Klinika Oczna 2008; 110: 343-346 (IGR: 11-2)

23861 Sector-based analysis with the Heidelberg Retinal Tomograph 3 across disc sizes and glaucoma stages: a multicenter study
Oddone F; Centofanti M; Iester M; Rossetti L; Fogagnolo P; Michelessi M; Capris E; Manni G
Ophthalmology 2009; 116: 1106-1111 (IGR: 11-2)

23787 Quantitative assessment of optic nerve head morphology and retinal nerve fibre layer in non-arteritic anterior ischaemic optic neuropathy with optical coherence tomography and confocal scanning laser ophthalmoloscopy
Chan CK; Cheng AC; Leung CK; Cheung CY; Yung AY; Gong B; Lam DS
British Journal of Ophthalmology 2009; 93: 731-735 (IGR: 11-2)

22582 Comparison between confocal scanning laser tomography, scanning laser polarimetry and optical coherence tomography on the ability to detect localised retinal nerve fibre layer defects in glaucoma patients
Windisch BK; Harasymowycz PJ; See JL; Chauhan BC; Belliveau AC; Hutchison DM; Nicolela MT
British Journal of Ophthalmology 2009; 93: 225-230 (IGR: 11-1)

22514 Assessment of cup-to-disc ratio with slit-lamp funduscopy, Heidelberg Retina Tomography II, and stereoscopic photos
Durmus M; Karadag R; Erdurmus M; Totan Y; Feyzi Hepsen I
European Journal of Ophthalmology 2009; 19: 55-60 (IGR: 11-1)

23008 Effect of prophylactic surgeries on HRT-II parameters and visual field of preclinical primary closed-angle glaucoma patients
Guo B; Yang X-G; Fan Q-H; Liu Z; Yu J-N; Chen L; Ai H
International Journal of Ophthalmology 2008; 8: 2244-2247 (IGR: 11-1)

23007 Clinical analysis of the parameters detected by HRT-II and Humphrey perimetry in the new international classification of angle-closure glaucoma
Yang X-G; Guo B; Liu Z; Yu J-N; Li P; Liu J-R; Li H-M; Ma Q-L
International Journal of Ophthalmology 2008; 8: 2239-2243 (IGR: 11-1)

23385 Comparison of quantitative imaging devices and subjective optic nerve head assessment by general ophthalmologists to differentiate normal from glaucomatous eyes
Vessani RM; Moritz R; Batis L; Zagui RB; Bernardoni S; Susanna R
Journal of Glaucoma 2009; 18: 253-261 (IGR: 11-1)

22657 Laser scanning tomography of optic discs of the normal Japanese population in a population-based setting
Abe H; Shirakashi M; Tsutsumi T; Araie M; Tomidokoro A; Iwase A; Tomita G; Yamamoto T; Tajimi Study Group
Ophthalmology 2009; 116: 223-230 (IGR: 11-1)

22538 Performance of confocal scanning laser tomograph Topographic Change Analysis (TCA) for assessing glaucomatous progression
Bowd C; Balasubramanian M; Weinreb RN; Vizzeri G; Alencar LM; O'Leary N; Sample PA; Zangwill LM
Investigative Ophthalmology and Visual Science 2009; 50: 691-701 (IGR: 11-1)

22911 Comparison of OCT and HRT findings among normal, normal tension glaucoma, and high tension glaucoma
Shin IH; Kang SY; Hong S; Kim SK; Seong GJ; Tak MK; Kim CY
Korean Journal of Ophthalmology 2008; 22: 236-241 (IGR: 11-1)

22651 Longitudinal evaluation of optic disc measurement variability with optical coherence tomography and confocal scanning laser ophthalmoscopy
Lin D; Leung CK; Weinreb RN; Cheung CY; Li H; Lam DS
Journal of Glaucoma 2009; 18: 101-106 (IGR: 11-1)

23386 Reproducibility of the Heidelberg Retina Tomograph III Glaucoma Probability Score
Taibbi G; Fogagnolo P; Orzalesi N; Rossetti L
Journal of Glaucoma 2009; 18: 247-252 (IGR: 11-1)

23390 Sensitivity and specificity with the glaucoma probability score in Heidelberg Retina Tomograph II in Japanese eyes
Saito H; Tomidokoro A; Yanagisawa M; Iwase A; Araie M
Journal of Glaucoma 2009; 18: 227-232 (IGR: 11-1)

22557 Retinal nerve fibre layer measurements and optic nerve head analysis in multiple sclerosis patients
Iester M; Cioli F; Uccelli A; Papadia M; Bandini F; Mancardi GL; Calabria GA
Eye 2009; 23: 407-412 (IGR: 11-1)

22670 Clinicians agreement in establishing glaucomatous progression using the Heidelberg retina tomograph
Vizzeri G; Weinreb RN; Martinez De La Casa JM; Alencar LM; Bowd C; Balasubramanian M; Medeiros FA; Sample P; Zangwill LM
Ophthalmology 2009; 116: 14-24 (IGR: 11-1)

21831 Morpho-functional follow-up of the optic nerve in treated ocular hypertension: Disc morphometry and steady-state pattern electroretinogram
Salgarello T; Falsini B; Stifano G; Montrone L; Iarossi G; Balestrazzi E; Colotto A
Current Eye Research 2008; 33: 709-721 (IGR: 10-3)

21509 Application of Heidelberg Retina Tomography III in glaucoma with unilateral visual field defects
Gege X; Lingling W
Chinese Ophthalmic Research 2008; 26: 466-469 (IGR: 10-3)

21695 Observer agreement using the Heidelberg Retina Tomograph: The Bridlington Eye Assessment Project
Hawker MJ; Ainsworth G; Vernon SA; Dua HS
Journal of Glaucoma 2008; 17: 280-286 (IGR: 10-3)

21503 Results of the Ocular Hypertension Treatment Study and the Confocal Scanning Laser Ophthalmoscopy Ancillary Study and evaluation of the Heidelberg Retina Tomograph
Klatt K; Schmidt E; Scheuerle AF
Ophthalmologe 2008; 105: 398-404 (IGR: 10-3)

21705 Comparison of retinal nerve fiber layer and optic disc imaging for diagnosing glaucoma in patients suspected of having the disease
Medeiros FA; Vizzeri G; Zangwill LM; Alencar LM; Sample PA; Weinreb RN
Ophthalmology 2008; 115: 1340-1346 (IGR: 10-3)

21522 Topographical analysis of the optic nerve in migraine patients
Moehnke TD; Sowka J; Shallo-Hoffmann J; Hardigan P; Woods AD
Optometry and Vision Science 2008; 85: 566-573 (IGR: 10-3)

21813 Evaluation of optic nerve head configuration in various types of optic neuropathy with Heidelberg Retina Tomograph
Nagai-Kusuhara A; Nakamura M; Kanamori A; Nakanishi Y; Kusuhara S; Negi A
Eye 2008; 22: 1154-1160 (IGR: 10-3)

21702 Exploring the Heidelberg Retina Tomograph III diagnostic accuracy across disc sizes and glaucoma stages: a multicenter study
Oddone F; Centofanti M; Rossetti L; Iester M; Fogagnolo P; Capris E; Manni G
Ophthalmology 2008; 115: 1358-1365 (IGR: 10-3)

21778 Analysis of HRT images: Comparison of reference planes
Poli A; Strouthidis NG; Ho TA; Garway-Heath DF
Investigative Ophthalmology and Visual Science 2008; 49: 3970-3975 (IGR: 10-3)

21447 Normative data of optic nerve head in Thai population by laser scanning tomography: The Siriraj study
Ruangvaravate N; Neungton C
Journal of the Medical Association of Thailand 2008; 91: 859-863 (IGR: 10-3)

21799 Heidelberg Retina Tomograph parameters of the optic disc in eyes with progressive retinal nerve fibre layer defects
Saarela V; Airaksinen PJ
Acta Ophthalmologica 2008; 86: 603-608 (IGR: 10-3)

21603 Limitations of the Heidelberg Retina Tomograph
Siam GA; Gheith ME; Monteiro de Barros DS; Lin AP; Moster MR
Ophthalmic Surgery Lasers and Imaging 2008; 39: 262-264 (IGR: 10-3)

21513 Relationship between the retinal thickness analyzer and the GDx VCC scanning laser polarimeter, Stratus OCT optical coherence tomograph, and Heidelberg Retina Tomograph II confocal scanning laser ophthalmoscopy
Ma KT; Lee SH; Hong S; Park KS; Kim CY; Seong GJ; Hong YJ
Korean Journal of Ophthalmology 2008; 22: 10-17 (IGR: 10-3)

21828 Optic disc and peripapillary morphology in unilateral nonarteritic anterior ischemic optic neuropathy and age- and refraction-matched normals
Saito H; Tomidokoro A; Tomita G; Araie M; Wakakura M
Ophthalmology 2008; 115: 1585-1590 (IGR: 10-3)

21033 Heritability of optic disc and cup measured by the Heidelberg retinal tomography in Chinese: The Guangzhou Twin Eye Study
He M; Liu B; Huang W; Zhang J; Yin Q; Zheng Y; Wang D; Ge J
Investigative Ophthalmology and Visual Science 2008; 49: 1350-1355 (IGR: 10-2)

21109 Importance of assessing optic disc size for accurate diagnosis of glaucoma
Wakakura M
Neuro-Ophthalmology Japan 2007; 24: 405-413 (IGR: 10-2)

20976 Relationship between Humphrey 30-2 SITA standard test, Matrix 30-2 threshold test, and Heidelberg Retina Tomograph in ocular hypertensive and glaucoma patients
Bozkurt B; Ylmaz PT; Irkec M
Journal of Glaucoma 2008; 17: 203-210 (IGR: 10-2)

21001 Correlation between photopic negative response and retinal nerve fiber layer thickness and optic disc topography in glaucomatous eyes
Machida S; Gotoh Y; Toba Y; Ohtaki A; Kaneko M; Kurosaka D
Investigative Ophthalmology and Visual Science 2008; 49: 2201-2207 (IGR: 10-2)

21356 Is the ISNT rule violated in early primary open-angle glaucoma - a scanning laser tomography study
Sihota R; Srinivasan G; Dada T; Gupta V; Ghate D; Sharma A
Eye 2008; 22: 819-824 (IGR: 10-2)

21294 Evaluating the effect of the new alignment algorithm for longitudinal series of Heidelberg retina tomography images
Bergin C; Garway-Heath DF; Crabb DP
Acta Ophthalmologica 2008; 86: 207-214 (IGR: 10-2)

21330 Heidelberg Retina Tomograph 3 machine learning classifiers for glaucoma detection
Townsend KA; Wollstein G; Danks D; Sung KR; Ishikawa H; Kagemann L; Gabriele ML; Schuman JS
British Journal of Ophthalmology 2008; 92: 814-818 (IGR: 10-2)

21257 Study of Heidelberg retina tomograph in myopia and glaucoma
Zhang C-M; Guo B-L; Wang J-R
International Journal of Ophthalmology 2008; 8: 800-802 (IGR: 10-2)

21149 Evaluation of a new scoring system for retinal nerve fiber layer photography using HRA1 in 964 eyes
Hong S; Moon JW; Ha SJ; Kim CY; Seong GJ; Hong YJ
Korean Journal of Ophthalmology 2007; 21: 216-221 (IGR: 10-2)

20960 Discriminating between normal and glaucoma-damaged eyes with the Heidelberg Retina Tomograph 3
Ferreras A; Pablo LE; Larrosa JM; Polo V; Pajarín AB; Honrubia FM
Ophthalmology 2008; 115: 775-781 (IGR: 10-2)

20953 Comparison of parameters from Heidelberg Retina Tomographs 2 and 3
Gabriele ML; Wollstein G; Bilonick RA; Burgansky-Eliash Z; Ishikawa H; Kagemann LE; Schuman JS
Ophthalmology 2008; 115: 673-677 (IGR: 10-2)

20925 Role of optic nerve imaging in glaucoma clinical practice and clinical trials
Greenfield DS; Weinreb RN
American Journal of Ophthalmology 2008; 145: 598-603 (IGR: 10-2)

21396 Evaluation of the optic nerve head with the Heidelberg retina tomograph in diabetes mellitus
Tekeli O; Turaçli ME; Atmaca LS; Elhan AH
Ophthalmologica 2008; 22: 168-172 (IGR: 10-2)

21271 Analysis of optic disc parameters by HRT-II in the patients with chronic angle-closure glaucoma
Xue M-H; Zhang L; Tang G-T; Li B; Zhao J-W; Wang M-H
International Journal of Ophthalmology 2008; 8: 299-300 (IGR: 10-2)

21013 Comparison of HRT-3 glaucoma probability score and subjective stereophotograph assessment for prediction of progression in glaucoma
Alencar LM; Bowd C; Weinreb RN; Zangwill LM; Sample PA; Medeiros FA
Investigative Ophthalmology and Visual Science 2008; 49: 1898-1906 (IGR: 10-2)

20319 Relationship between central corneal thickness and parameters of optic nerve head topography in healthy subjects
Cankaya AB; Elgin U; Batman A; Acaroglu G
European Journal of Ophthalmology 2008; 18: 32-38 (IGR: 10-1)

20354 Association of retinal nerve fibre layer thickness measured by confocal scanning laser ophthalmoscopy and optical coherence tomography with disc size and axial length
Nagai-Kusuhara A; Nakamura M; Fujioka M; Tatsumi Y; Negi A
British Journal of Ophthalmology 2008; 92: 186-90 (IGR: 10-1)

20346 Optic disc size in a population-based study in central India: the Central India Eye and Medical Study (CIEMS)
Nangia V; Matin A; Bhojwani K; Kulkarni M; Yadav M; Jonas JB
Acta Ophthalmologica Scandinavica 2008; 86: 103-104 (IGR: 10-1)

20850 A Comparison Among Humphrey Field Analyzer, Microperimetry, and Heidelberg Retina Tomograph in the Evaluation of Macula in Primary Open Angle Glaucoma
Öztürk F; Fatma Yavas G; Küsbeci T; Samet Ermis S
Journal of Glaucoma 2008; 17: 118-121 (IGR: 10-1)

20645 Correlation of the Heidelberg retinal tomograph, evaluation of the retinal nerve fiber layer and perimetry in the diagnosis of glaucoma
Skorkovska S; Michalek J; Sedlacik M; Maskova Z; Koci J
Česka a Slovenska Oftalmologie 2007; 63: 403-414 (IGR: 10-1)

20812 Topographic comparison of the visual function on multifocal visual evoked potentials with optic nerve structure on heidelberg retinal tomography
Punjabi OS; Stamper RL; Bostrom AG; Han Y; Lin SC
Ophthalmology 2008; 115: 440-446 (IGR: 10-1)

20485 Comparison of classifiers applied to confocal scanning laser ophthalmoscopy data
Adler W; Peters A; Lausen B
Methods of Information in Medicine 2008; 47: 38-46 (IGR: 10-1)

20659 The effectiveness of the Heidelberg Retina Tomograph and laser diagnostic glaucoma scanning system (GDx) in detecting and monitoring glaucoma.
Kwartz AJ; Henson DB; Harper RA; Spencer AF; McLeod D
Health Technol Assess 2005; 9: 1-132, iii (IGR: 10-1)

20579 High-resolution imaging of retinal cells in the living eye
Paques M; Simonutti M; Roux MJ; Bellman C; Lacombe F; Grieve K; Glanc M; LeMer Y; Sahel J-A
Eye 2007; 21: S18-S20 (IGR: 10-1)

20332 Diagnostic ability of the heidelberg retina tomograph 3 for glaucoma
Ferreras A; Pablo LE; Pajarín AB; Larrosa JM; Polo V; Pueyo V
American Journal of Ophthalmology 2008; 145: 354-359 (IGR: 10-1)

20742 New developments in Heidelberg retina tomograph for glaucoma
Strouthidis NG; Garway-Heath DF
Current Opinions in Ophthalmology 2008; 19: 141-148 (IGR: 10-1)

20395 Comparison of optic nerve head topography and visual field in eyes with open-angle and angle-closure glaucoma
Boland MV; Zhang L; Broman AT; Jampel HD; Quigley HA
Ophthalmology 2008; 115: 239-245e2 (IGR: 10-1)

20342 Glaucoma Probability Score vs Moorfields Classification in Normal, Ocular Hypertensive, and Glaucomatous Eyes
Moreno-Montañés J; Antón A; García N; Mendiluce L; Ayala E; Sebastián A
American Journal of Ophthalmology 2008; 145: 360-368 (IGR: 10-1)

19839 Application of retinal nerve fiber layer thickness detected by HRT- II and OCT3 in early diagnosis of primary open-angle glaucoma
Cheng Y-C; Duan X-C
International Journal of Ophthalmology 2007; 7: 1022-1024 (IGR: 9-4)

19720 Diagnostic capability of PULSAR, FDT y HRT-II in glaucoma suspects
Gonzalez de la Rosa M; Gonzalez Hernandez M; Aguilar Estevez J; Diaz Aleman T; Armas Plasencia R
Archivos de la Sociedad Española de Oftalmologia 2007; 82: 413-422 (IGR: 9-4)

19721 Correlation between standard automated perimetry global indices and Heidelberg Retina Tomograph II parameters
Perez-Inigo A; Polo V; Larrosa JM; Ferreras A; Sanchez-Cano A; Martinez-de-la-Casa JM; Honrubia FM
Archivos de la Sociedad Española de Oftalmologia 2007; 82: 401-411 (IGR: 9-4)

19663 Automated interpretation of optic nerve images: a data mining framework for glaucoma diagnostic support
Abidi SS; Artes PH; Yun S; Yu J
Medinfo 2007; 12: 1309-1313 (IGR: 9-4)

19969 Optic disk and nerve fiber layer imaging to detect glaucoma
Badalà F; Nouri-Mahdavi K; Raoof DA; Leeprechanon N; Law SK; Caprioli J
American Journal of Ophthalmology 2007; 144: 724-732 (IGR: 9-4)

20074 Assessment of rat and mouse RGC apoptosis imaging in vivo with different scanning laser ophthalmoscopes
Maass A; von Leithner PL; Luong V; Guo L; Salt TE; Fitzke FW; Cordeiro MF
Current Eye Research 2007; 32: 851-861 (IGR: 9-4)

19906 Comparison of diagnostic accuracy of Heidelberg Retina Tomograph II and Heidelberg Retina Tomograph 3 to discriminate glaucomatous and nonglaucomatous eyes
De León-Ortega JE; Sakata LM; Monheit BE; McGwin G Jr; Arthur SN; Girkin CA
American Journal of Ophthalmology 2007; 144: 525-532 (IGR: 9-4)

19794 The importance of HRT II and perimeter octopus 101 in glaucoma diseases
Ferkova S; Chynoransky M; Krasnik V; Terek M
Česka a Slovenska Oftalmologie 2007; 63: 325-334 (IGR: 9-4)

19790 Evaluation of glaucoma progression by means of HRT II results
Ferkova S; Chynoransky M; Terek M
Česka a Slovenska Oftalmologie 2007; 63: 230-242 (IGR: 9-4)

20049 Diagnostic ability of Heidelberg Retina Tomograph 3 classifications: glaucoma probability score versus Moorfields regression analysis
Ferreras A; Pajarín AB; Polo V; Larrosa JM; Pablo LE; Honrubia FM
Ophthalmology 2007; 114: 1981-1987 (IGR: 9-4)

19759 Diagnosis of open-angle glaucoma by Moorfields regression analysis and multivariate discriminate analysis
Liu C; Hu Y; Xu C; Zhu Z
Chinese Ophthalmic Research 2007; 25: 778-781 (IGR: 9-4)

19792 Importance of structural examination methods in the follow-up of patients with ocular hypertension
Skorkovska K
Česka a Slovenska Oftalmologie 2007; 63: 335-349 (IGR: 9-4)

20009 Monitoring glaucomatous progression using a novel Heidelberg Retina Tomograph event analysis
Fayers T; Strouthidis NG; Garway-Heath DF
Ophthalmology 2007; 114: 1973-1980 (IGR: 9-4)

19470 A comparison of HRT II and GDx imaging for glaucoma detection in a primary care eye clinic setting
Andreou PA; Wickremasinghe SS; Asaria RH; Tay E; Franks WA
Eye 2007; 21: 1050-1055 (IGR: 9-3)

19551 A pilot study to detect glaucoma with confocal scanning laser ophthalmoscopy compared with nonmydriatic stereoscopic photography in a community health screening
Ohkubo S; Takeda H; Higashide T; Sasaki T; Sugiyama K
Journal of Glaucoma 2007; 16: 531-538 (IGR: 9-3)

19277 Rarebit perimetry and optic disk topography in pediatric glaucoma
Martin LM; Nilsson AL
Journal of Pediatric Ophthalmology & Strabismus 2007; 44: 223-231 (IGR: 9-3)

19659 Evaluation of optical coherence tomography and heidelberg retinal tomography parameters in detecting early and moderate glaucoma
Naithani P; Sihota R; Sony P; Dada T; Gupta V; Kondal D; Pandey RM
Investigative Ophthalmology and Visual Science 2007; 48: 3138-3145 (IGR: 9-3)

19552 Interocular differences in optic nerve head topography of the subjects with unilateral peripapillary myelinated nerve fibers
Unal M; Yücel I; Duman O; Ylmaz A; Akar Y
Journal of Glaucoma 2007; 16: 539-542 (IGR: 9-3)

19378 Comparison of angiofluorography and Heidelberg II retinal tomography of the head of the optic nerve in patients with primary open-angle glaucoma
Voinea L; Ion DA; Dascalu AM; Ungureanu E; Panca A; Chivu RD
Oftalmologia 2007; 51: 85-90 (IGR: 9-3)

19307 Relationship between standard automated perimetry and HRT, OCT and GDx in normal, ocular hypertensive and glaucomatous subjects
Lopez-Pena MJ; Ferreras A; Polo V; Larrosa JM; Honrubia FM
Archivos de la Sociedad Española de Oftalmologia 2007; 82: 197-208 (IGR: 9-3)

19623 Optic disc measurements in myopia with optical coherence tomography and confocal scanning laser ophthalmoscopy
Leung CK; Cheng AC; Chong KK; Leung KS; Mohamed S; Lau CS; Cheung CY; Chu GC; Lai RY; Pang CC
Investigative Ophthalmology and Visual Science 2007; 48: 3178-3183 (IGR: 9-3)

19452 Effect of statin drugs and aspirin on progression in open-angle glaucoma suspects using confocal scanning laser ophthalmoscopy
De Castro DK; Punjabi OS; Bostrom AG; Stamper RL; Lietman TM; Ray K; Lin SC
Clinical and Experimental Ophthalmology 2007; 35: 506-513 (IGR: 9-3)

18171 American Chinese glaucoma imaging study: A comparison of the optic disc and retinal nerve fiber layer in detecting glaucomatous damage
Leung CK; Medeiros FA; Zangwill LM; Sample PA; Bowd C; Ng D; Cheung CY; Lam DS; Weinreb RN
Investigative Ophthalmology and Visual Science 2007; 48: 2644-2652 (IGR: 9-2)

17642 Optic disc imaging in perimetrically normal eyes of glaucoma patients with unilateral field loss
Caprioli J; Nouri-Mahdavi K; Law SK; Badala F
Transactions of the American Ophthalmological Society 2006; 104: 202-210 (IGR: 9-2)

18021 Sector-based analysis of frequency doubling technology sensitivity and optic nerve head shape parameters
Iester M; Sangermani C; De Feo F; Ungaro N; Cicinelli S; Tardini MG; Calabria G; Gandolfi S
European Journal of Ophthalmology 2007; 17: 223-229 (IGR: 9-2)

17586 Regression analysis of ranked segment parameters for optic nerve head classification: A pilot study
Cubbidge RP; Hosking SL; Hilton EJ; Gibson JM
Ophthalmic and Physiological Optics 2007; 27: 194-200 (IGR: 9-2)

18118 Linear regression modeling of rim area to discriminate between normal and glaucomatous optic nerve heads: The Bridlington Eye Assessment Project
Hawker MJ; Vernon SA; Tattersall CL; Dua HS
Journal of Glaucoma 2007; 16: 345-351 (IGR: 9-2)

18122 The 'cup-to-disc ratio': A comparison of TopSS, HRT II and subjective findings
Hitzl W; Hornykewycz K; Grabner G; Reitsamer HA
Klinische Monatsblätter für Augenheilkunde 2007; 224: 391-395 (IGR: 9-2)

18027 Intereye spatial relationship of abnormal neuroretinal rim locations in glaucoma patients from the diagnostic innovations in glaucoma study
Hoffmann EM; Boden C; Zangwill LM; Bowd C; Medeiros FA; Crowston JG; Sample PA; Weinreb RN
American Journal of Ophthalmology 2007; 143: 781-787 (IGR: 9-2)

17456 Evaluating the optic nerve and retinal nerve fibre layer: The roles of Heidelberg retina tomography, scanning laser polarimetry and optical coherence tomography
Hoh ST
Annals of the Academy of Medicine, Singapore 2007; 36: 194-202 (IGR: 9-2)

18001 Detection of glaucomatous optic nerve head by using Heidelberg topographic maps
Iester M; Zanini M; Vittone P; Calabria G
Eye 2007; 21: 609-613 (IGR: 9-2)

18022 Diagnostic accuracy of the Moorfields Regression Analysis using the Heidelberg Retina Tomograph in glaucoma patients with visual field defects
Medved N; Cvenkel B
European Journal of Ophthalmology 2007; 17: 216-222 (IGR: 9-2)

17629 Diagnostic usefulness of optical coherence tomography (OCT), scanning laser tomography (HRT-II) and laser polarimetry (GDx) in open-angle glaucoma
Pueyo V; Polo V; Larrosa JM; Ferreras A; Martinez-de-la-Casa JM; Honrubia FM
Archivos de la Sociedad Española de Oftalmologia 2006; 81: 693-700 (IGR: 9-2)

18195 Comparison of optic nerve head topography in healthy adults using a Heidelberg retina tomograph and retinal thickness analyzer
Rekic A; Breznik M; Cvenkel B
International Ophthalmology 2007; 27: 1-9 (IGR: 9-2)

17450 Adaptive optics scanning laser ophthalmoscopy for in vivo imaging of lamina cribrosa
Vilupuru AS; Rangaswamy NV; Frishman LJ; Smith 3rd EL; Harwerth RS; Roorda A
Journal of the Optical Society of America. A, Optics, Image Science, and Vision 2007; 24: 1417-1425 (IGR: 9-2)

18170 The effect of disc size and severity of disease on the diagnostic accuracy of the Heidelberg Retina Tomograph Glaucoma Probability Score
Zangwill LM; Jain S; Racette L; Ernstrom KB; Bowd C; Medeiros FA; Sample PA; Weinreb RN
Investigative Ophthalmology and Visual Science 2007; 48: 2653-2660 (IGR: 9-2)

18077 Assessment of the optic disc to measure neuroprotection
Mikelberg FS
Canadian Journal of Ophthalmology 2007; 42: 421-424 (IGR: 9-2)

18064 Some dissociating factors in the analysis of structural and functional progressive damage in open-angle glaucoma
Hudson CJ; Kim LS; Hancock SA; Cunliffe IA; Wild JM
British Journal of Ophthalmology 2007; 91: 624-628 (IGR: 9-2)

16973 Measurement of autofluorescence in the parapapillary atrophic zone in patients with ocular hypertension
Laemmer R; Horn FK; Viestenz A; Link B; Juenemann AG; Mardin CY
Graefe's Archive for Clinical and Experimental Ophthalmology 2007; 245: 51-58 (IGR: 9-1)

17178 Correlation between the shape of optic nerve head and retinal nerve fiber layer defect
Koike I; Hiroishi G; Koike N; Ikeda Y; Yoshida S; Fujisawa K; Ishibashi T
Japanese Journal of Clinical Ophthalmology 2006; 60: 1925-1929 (IGR: 9-1)

16822 Does treated systemic hypertension affect progression of optic nerve damage in glaucoma suspects?
Punjabi OS; Stamper RL; Bostrom AG; Lin SC
Current Eye Research 2007; 32: 153-160 (IGR: 9-1)

16951 Early glaucoma detection using the Humphrey Matrix Perimeter, GDx VCC, Stratus OCT, and retinal nerve fiber layer photography
Hong S; Ahn H; Ha SJ; Yeom HY; Seong GJ; Hong YJ
Ophthalmology 2007; 114: 210-215 (IGR: 9-1)

17145 Diagnostic assessment of OCT3000 and HRT-II in detecting glaucoma
Shao Y; Qu J; Zhu H; Fang A
Chinese Ophthalmic Research 2006; 24: 647-650 (IGR: 9-1)

16952 Glaucoma detection with the Heidelberg retina tomograph 3
Burgansky-Eliash Z; Wollstein G; Bilonick RA; Ishikawa H; Kagemann L; Schuman JS
Ophthalmology 2007; 114: 466-471 (IGR: 9-1)

16964 Effect of glaucomatous damage on repeatability of confocal scanning laser ophthalmoscope, scanning laser polarimetry, and optical coherence tomography
Deleon Ortega JE; Sakata LM; Kakati B; McGwin G Jr; Monheit BE; Arthur SN; Girkin CA
Investigative Ophthalmology and Visual Science 2007; 48: 1156-1163 (IGR: 9-1)

16980 Interobserver variability in confocal optic nerve analysis (HRT)
Hermann MM; Garway-Heath DF; Jonescu-Cuypers CP; Burk RO; Jonas JB; Mardin CY; Funk J; Diestelhorst M
International Ophthalmology 2005; 26: 143-149 (IGR: 9-1)

16845 Comparison of glaucoma progression evaluated with Heidelberg retina tomograph II versus optic nerve head stereophotographs
Kourkoutas D; Buys YM; Flanagan JG; Hatch WV; Balian C; Trope GE
Canadian Journal of Ophthalmology 2007; 42: 82-88 (IGR: 9-1)

17017 The effects of study design and spectrum bias on the evaluation of diagnostic accuracy of confocal scanning laser ophthalmoscopy in glaucoma
Medeiros FA; Ng D; Zangwill LM; Sample PA; Bowd C; Weinreb RN
Investigative Ophthalmology and Visual Science 2007; 48: 214-222 (IGR: 9-1)

16875 Agreement between stereophotographic and confocal scanning laser ophthalmoscopy measurements of cup/disc ratio: Effect on a predictive model for glaucoma development
Medeiros FA; Zangwill LM; Bowd C; Vasile C; Sample PA; Weinreb RN
Journal of Glaucoma 2007; 16: 209-214 (IGR: 9-1)

17072 Heidelberg Retina Tomograph II topographic parameters, diagnostic capabilities of moorfields regression analysis, and their affecting factors
Nakano S; Takita T; Imaizumi M; Nakatsuka K
Nippon Ganka Gakkai Zasshi 2006; 110: 943-949 (IGR: 9-1)

16882 Diagnostic ability of the Heidelberg retina tomograph, optical coherence tomograph, and scanning laser polarimeter in open-angle glaucoma
Pueyo V; Polo V; Larrosa JM; Ferreras A; Pablo LE; Honrubia FM
Journal of Glaucoma 2007; 16: 173-177 (IGR: 9-1)

17147 Advances in imaging of the optic disc and retinal nerve fiber layer
Trick GL; Calotti FY; Skarf B
Journal of Neuro-Ophthalmology 2006; 26: 284-295 (IGR: 9-1)

16829 Sensitivity and specificity of Heidelberg Retinal Tomography II parameters in detecting early and moderate glaucomatous damage: effect of disc size
Uysal Y; Bayer A; Erdurman C; Kilic S
Clinical and Experimental Ophthalmology 2007; 35: 113-118 (IGR: 9-1)

16782 Axial length and optic disc size in normal eyes
Oliveira C; Harizman N; Girkin CA; Xie A; Tello C; Liebmann JM; Ritch R
British Journal of Ophthalmology 2007; 91: 37-39 (IGR: 9-1)

16830 Atypical retinitis pigmentosa masquerading as primary open-angle glaucoma
Lin J -C; Vander JF; Martin M; Katz J
Journal of Glaucoma 2007; 16: 268-270 (IGR: 9-1)