| # | Title | Journal | Year | Citations |
|---|
| 1 | The Biomechanical Effect of Corneal Collagen Cross-Linking (CXL) With Riboflavin and UV-A is Oxygen Dependent | Translational Vision Science and Technology | 2013 | 192 |
| 2 | Inherited Retinal Degenerations: Current Landscape and Knowledge Gaps | Translational Vision Science and Technology | 2018 | 168 |
| 3 | Introduction to Machine Learning, Neural Networks, and Deep Learning | Translational Vision Science and Technology | 2020 | 146 |
| 4 | The Nature of Macular Damage in Glaucoma as Revealed by Averaging Optical Coherence Tomography Data | Translational Vision Science and Technology | 2012 | 134 |
| 5 | Factors Affecting Perceptual Threshold in Argus II Retinal Prosthesis Subjects | Translational Vision Science and Technology | 2013 | 122 |
| 6 | Why Do People (Still) Go Blind from Glaucoma? | Translational Vision Science and Technology | 2015 | 118 |
| 7 | Terpinen-4-ol is the Most Active Ingredient of Tea Tree Oil to KillDemodexMites | Translational Vision Science and Technology | 2013 | 109 |
| 8 | A Clinician's Guide to Artificial Intelligence: How to Critically Appraise Machine Learning Studies | Translational Vision Science and Technology | 2020 | 109 |
| 9 | Computer-Based Image Analysis for Plus Disease Diagnosis in Retinopathy of Prematurity: Performance of the “i-ROP” System and Image Features Associated With Expert Diagnosis | Translational Vision Science and Technology | 2015 | 105 |
| 10 | Deep Learning-Based Automated Classification of Multi-Categorical Abnormalities From Optical Coherence Tomography Images | Translational Vision Science and Technology | 2018 | 105 |
| 11 | Injectable Chemically Crosslinked Hydrogel for the Controlled Release of Bevacizumab in Vitreous: A 6-Month In Vivo Study | Translational Vision Science and Technology | 2015 | 103 |
| 12 | Insights into Systemic Disease through Retinal Imaging-Based Oculomics | Translational Vision Science and Technology | 2020 | 103 |
| 13 | Assessing the Accuracy of Foveal Avascular Zone Measurements Using Optical Coherence Tomography Angiography: Segmentation and Scaling | Translational Vision Science and Technology | 2017 | 102 |
| 14 | The 24-2 Visual Field Test Misses Central Macular Damage Confirmed by the 10-2 Visual Field Test and Optical Coherence Tomography | Translational Vision Science and Technology | 2016 | 101 |
| 15 | Choroidal Vascularity Index in Vogt-Koyanagi-Harada Disease: An EDI-OCT Derived Tool for Monitoring Disease Progression | Translational Vision Science and Technology | 2016 | 100 |
| 16 | Oral Mineralocorticoid-Receptor Antagonists: Real-Life Experience in Clinical Subtypes of Nonresolving Central Serous Chorioretinopathy With Chronic Epitheliopathy | Translational Vision Science and Technology | 2016 | 89 |
| 17 | Automatic Detection of Diabetic Retinopathy in Retinal Fundus Photographs Based on Deep Learning Algorithm | Translational Vision Science and Technology | 2019 | 89 |
| 18 | A Review of Deep Learning for Screening, Diagnosis, and Detection of Glaucoma Progression | Translational Vision Science and Technology | 2020 | 89 |
| 19 | Liquid Biopsy of Vitreous Reveals an Abundant Vesicle Population Consistent With the Size and Morphology of Exosomes | Translational Vision Science and Technology | 2018 | 86 |
| 20 | Current Challenges and Barriers to Real-World Artificial Intelligence Adoption for the Healthcare System, Provider, and the Patient | Translational Vision Science and Technology | 2020 | 85 |
| 21 | Olfactory Ensheathing Cells Rescue Optic Nerve Fibers in a Rat Glaucoma Model | Translational Vision Science and Technology | 2012 | 81 |
| 22 | Topical, Aqueous, Clear Cyclosporine Formulation Design for Anterior and Posterior Ocular Delivery | Translational Vision Science and Technology | 2015 | 80 |
| 23 | Transfer Learning for Automated OCTA Detection of Diabetic Retinopathy | Translational Vision Science and Technology | 2020 | 78 |
| 24 | A Comparison of Perimetric Results from a Tablet Perimeter and Humphrey Field Analyzer in Glaucoma Patients | Translational Vision Science and Technology | 2016 | 77 |
| 25 | Ensemble Deep Learning for Diabetic Retinopathy Detection Using Optical Coherence Tomography Angiography | Translational Vision Science and Technology | 2020 | 76 |
| 26 | VEGF and Intraocular Neovascularization: From Discovery to Therapy | Translational Vision Science and Technology | 2016 | 74 |
| 27 | Quantitative Analysis of Mouse Retinal Layers Using Automated Segmentation of Spectral Domain Optical Coherence Tomography Images | Translational Vision Science and Technology | 2015 | 72 |
| 28 | Transplantation of Human Embryonic Stem Cell-Derived Retinal Cells into the Subretinal Space of a Non-Human Primate | Translational Vision Science and Technology | 2017 | 72 |
| 29 | A Smartphone-Based Tool for Rapid, Portable, and Automated Wide-Field Retinal Imaging | Translational Vision Science and Technology | 2018 | 66 |
| 30 | A Single Wide-Field OCT Protocol Can Provide Compelling Information for the Diagnosis of Early Glaucoma | Translational Vision Science and Technology | 2016 | 65 |
| 31 | Suprachoroidal Corticosteroid Administration: A Novel Route for Local Treatment of Noninfectious Uveitis | Translational Vision Science and Technology | 2016 | 65 |
| 32 | Applications of Artificial Intelligence to Electronic Health Record Data in Ophthalmology | Translational Vision Science and Technology | 2020 | 64 |
| 33 | Topical Ocular Drug Delivery to the Back of the Eye by Mucus-Penetrating Particles | Translational Vision Science and Technology | 2015 | 62 |
| 34 | Central Glaucomatous Damage of the Macula Can Be Overlooked by Conventional OCT Retinal Nerve Fiber Layer Thickness Analyses | Translational Vision Science and Technology | 2015 | 62 |
| 35 | Deep Learning Algorithm for Automated Diagnosis of Retinopathy of Prematurity Plus Disease | Translational Vision Science and Technology | 2019 | 62 |
| 36 | Validation of a Tablet as a Tangent Perimeter | Translational Vision Science and Technology | 2016 | 61 |
| 37 | Artificial Intelligence to Stratify Severity of Age-Related Macular Degeneration (AMD) and Predict Risk of Progression to Late AMD | Translational Vision Science and Technology | 2020 | 61 |
| 38 | Natural Bioadhesive Biodegradable Nanoparticle-Based Topical Ophthalmic Formulations for Management of Glaucoma | Translational Vision Science and Technology | 2015 | 60 |
| 39 | Longitudinal and Cross-Sectional Analyses of Age Effects on Retinal Nerve Fiber Layer and Ganglion Cell Complex Thickness by Fourier-Domain OCT | Translational Vision Science and Technology | 2016 | 58 |
| 40 | Efficacy and Complications of Intravitreal Rituximab Injection for Treating Primary Vitreoretinal Lymphoma | Translational Vision Science and Technology | 2012 | 57 |
| 41 | Implantable MicroPump for Drug Delivery in Patients with Diabetic Macular Edema | Translational Vision Science and Technology | 2014 | 57 |
| 42 | Advancing Clinical Trials for Inherited Retinal Diseases: Recommendations from the Second Monaciano Symposium | Translational Vision Science and Technology | 2020 | 56 |
| 43 | Artificial Intelligence in Retinopathy of Prematurity Diagnosis | Translational Vision Science and Technology | 2020 | 56 |
| 44 | Methodological Challenges of Deep Learning in Optical Coherence Tomography for Retinal Diseases: A Review | Translational Vision Science and Technology | 2020 | 56 |
| 45 | An Automated Reference Frame Selection (ARFS) Algorithm for Cone Imaging with Adaptive Optics Scanning Light Ophthalmoscopy | Translational Vision Science and Technology | 2017 | 55 |
| 46 | Towards Standardization of Quantitative Retinal Vascular Parameters: Comparison of SIVA and VAMPIRE Measurements in the Lothian Birth Cohort 1936 | Translational Vision Science and Technology | 2018 | 55 |
| 47 | Imaging Artifacts and Segmentation Errors With Wide-Field Swept-Source Optical Coherence Tomography Angiography in Diabetic Retinopathy | Translational Vision Science and Technology | 2019 | 55 |
| 48 | Beyond Retinal Layers: A Deep Voting Model for Automated Geographic Atrophy Segmentation in SD-OCT Images | Translational Vision Science and Technology | 2018 | 54 |
| 49 | An Ophthalmic Targeted Exome Sequencing Panel as a Powerful Tool to Identify Causative Mutations in Patients Suspected of Hereditary Eye Diseases | Translational Vision Science and Technology | 2019 | 54 |
| 50 | VFMA: Topographic Analysis of Sensitivity Data From Full-Field Static Perimetry | Translational Vision Science and Technology | 2015 | 53 |
