| scholarly article | Q13442814 |
| P356 | DOI | 10.1016/S0161-6420(00)00284-0 |
| P698 | PubMed publication ID | 11013178 |
| P50 | author | David Garway-Heath | Q38546194 |
| P2093 | author name string | Fitzke FW | |
| Hitchings RA | |||
| Poinoosawmy D | |||
| P2860 | cites work | Magnification characteristics of fundus imaging systems. | Q31952956 |
| Identification of early glaucoma cases with the scanning laser ophthalmoscope. | Q32037134 | ||
| Microperimetry of localized retinal nerve fiber layer defects | Q32062569 | ||
| Relationship of optic disc topography to optic nerve fiber number in glaucoma | Q32066017 | ||
| Mapping structural to functional damage in glaucoma with standard automated perimetry and confocal scanning laser ophthalmoscopy | Q32066507 | ||
| High spatial resolution automated perimetry in glaucoma | Q35300580 | ||
| Quantitative evaluation of the optic nerve head in early glaucoma | Q35304760 | ||
| Measurement of optic disc size: equivalence of methods to correct for ocular magnification. | Q35305211 | ||
| Mapping structural damage of the optic disk to visual field defect in glaucoma | Q36861032 | ||
| The Histology of Retinal Nerve Fiber Layer Bundles and Bundle Defects | Q39664169 | ||
| The Course of Axons Through the Retina and Optic Nerve Head | Q39664179 | ||
| An evaluation of clusters in the glaucomatous visual field | Q42609789 | ||
| The topographical relationship between optic disc and visual field in glaucoma | Q42635334 | ||
| Spatial analyses of glaucomatous visual fields; a comparison with traditional visual field indices | Q44276957 | ||
| Glaucoma Hemifield Test. Automated visual field evaluation. | Q52420672 | ||
| Changes in optic disk characteristics and number of nerve fibers in experimental glaucoma | Q67586495 | ||
| Postmortem preservation of ganglion cells in the human retina. A morphometric investigation with the carbocyanine dye DiI | Q68074320 | ||
| The temporal raphe of the human retina | Q70068939 | ||
| Biometric study of the disc cup in open-angle glaucoma | Q70337557 | ||
| Glaucoma visual field analysis by computed profile of nerve fiber function in optic disc sectors | Q70380940 | ||
| Pattern of glaucomatous neuroretinal rim loss | Q70562357 | ||
| The mode of progressive disc cupping in ocular hypertension and glaucoma | Q71153898 | ||
| The Organization of Nerve Fiber Bundles in the Primate Optic Nerve Head | Q72619530 | ||
| The human fetal retinal nerve fiber layer and optic nerve head: a DiI and DiA tracing study | Q73439606 | ||
| P433 | issue | 10 | |
| P304 | page(s) | 1809-1815 | |
| P577 | publication date | 2000-10-01 | |
| P1433 | published in | Ophthalmology | Q7098109 |
| P1476 | title | Mapping the visual field to the optic disc in normal tension glaucoma eyes | |
| P478 | volume | 107 |
| Q36958320 | 'Structure-function relationship' in glaucoma: past thinking and current concepts. |
| Q35797308 | 2-D pattern of nerve fiber bundles in glaucoma emerging from spectral-domain optical coherence tomography |
| Q46251164 | 3D Histomorphometric Reconstruction and Quantification of the Optic Nerve Head Connective Tissues. |
| Q61797162 | A Novel Method for the Objective Identification of Hyperautofluorescent Ring in Retinitis Pigmentosa Using Binarization Processing |
| Q31130077 | A Statistical Model to Analyze Clinician Expert Consensus on Glaucoma Progression using Spatially Correlated Visual Field Data. |
| Q58715967 | A comparative study of structural, functional and circulatory parameters in glaucoma diagnostics |
| Q36306236 | A comparison of the diagnostic ability of vessel density and structural measurements of optical coherence tomography in primary open angle glaucoma |
| Q36202267 | A framework for comparing structural and functional measures of glaucomatous damage. |
| Q39865326 | A mathematical description of nerve fiber bundle trajectories and their variability in the human retina. |
| Q92734404 | A spatially varying change points model for monitoring glaucoma progression using visual field data |
| Q34414644 | A test of a linear model of glaucomatous structure-function loss reveals sources of variability in retinal nerve fiber and visual field measurements. |
| Q92468033 | Additive Role of Optical Coherence Tomography Angiography Vessel Density Measurements in Glaucoma Diagnoses |
| Q53243259 | Anatomic and functional correlation of frequency-doubling technology perimetry (FDTP) in multiple sclerosis. |
| Q35124305 | Anatomic vs. acquired image frame discordance in spectral domain optical coherence tomography minimum rim measurements. |
| Q87272666 | Anatomical and functional impairment of the nerve fiber layer in patients with optic nerve head drusen |
| Q35620366 | Applications of optical coherence tomography in pediatric clinical neuroscience |
| Q98577920 | Artificial Intelligence Mapping of Structure to Function in Glaucoma |
| Q37108485 | Assessing visual field clustering schemes using machine learning classifiers in standard perimetry |
| Q47199622 | Association of Functional Loss With the Biomechanical Response of the Optic Nerve Head to Acute Transient Intraocular Pressure Elevations |
| Q33854304 | Association of SIX1/SIX6 locus polymorphisms with regional circumpapillary retinal nerve fibre layer thickness: The Nagahama study. |
| Q45187625 | Attenuation of the retinal nerve fibre layer and reduced retinal function assessed by optical coherence tomography and full-field electroretinography in patients exposed to vigabatrin medication |
| Q36056146 | Automated quantification of optic nerve axons in primate glaucomatous and normal eyes--method and comparison to semi-automated manual quantification. |
| Q31143535 | Automatic identification of the temporal retinal nerve fiber raphe from macular cube data |
| Q60301303 | Bruch's membrane opening minimum rim width and retinal nerve fiber layer thickness in a Brazilian population of healthy subjects |
| Q54974067 | Bruch's membrane opening-minimum rim width and visual field loss in glaucoma: a broken stick analysis. |
| Q57030943 | Can we predict when to start renal replacement therapy in patients with chronic kidney disease using 6 months of clinical data? |
| Q92523263 | Case report: what gives the myopic tilted disc an oval appearance? |
| Q34311052 | Change of retinal nerve fiber layer thickness in patients with nonarteritic inflammatory anterior ischemic optic neuropathy |
| Q91893397 | Characteristics of Normal-tension Glaucoma Patients with Temporal Retinal Nerve Fibre Defects |
| Q53041174 | Characteristics of eyes with inner retinal cleavage. |
| Q36943824 | Choice of statistical method influences apparent association between structure and function in glaucoma |
| Q64272821 | Choroidal Microvascular Dropout in Pseudoexfoliation Glaucoma |
| Q37696911 | Choroidal area assessment in various fundus sectors of patients at different stages of primary open-angle glaucoma by using enhanced depth imaging optical coherence tomography |
| Q98779126 | Chromatic Pupilloperimetry Measures Correlate With Visual Acuity and Visual Field Defects in Retinitis Pigmentosa Patients |
| Q90168392 | Circumpapillary and macular vessel density assessment by optical coherence tomography angiography in eyes with temporal hemianopia from chiasmal compression. Correlation with retinal neural and visual field loss |
| Q35302214 | Circumpapillary course of retinal pigment epithelium can be fit to sine wave and amplitude of sine wave is significantly correlated with ovality ratio of optic disc |
| Q47155955 | Comparison between the Correlations of Retinal Nerve Fiber Layer Thickness Measured by Spectral Domain Optical Coherence Tomography and Visual Field Defects in Standard Automated White-on-White Perimetry versus Pulsar Perimetry. |
| Q87061018 | Comparison between visual field defect in pigmentary glaucoma and primary open-angle glaucoma |
| Q34515431 | Comparison of Spectralis-OCT, GDxVCC and GDxECC in assessing retinal nerve fiber layer (RNFL) in glaucomatous patients |
| Q37206071 | Comparison of Standard Automated Perimetry, Short-Wavelength Automated Perimetry, and Frequency-Doubling Technology Perimetry to Monitor Glaucoma Progression |
| Q34104172 | Comparison of multifocal visual evoked potential, standard automated perimetry and optical coherence tomography in assessing visual pathway in multiple sclerosis patients |
| Q46079192 | Comparison of multifocal visual evoked potential, static automated perimetry, and optical coherence tomography findings for assessing visual pathways in patients with pituitary adenomas. |
| Q41577660 | Comparison of peripapillary vessel density between preperimetric and perimetric glaucoma evaluated by OCT-angiography |
| Q36795735 | Correlating RNFL thickness by OCT with perimetric sensitivity in glaucoma patients |
| Q30932590 | Correlation analysis of visual field thresholds and scanning laser ophthalmoscopic optic nerve head measurements in glaucoma |
| Q50207779 | Correlation between N2 amplitude of multifocal ERGs and retinal sensitivity and retinal nerve fiber layer thickness in glaucomatous eyes |
| Q43079060 | Correlation between macular and retinal nerve fibre layer Fourier-domain OCT measurements and visual field loss in chiasmal compression. |
| Q37211239 | Correlation between peripapillary retinal nerve fiber layer thickness and fundus autofluorescence in primary open-angle glaucoma |
| Q36752305 | Correlation of localized glaucomatous visual field defects and spectral domain optical coherence tomography retinal nerve fiber layer thinning using a modified structure-function map for OCT |
| Q35580019 | Correlation of retinal nerve fiber layer thickness and visual fields in glaucoma: a broken stick model |
| Q42375857 | Correlations between local peripapillary choroidal thickness and axial length, optic disc tilt, and papillo-macular position in young healthy eyes |
| Q33266050 | Correlations between retinal nerve fiber layer and visual field in eyes with nonarteritic anterior ischemic optic neuropathy |
| Q37228974 | Cross-sectional study: Does combining optical coherence tomography measurements using the 'Random Forest' decision tree classifier improve the prediction of the presence of perimetric deterioration in glaucoma suspects? |
| Q33994214 | Decreased retinal ganglion cell layer thickness in patients with type 1 diabetes |
| Q49233887 | Deep Defects Seen on Visual Fields Spatially Correspond Well to Loss of Retinal Nerve Fiber Layer Seen on Circumpapillary OCT Scans |
| Q91782591 | Defective angles of localized retinal nerve fiber layer reflect the severity of visual field defect- a cross-sectional analysis |
| Q37626288 | Defects of the lamina cribrosa in eyes with localized retinal nerve fiber layer loss |
| Q42755901 | Deriving visual field loss based upon OCT of inner retinal thicknesses of the macula |
| Q46224257 | Detecting Glaucoma With a Portable Brain-Computer Interface for Objective Assessment of Visual Function Loss |
| Q41877681 | Detecting changes in retinal function: Analysis with Non-Stationary Weibull Error Regression and Spatial enhancement (ANSWERS). |
| Q40530401 | Detecting glaucoma with visual fields derived from frequency-domain optical coherence tomography |
| Q101051251 | Detection of functional deterioration in glaucoma by trend analysis using comprehensive overlapping clusters of locations |
| Q82957346 | Detection of macular and circumpapillary structural loss in normal hemifield areas of glaucomatous eyes with localized visual field defects using spectral-domain optical coherence tomography |
| Q51803537 | Determinants and Characteristics of Bruch's Membrane Opening and Bruch's Membrane Opening-Minimum Rim Width in a Normal Japanese Population. |
| Q48232227 | Diagnostic ability of Humphrey perimetry, Octopus perimetry, and optical coherence tomography for glaucomatous optic neuropathy |
| Q50467483 | Difference in the posterior pole profiles associated with the initial location of visual field defect in early-stage normal tension glaucoma. |
| Q85258473 | Differentiation by imaging of superior segmental optic hypoplasia and normal-tension glaucoma with inferior visual field defects only |
| Q36953161 | Distribution of damage to the entire retinal ganglion cell pathway: quantified using spectral-domain optical coherence tomography analysis in patients with glaucoma. |
| Q37551966 | Early glaucoma involves both deep local, and shallow widespread, retinal nerve fiber damage of the macular region |
| Q42647695 | Effects of ocular rotation on parapapillary retinal nerve fiber layer thickness analysis measured with spectral-domain optical coherence tomography |
| Q38892382 | Enhancement of Visual Field Predictions with Pointwise Exponential Regression (PER) and Pointwise Linear Regression (PLR). |
| Q91620442 | Estimating Rates of Progression and Predicting Future Visual Fields in Glaucoma Using a Deep Variational Autoencoder |
| Q91767858 | Estimating Visual Field Mean Deviation using Optical Coherence Tomographic Nerve Fiber Layer Measurements in Glaucoma Patients |
| Q35784579 | Estimating the Amount of Hemoglobin in the Neuroretinal Rim Using Color Images and OCT. |
| Q59334933 | Evaluation of Structure-Function Relationships in Longitudinal Changes of Glaucoma using the Spectralis OCT Follow-Up Mode |
| Q43241177 | Evaluation of Visual Field and Imaging Outcomes for Glaucoma Clinical Trials (An American Ophthalomological Society Thesis). |
| Q35521549 | Evaluation of a Method for Estimating Retinal Ganglion Cell Counts Using Visual Fields and Optical Coherence Tomography |
| Q33818741 | Evaluation of a combined index of optic nerve structure and function for glaucoma diagnosis |
| Q35066822 | Evaluation of inner retinal layers in eyes with temporal hemianopic visual loss from chiasmal compression using optical coherence tomography |
| Q92048927 | Evaluation of microvascular network with optical coherence tomography angiography (OCTA) in branch retinal vein occlusion (BRVO) |
| Q44881441 | Evaluation of relationship between retinal nerve fiber layer thickness progression and visual field progression in patients with glaucoma |
| Q36008824 | Evaluation of the Structure-Function Relationship in Glaucoma Using a Novel Method for Estimating the Number of Retinal Ganglion Cells in the Human Retina |
| Q58801264 | Evidence for alterations in fixational eye movements in glaucoma |
| Q51533499 | Examination of the performance of different pointwise linear regression progression criteria to detect glaucomatous visual field change. |
| Q48156670 | Exploration of peripapillary vessel density in highly myopic eyes with peripapillary intrachoroidal cavitation and its relationship with ocular parameters using optical coherence tomography angiography. |
| Q64116685 | Factors Related to Superior and Inferior Hemifield Defects in Primary Open-Angle Glaucoma |
| Q96231069 | Factors in Color Fundus Photographs That Can Be Used by Humans to Determine Sex of Individuals |
| Q48346262 | Glaucoma Diagnostic Ability of the Optical Coherence Tomography Angiography Vessel Density Parameters. |
| Q42337039 | Glaucomatous changes in lamina pores shape within the lamina cribrosa using wide bandwidth, femtosecond mode-locked laser OCT. |
| Q36487471 | Glaucomatous damage of the macula |
| Q84614264 | Global flash multifocal electroretinogram: early detection of local functional changes and its correlations with optical coherence tomography and visual field tests in diabetic eyes |
| Q42632355 | Goldmann V Standard Automated Perimetry Underestimates Central Visual Sensitivity in Glaucomatous Eyes with Increased Axial Length |
| Q91474663 | Home monitoring for glaucoma |
| Q35519065 | Hypodense regions (holes) in the retinal nerve fiber layer in frequency-domain OCT scans of glaucoma patients and suspects |
| Q37439223 | Idiopathic Acquired Temporal Wedge Visual Field Defects |
| Q27334795 | Imaging Glaucomatous Damage Across the Temporal Raphe |
| Q64090984 | Improved Detection of Visual Field Progression Using a Spatiotemporal Boundary Detection Method |
| Q60929905 | Improving Visual Field Examination of the Macula Using Structural Information |
| Q39052946 | Improving our understanding, and detection, of glaucomatous damage: An approach based upon optical coherence tomography (OCT). |
| Q57493556 | Improving the structure-function relationship in glaucomatous and normative eyes by incorporating photoreceptor layer thickness |
| Q34230887 | In vivo adaptive optics imaging of the temporal raphe and its relationship to the optic disc and fovea in the human retina |
| Q38978405 | Incorporating Spatial Models in Visual Field Test Procedures |
| Q34645751 | Initial Arcuate Defects within the Central 10 Degrees in Glaucoma |
| Q51732884 | Integrating independent spatio-temporal replications to assess population trends in disease spread. |
| Q33982090 | Integration and fusion of standard automated perimetry and optical coherence tomography data for improved automated glaucoma diagnostics |
| Q42355224 | Intraocular pressure and visual field changes in normal-tension glaucoma patients treated using either unoprostone or latanoprost: a prospective comparative study |
| Q36107003 | Intrasession and Between-Visit Variability of Sector Peripapillary Angioflow Vessel Density Values Measured with the Angiovue Optical Coherence Tomograph in Different Retinal Layers in Ocular Hypertension and Glaucoma |
| Q35161074 | Lamina cribrosa microarchitecture in normal monkey eyes part 1: methods and initial results |
| Q40825170 | Linking structure and function in glaucoma |
| Q39523978 | Localized Changes in Retinal Nerve Fiber Layer Thickness as a Predictor of Localized Functional Change in Glaucoma |
| Q89357434 | Long-term follow-up of retinal nerve fiber layer cleavages in glaucoma patients and suspects |
| Q37439892 | Macular Ganglion Cell Layer and Peripapillary Retinal Nerve Fibre Layer Thickness in Patients with Unilateral Posterior Cerebral Artery Ischaemic Lesion: An Optical Coherence Tomography Study |
| Q90566934 | Macular Imaging with Optical Coherence Tomography in Glaucoma |
| Q36790861 | Macular thickness as a predictor of loss of visual sensitivity in ethambutol-induced optic neuropathy |
| Q37697866 | Macular thickness measurements with frequency domain-OCT for quantification of axonal loss in chronic papilledema from pseudotumor cerebri syndrome |
| Q21132027 | Mapping glaucoma patients' 30-2 and 10-2 visual fields reveals clusters of test points damaged in the 10-2 grid that are not sampled in the sparse 30-2 grid |
| Q43753405 | Mapping the visual field |
| Q34330129 | Measurement of local retinal ganglion cell layer thickness in patients with glaucoma using frequency-domain optical coherence tomography |
| Q90376451 | Microvascular damage assessed by optical coherence tomography angiography for glaucoma diagnosis: a systematic review of the most discriminative regions |
| Q58777200 | Multicolor imaging for retinal nerve fiber layer defect in glaucoma |
| Q30847634 | Multifocal VEP and OCT in optic neuritis: a topographical study of the structure-function relationship |
| Q50073178 | Nerve Fiber Flux Analysis Using Wide-Field Swept-Source Optical Coherence Tomography |
| Q34398748 | On improving the use of OCT imaging for detecting glaucomatous damage |
| Q35834569 | Optic Disc - Fovea Angle: The Beijing Eye Study 2011 |
| Q38630362 | Optical Coherence Tomography Analysis Based Prediction of Humphrey 24-2 Visual Field Thresholds in Patients With Glaucoma. |
| Q44912171 | Pattern electroretinogram in neuromyelitis optica and multiple sclerosis with or without optic neuritis and its correlation with FD-OCT and perimetry |
| Q93048160 | Peripapillary Vessel Density In Unilateral Preperimetric Glaucoma |
| Q64973543 | Peripapillary Vessel Density Reversal after Trabeculectomy in Glaucoma. |
| Q92025166 | Peripapillary Vessel Density in Young Patients with Open-Angle Glaucoma: Comparison between High-Tension and Normal-Tension Glaucoma |
| Q96127321 | Point-wise correlations between 10-2 Humphrey visual field and OCT data in open angle glaucoma |
| Q81271840 | Pointwise linear progression criteria and the detection of visual field change in a glaucoma trial |
| Q37623449 | Posterior Pole Retinal Thickness for Detection of Structural Damage in Anterior Ischaemic Optic Neuropathy |
| Q89148878 | Prediction Accuracy of the Dynamic Structure-Function Model for Glaucoma Progression Using Contrast Sensitivity Perimetry and Confocal Scanning Laser Ophthalmoscopy |
| Q47129551 | Preperimetric Glaucoma Prospective Observational Study (PPGPS): Design, baseline characteristics, and therapeutic effect of tafluprost in preperimetric glaucoma eye. |
| Q49164858 | Preperimetric Glaucoma Prospective Study (PPGPS): Predicting Visual Field Progression With Basal Optic Nerve Head Blood Flow in Normotensive PPG Eyes |
| Q36175276 | Preserved retinal sensitivity in spatial correspondence to an intrachoroidal cavitation area with full thickness retinal defect: a case report |
| Q36766621 | Progressive loss of retinal ganglion cell function precedes structural loss by several years in glaucoma suspects |
| Q64080591 | Propagation and Selectivity of Axonal Loss in Leber Hereditary Optic Neuropathy |
| Q38821827 | Quadrant Field Pupillometry Detects Melanopsin Dysfunction in Glaucoma Suspects and Early Glaucoma |
| Q54957906 | Quantifying positional variation of retinal blood vessels in glaucoma. |
| Q91394296 | Quantitative automated circumpapillary microvascular density measurements: a new angioOCT-based methodology |
| Q47202464 | Reducing noise in suspected glaucomatous visual fields by using a new spatial filter. |
| Q33957323 | Reducing variability in visual field assessment for glaucoma through filtering that combines structural and functional information |
| Q36950963 | Regional correlation among ganglion cell complex, nerve fiber layer, and visual field loss in glaucoma |
| Q33930870 | Relation between macular retinal ganglion cell/inner plexiform layer thickness and multifocal electroretinogram measures in experimental glaucoma |
| Q48010721 | Relationship Between Central Retinal Vessel Trunk Location and Visual Field Loss in Glaucoma |
| Q89876473 | Relationship Between Funduscopic Conus and Optic Disc Factors Associated with Myopia in Young Healthy Eyes |
| Q42974379 | Relationship Between Optic Nerve Appearance and Retinal Nerve Fiber Layer Thickness as Explored with Spectral Domain Optical Coherence Tomography |
| Q33912249 | Relationship between Retinal Inner Nuclear Layer Thickness and Severity of Visual Field Loss in Glaucoma |
| Q36267999 | Relationship between optical coherence tomography sector peripapillary angioflow-density and Octopus visual field cluster mean defect values |
| Q33322717 | Relationship between scanning laser polarimetry with enhanced corneal compensation and with variable corneal compensation |
| Q33852898 | Relationship between spectral-domain optical coherence tomography and standard automated perimetry in healthy and glaucoma patients. |
| Q33611584 | Relationship between standard automated perimetry and retinal nerve fiber layer parameters measured with laser polarimetry |
| Q34956098 | Relationships of retinal structure and humphrey 24-2 visual field thresholds in patients with glaucoma |
| Q46490764 | Reproducibility of Optical Coherence Tomography Angiography Macular and Optic Nerve Head Vascular Density in Glaucoma and Healthy Eyes |
| Q36070021 | Retinal Ganglion Cell Layer Thinning Within One Month of Presentation for Non-Arteritic Anterior Ischemic Optic Neuropathy |
| Q38063776 | Retinal ganglion cell functional plasticity and optic neuropathy: a comprehensive model |
| Q41180108 | Retinal nerve fiber bundle tracing and analysis in human eye by polarization sensitive OCT. |
| Q44641953 | Retinal nerve fiber layer thickness measured with optical coherence tomography is related to visual function in glaucomatous eyes |
| Q34330104 | Retinal nerve fiber structure versus visual field function in patients with ischemic optic neuropathy. A test of a linear model |
| Q35354071 | Retinal nerve fibre layer and visual function loss in glaucoma: the tipping point |
| Q34803818 | Scanning laser polarimetry, but not optical coherence tomography predicts permanent visual field loss in acute nonarteritic anterior ischemic optic neuropathy |
| Q41238033 | Segmented inner plexiform layer thickness as a potential biomarker to evaluate open-angle glaucoma: Dendritic degeneration of retinal ganglion cell. |
| Q36969016 | Senescence of human multifocal electroretinogram components: a localized approach |
| Q42410233 | Some dissociating factors in the analysis of structural and functional progressive damage in open-angle glaucoma |
| Q46472911 | Spectral-domain optical coherence tomography analysis in deprivational amblyopia: a pilot study with unilateral pediatric cataract patients |
| Q34612319 | Standard automated perimetry versus matrix frequency doubling technology perimetry in subjects with ocular hypertension and healthy control subjects |
| Q58705173 | Steeper structure-function relationship in eyes with than without a parapapillary deep-layer microvasculature dropout |
| Q54472821 | Structural and functional assessment by hemispheric asymmetry testing of the macular region in preperimetric glaucoma. |
| Q33727849 | Structural parameters associated with location of peaks of peripapillary retinal nerve fiber layer thickness in young healthy eyes. |
| Q33714185 | Structure and function in patients with glaucomatous defects near fixation. |
| Q51247836 | Structure-Function Relationship between Flicker-Defined Form Perimetry and Spectral-Domain Optical Coherence Tomography in Glaucoma Suspects. |
| Q41157157 | Structure-Function Relationships in Perimetric Glaucoma: Comparison of Minimum-Rim Width and Retinal Nerve Fiber Layer Parameters. |
| Q33536892 | Structure-function correlations using scanning laser polarimetry in primary angle-closure glaucoma and primary open-angle glaucoma |
| Q89792909 | The Angioarchitecture of the Optic Nerve Head in Patients with Optic Disc Drusen |
| Q35656789 | The Effect of Cataract on Early Stage Glaucoma Detection Using Spatial and Temporal Contrast Sensitivity Tests |
| Q58708549 | The Relationship Between Bruch's Membrane Opening-Minimum Rim Width and Retinal Nerve Fiber Layer Thickness and a New Index Using a Neural Network |
| Q47141448 | The association between photoreceptor layer thickness measured by optical coherence tomography and visual sensitivity in glaucomatous eyes |
| Q41184602 | The association between retinal vein pulsation pressure and optic disc haemorrhages in glaucoma |
| Q39181801 | The connective tissue phenotype of glaucomatous cupping in the monkey eye - Clinical and research implications. |
| Q30977523 | The correlation between optic nerve head topographic measurements, peripapillary nerve fibre layer thickness, and visual field indices in glaucoma |
| Q34242957 | The effect of test variability on the structure-function relationship in early glaucoma. |
| Q87031171 | The glaucoma detection capability of spectral-domain OCT and GDx-VCC deviation maps in early glaucoma patients with localized visual field defects |
| Q33491500 | The location of the inferior and superior temporal blood vessels and interindividual variability of the retinal nerve fiber layer thickness |
| Q37296569 | The locations of circumpapillary glaucomatous defects seen on frequency-domain OCT scans |
| Q45005673 | The nerve fibre layer symmetry test: computerized evaluation of human retinal nerve fibre layer thickness as measured by optical coherence tomography |
| Q50218068 | The relationship between contrast sensitivity and retinal nerve fiber layer thickness in patients with glaucoma |
| Q35659189 | The relationship between retinal ganglion cell function and retinal nerve fiber thickness in early glaucoma. |
| Q53579442 | The relationship between structure and function as measured by OCT and Octopus perimetry. |
| Q34007622 | The relationship between visual field and retinal nerve fiber layer measurements in patients with multiple sclerosis |
| Q39391365 | The value of visual field testing in the era of advanced imaging: clinical and psychophysical perspectives |
| Q99411367 | Three-Dimensional Neuroretinal Rim Thickness and Visual Fields in Glaucoma: A Broken Stick Model |
| Q57706416 | Topographical Correlation Between Macular Layer Thickness and Clockwise Circumpapillary Retinal Nerve Fiber Layer Sectors in Patients with Normal Tension Glaucoma |
| Q39147523 | Trans-synaptic Retrograde Degeneration in the Human Visual System: Slow, Silent, and Real |
| Q36272409 | Transient Peripapillary Retinoschisis in Glaucomatous Eyes |
| Q47868064 | Tuning and spontaneous spike time synchrony share a common structure in macaque inferior temporal cortex |
| Q35589816 | Use of high spatial resolution perimetry to identify scotomata not apparent with conventional perimetry in the nasal field of glaucomatous subjects |
| Q42369571 | Usefulness of axonal tract-dependent OCT macular sectors for evaluating structural change in normal-tension glaucoma |
| Q49356734 | Validation of the structure-function correlation report from the heidelberg edge perimeter and spectral-domain optical coherence tomography |
| Q61804167 | Visual Crowding in Glaucoma |
| Q92642739 | Visual Field Prediction using Recurrent Neural Network |
| Q21560813 | Visual advantage in deaf adults linked to retinal changes |
| Q42430235 | Visual field defects and changes in macular retinal ganglion cell complex thickness in eyes with intrachoroidal cavitation are similar to those in early glaucoma |
| Q51736583 | Visual field defects and retinal nerve fiber imaging in patients with obstructive sleep apnea syndrome and in healthy controls. |
| Q83972232 | [Conventional perimetry. Antiquated or indispensable for functional glaucoma diagnostics?] |
| Q52670688 | [Structural endpoints for glaucoma studies]. |
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