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| [38] | Baseline retinal vascular bed area on ultra-wide field fluorescein angiography correlates with the anatomical outcome of diabetic macular oedema to ranibizumab therapy: two-year analysis of the DAVE Study (Fan, W, Uji, A, Wykoff, CC, Brown, DM, van Hemert, J, Falavarjani, KG, Wang, K, Sadda, SR and Ip, M), In Eye, volume 37, 2023. |
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| [37] | Choroidal vascular alterations evaluated by ultra-widefield indocyanine green angiography in central serous chorioretinopathy (S Jeong, W Kang, D Noh van Hemert, J and M Sagong), In Graefes Arch Clin Exp Ophthalmol, volume 260, 2022. |
| [36] | Multi-modal retinal scanning to measure retinal thickness and peripheral blood vessels in multiple sclerosis (Pearson, T, Chen, Y, Dhillon, B, Chandran, S, van Hemert, J and MacGillivray, T), In Sci. Rep., Springer Science and Business Media LLC, volume 12, 2022. |
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| [35] | Effects of refractive power on quantification using ultra-widefield retinal imaging (Lim, S-H, Jeong, S, Ahn, JH, van Hemert, J and Sagong, M), In BMC Ophthalmology, volume 21, 2021. |
| [34] | Retinal vascular bed area on ultra-wide field fluorescein angiography indicates the severity of diabetic retinopathy (Fan, W, Uji, A, Nittala, M, Wykoff, CC, Brown, D, Fleming, A, Robertson, G, van Hemert, J, Sadda, S and Ip, M S), In Br J Ophthalmol, 2021. |
| [33] | A New Biomarker Quantifying The Effect Of Anti-VEGF Therapy In Eyes With Proliferative Diabetic Retinopathy On Ultra-wide Field Fluorescein Angiography: Recovery Study (Fan, W, Nittala, M G, Wykoff, CC, Brown, DM, Uji, A, van Hemert, J, Fleming, A, Robertson, G, Sadda, SR and Ip, M), In Retina, 2021. |
| [32] | Macular Microvascular Changes and Their Correlation With Peripheral Nonperfusion in Branch Retinal Vein Occlusion (Ryu, G, Park, D, Lim, J, van Hemert, J and Sagong, M), In Am J Ophthalmol, volume 225, 2021. |
| [31] | Relationship between distribution and severity of non-perfusion and cytokine levels and macular thickness in branch retinal vein occlusion (Ryu, G, Noh, D, van Hemert, J, Sadda, SR and Sagong, M), In Scient Rep, volume 11, 2021. |
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| [30] | Fractal analysis of retinal vasculature in normal subjects on ultra-wide field fluorescein angiography (Fan, W-Y, Fleming, A, Robertson, G, Uji, A, van Hemert, J, Singer, M, Sagong, M, Ip, M and Sadda, SR), In Int. J. Ophthalmol., volume 13, 2020. |
| [29] | Quantitative analysis of choroidal vasculature in polypoidal choroidal vasculopathy using ultra-widefield indocyanine green angiography (Ryu, G, Moon, C, van Hemert, J and Sagong, M), In Nature Scient Rep, volume 10, 2020. |
| [28] | Retinal vascular caliber association with nonperfusion and diabetic retinopathy severity depends on vascular caliber measurement location (Ashraf, M, Shokrollahi, S, Pisig, AU, Sampani, K, Abdelal, O, Cavallerano, JD, Robertson, G, Fleming, A, van Hemert, J, Pitoc, CM, Sun, JK, Aiello, LP and Silva, PS), In Ophthalmol Retina, 2020. |
| [27] | Distribution of peripheral lesions identified by mydriatic ultra-wide field fundus imaging in diabetic retinopathy (Verma, A, Alagorie, AR, Ramasamy, K, van Hemert, J, Yadav, H, Pappuru, RR, Tufail, A, Nittala, MG, Sadda, SR and Raman, R), In Graefe's Archive for Clinical and Experimental Ophthalmology, volume 258, 2020. |
| [26] | Association between hypertension and retinal vascular features in ultra-widefield fundus imaging (Robertson, G, Fleming, A, Williams, MC, Trucco, E, Quinn, N, Hogg, R, McKay, GJ, Kee, F, Young, I, Pellegrini, E, Newby, DE, van Beek, EJR, Peto, T, Dhillon, B, van Hemert, J and MacGillivray, TJ), In Open Heart, volume 7, 2020. |
| [25] | Distribution and Location of Vortex Vein Ampullae in Healthy Human Eyes as Assessed by Ultra-Widefield Indocyanine Green Angiography (Verma, A, Maram, J, Alagorie, AR, Gupta Nittala, M, van Hemert, J, Keane, D, Carnevale, J, Bell, D, Singer, M and Sadda, SR), In Ophthalmol Retina, volume 4, 2020. |
| [24] | Peripheral extent of the choroidal circulation by ultra-widefield indocyanine green angiography in healthy eyes (Verma, A, Maram, J, Alagorie, AR, van Hemert, J, Bell, DJ, Singer, M, Keane, D, Carnevale, J, Nittala, M and Sadda, SR), In Br J Ophthalmol, 2020. |
| [23] | Optic Disc and Fovea Localisation in Ultra-widefield Scanning Laser Ophthalmoscope Images Captured in Multiple Modalities (Wakeford, PR, Pellegrini, E, Robertson, G, Verhoek, M, Fleming, AD, van Hemert, J and Heng, IS), In Communications in Computer and Information Science (Zheng, Yalin, Williams, Bryan M., Chen, Ke, eds.), Springer International Publishing, 2020. |
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| [22] | Effect of phase-plate adjustment on retinal image sharpness and visible retinal area on ultrawide-field imaging (A Gupta, H El-Rami, R Barham, A Fleming, van Hemert, J, JK Sun, PS Silva and LP Aiello), In Eye, Springer Nature America, 2019. |
| [21] | Classification of Regions of Nonperfusion on Ultra-widefield Fluorescein Angiography in patients with Diabetic Macular Edema (Fang, M, Fan, W, Shi, Y, Ip, MS, Wykoff, CC, Wang, K, Falavarjani, KG, Brown, DM, van Hemert, J and Sadda, SR), In Am J Ophthalmol, Elsevier, 2019. |
| [20] | Severity of diabetic macular edema correlates with retinal vascular bed area on ultra-wide field fluorescein angiography. DAVE Study. (Fan, W, Uji, A, Wang, K, Falavarjani, KG, Wykoff, CC, Brown, DM, van Hemert, J, Sagong, M, Sadda, SR and Ip, M), In Retina, 2019. |
| [19] | Imaging of the eye (van Hemert, J and Verhoek, M), USPTO, 2019, US10357150B2 with priority to GB201307990D0. |
| [18] | Imaging of the eye (van Hemert, J., Verhoek, M., Brown, D., Wykoff, C. and Croft, D.), USPTO, 2019, US10349825B2 with priority to GB201307990D0. |
| [17] | Improvements in and Relating to Imaging of the Eye (van Hemert, J. and Verhoek, M.), EPO, 2019, EP2800058B2 with priority to GB201307990D0. |
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| [16] | Changes in retinal ischaemic index correlate with recalcitrant macular oedema in retinal vein occlusion: WAVE study (Kwon, S, Wykoff, CC, Brown, DM, van Hemert, J, Fan, W and Sadda, SR), In Br J Ophthalmol, BMJ Publishing Group Ltd, 2018. |
| [15] | Precise Measurement of Retinal Vascular Bed Area and Density on Ultra-wide Fluorescein Angiography in Normal Subjects (Fan, W, Uji, A, Borrelli, E, Singer, M, Sagong, M, van Hemert, J and Sadda, SR), In Am J Ophthalmol, Elsevier, volume 188, 2018. |
| [14] | Comparison of subjective assessment and precise quantitative assessment of lesion distribution in diabetic retinopathy (Sears, C, Nittala, MG, Jayadev, C, M Verhoek, A Fleming, van Hemert, J, Tsui, I and SriniVas RS), In JAMA Ophthalmology, volume 136, 2018. |
| [13] | Ultra-Wide-Field Fluorescein Angiography-Guided Normalization of Ischemic Index Calculation in Eyes With Retinal Vein Occlusion (Wang, K, Ghasemi Falavarjani, K, Nittala, MG, Sagong, M, Wykoff, CC, van Hemert, J, Ip, M and Sadda, SR), In Invest. Ophthalmol. Vis. Sci., volume 59, 2018. |
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| [12] | Distribution of Nonperfusion Area on Ultra-widefield Fluorescein Angiography in Eyes With Diabetic Macular Edema: DAVE Study (Fan, W, Wang, K, Ghasemi Falavarjani, K, Sagong, M, Uji, A, Ip, M, Wykoff, CC, Brown, DM, van Hemert, J and Sadda, SR), In Am J Ophthalmol, volume 180, 2017. |
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| [11] | Ultra-widefield Imaging of the Peripheral Retinal Vasculature in Normal Subjects (M Singer, M Sagong, van Hemert, J, L Kuehlewein, D Bell and SR Sadda), In Ophthalmology, volume 123, 2016. |
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| [10] | Application of a wide-field phantom eye for optical coherence tomography and reflectance imaging (Corcoran, A, Muyo, G, van Hemert, J, Gorman, A and Harvey, A), In J Mod Optics, volume 62, 2015. |
| [9] | Supplement 173: Wide Field Ophthalmic Photography Image Storage SOP Classes (DICOM Standards Committee), DICOM Work Item 2013-12-A undertaken by WG 9 (Ophthalmology), 2015. |
| [8] | Retinal Area Detector From Scanning Laser Ophthalmoscope Images for Diagnosing Retinal Diseases (Haleem, MS, Liangxiu Han, van Hemert, J, Baihua Li and Fleming, A), In IEEE J Biomed Health Inform, volume 19, 2015. |
| [7] | Improvements in and relating to imaging of the eye (van Hemert, J, Wykoff, C, Verhoek, M, Brown, D and Daniel, C), Patent Pending, 2015, WO2015GB51301. |
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| [6] | Precise montaging and metric quantification of retinal surface area from ultra-widefield fundus photography and fluorescein angiography. (Croft, DE, van Hemert, J, Wykoff, CC, Clifton, D, Verhoek, M, Fleming, A and Brown, DM), In Ophthalmic Surg Lasers Imaging Retina, volume 45, 2014. |
| [5] | IMAGING OF THE EYE (van Hemert, J and Verhoek, M), Patent Pending, 2014, US 20140327877. |
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| [4] | Automatic Extraction of the Optic Disc Boundary for Detecting Retinal Diseases (MS Haleem, L Han, B Li, A Nisbet, J van Hemert and M Verhoek), In Comp Graphics Imag (L Linsen, M Kampel, eds.), ACTA Press, volume 798, 2013. |
| [3] | Automatic extraction of retinal features from colour retinal images for glaucoma diagnosis: A review (Haleem, MS, Han, L, van Hemert, J and Li, B), In Comput Med Imaging Graph, Elsevier Science, volume 37, 2013. |
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| [2] | Transition Models as an incremental approach for problem solving in Evolutionary Algorithms (A Defaweux, T Lenaerts, van Hemert, J and J Parent), In Genetic and Evolutionary Computation (H-G Beyer et al., ed.), ACM Press, volume 7, 2005. |
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| [1] | Measuring the Searched Space to Guide Efficiency: The Principle and Evidence on Constraint Satisfaction (van Hemert, J and T Bäck), In Parallel Problem Solving from Nature (JJ Merelo, A Panagiotis, H-G Beyer, José-Luis Fernández-Villacañas, Hans-Paul Schwefel, eds.), Springer, volume 2439, 2002. |