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Journal of Imaging Informatics in Medicine

Erschienen in:

29.05.2019 | Original Paper

Artery/Vein Vessel Tree Identification in Near-Infrared Reflectance Retinographies

verfasst von: Joaquim de Moura, Jorge Novo, José Rouco, Pablo Charlón, Marcos Ortega

Erschienen in: Journal of Imaging Informatics in Medicine | Ausgabe 6/2019

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Abstract

An accurate identification of the retinal arteries and veins is a relevant issue in the development of automatic computer-aided diagnosis systems that facilitate the analysis of different relevant diseases that affect the vascular system as diabetes or hypertension, among others. The proposed method offers a complete analysis of the retinal vascular tree structure by its identification and posterior classification into arteries and veins using optical coherence tomography (OCT) scans. These scans include the near-infrared reflectance retinography images, the ones we used in this work, in combination with the corresponding histological sections. The method, firstly, segments the vessel tree and identifies its characteristic points. Then, Global Intensity-Based Features (GIBS) are used to measure the differences in the intensity profiles between arteries and veins. A k-means clustering classifier employs these features to evaluate the potential of artery/vein identification of the proposed method. Finally, a post-processing stage is applied to correct misclassifications using context information and maximize the performance of the classification process. The methodology was validated using an OCT image dataset retrieved from 46 different patients, where 2,392 vessel segments and 97,294 vessel points were manually labeled by an expert clinician. The method achieved satisfactory results, reaching a best accuracy of 93.35% in the identification of arteries and veins, being the first proposal that faces this issue in this image modality.

Albrecht P, Ringelstein M, Müller A, Keser N, Dietlein T, Lappas A, Foerster A, Hartung H, Aktas O, Methner A: Degeneration of retinal layers in multiple sclerosis subtypes quantified by Optical Coherence Tomography. Mult Scler J 18(10): 1422–1429, 2012CrossRef

Baamonde S, de Moura J, Novo J, Ortega M (2017) Automatic detection of epiretinal membrane in OCT images by means of local luminosity patterns. In: International work-conference on artificial neural networks, pp 222–235

Barreira N, Ortega M, Rouco J, Penedo M, Pose-Reino A, Mariño C: Semi-automatic procedure for the computation of the arteriovenous ratio in retinal images. Int J Comput Vis Biomechan 3(2): 135–147, 2010

Bellazzi R, Montani S, Riva A, Stefanelli M: Web-based telemedicine systems for home-care: technical issues and experiences. Comput Methods Programs Biomed 64(3): 175–187, 2001CrossRef

Biswas S, Lovell BC (2007) Bézier and splines in image processing and machine vision. Science and Business Media:109–121

Blanco M, Penedo M, Barreira N, Penas M, Carreira MJ (2006) Localization and extraction of the optic disc using the fuzzy circular hough transform. In: International conference on artificial intelligence and soft computing, pp 712–721

de Boor C: A practical guide to splines. Appl Math Sci 27: 1–7, 1978

Bowd C, Weinreb RN, Williams JM, Zangwill LM: The retinal nerve fiber layer thickness in ocular hypertensive, normal, and glaucomatous eyes with Optical Coherence Tomography. Arch Ophthalmol 118(1): 22–26, 2000CrossRef

Caderno I, Penedo M, Barreira N, Mariño C, Gonzalez F: Precise detection and measurement of the retina vascular tree. Pattern Recogn Image Anal (Adv Math Theory Appl) 15(2): 523–526, 2005

10.

Calvo D, Ortega M, Penedo M, Rouco J: Automatic detection and characterisation of retinal vessel tree bifurcations and crossovers in eye fundus images. Comput Methods Programs Biomed 103(1): 28–38, 2011CrossRef

11.

Canny J (1986) A computational approach to edge detection. IEEE Transactions on Pattern Analysis and Machine Intelligence (6):679–698CrossRef

12.

Dashtbozorg B, Mendonċa AM, Campilho A (2013) Automatic classification of retinal vessels using structural and intensity information. In: Iberian conference on pattern recognition and image analysis, pp 600–607CrossRef

13.

Diamond E: Manual of diagnostic imaging: a clinician’s guide to clinical problem solving. Radiology 157(1): 18–18, 1985CrossRef

14.

Dougherty E: Mathematical morphology in image processing New York: CRC Press, 1992

15.

Earley M: Clinical anatomy of the eye. Optom Vis Sci 77(5): 231–232, 2000CrossRef

16.

Fercher AF, Drexler W, Hitzenberger CK, Lasser T: Optical Coherence Tomography-principles and applications. Rep Progress Phys 66(2): 239, 2003CrossRef

17.

Frangi AF, Niessen WJ, Vincken KL, Viergever MA (1998) Multiscale vessel enhancement filtering. In: International conference on medical image computing and computer-assisted intervention, pp 130–137CrossRef

18.

Gómes E, Del Pozo F, Quiles J, Arredondo M, Rahms H, Sanz M, Cano P, et al.: A telemedicine system for remote cooperative medical imaging diagnosis. Comput Methods Programs Biomed 49(1): 37–48, 1996CrossRef

19.

González-López A, Ortega M, Penedo M, Charlón P (2014) Automatic robust segmentation of retinal layers in OCT images with refinement stages. In: International conference image analysis and recognition, pp 337–345

20.

Grisan E, Ruggeri A (2003) A divide et impera strategy for automatic classification of retinal vessels into arteries and veins. In: Engineering in Medicine and Biology Society, 2003. Proceedings of the 25th annual international conference of the IEEE, vol 1, pp 890–893

21.

Ho A: Retina: Color Atlas & Synopsis of Clinical Ophthalmology (Wills Eye Hospital Series) New York: McGraw-Hill Professional, 2003

22.

Huang T, Yang G, Tang G: A fast two-dimensional median filtering algorithm. IEEE Trans Acoust Speech Signal Process 27(1): 13–18, 1979CrossRef

23.

Hubbard LD, Brothers RJ, King WN, Clegg LX, Klein R, Cooper LS, Sharrett AR, Davis MD, Cai J: Methods for evaluation of retinal microvascular abnormalities associated with hypertension/sclerosis in the atherosclerosis risk in communities study. Ophthalmology 106(12): 2269–2280, 1999CrossRef

24.

Ikram M, De Jong F, Bos M, Vingerling J, Hofman A, Koudstaal PJ, De Jong P, Breteler M: Retinal vessel diameters and risk of stroke the rotterdam study. Neurology 66(9): 1339–1343, 2006CrossRef

25.

Jonas JB, Schmidt AM, Müller-Bergh J, Schlötzer-Schrehardt U, Naumann G: Human optic nerve fiber count and optic disc size. Invest Ophthalmol Vis Sci 33(6): 2012–2018, 1992PubMed

26.

Joshi VS, Reinhardt JM, Garvin MK, Abramoff MD: Automated method for identification and artery-venous classification of vessel trees in retinal vessel networks. PloS One 9(2): e88,061, 2014CrossRef

27.

Kass M, Witkin A, Terzopoulos D (1987) Snakes: Active contour models. In: 1St international conference on computer vision, vol 259, pp 268

28.

Kondermann C, Kondermann D, Yan M, et al. (2007) Blood vessel classification into arteries and veins in retinal images. In: Proceedings of SPIE Medical Imaging, pp 651,247–6512,479

29.

López AM, Lloret D, Serrat J, Villanueva JJ: Multilocal creaseness based on the level-set extrinsic curvature. Comput Vis Image Underst 77(2): 111–144, 2000CrossRef

30.

MacQueen J (1967) Some methods for classification and analysis of multivariate observations. In: Proceedings of the fifth Berkeley Symposium on Mathematical Statistics and Probability, vol 1, pp 281–297

31.

de Moura J, Novo J, Charlón P, Barreira N, Ortega M: Enhanced visualization of the retinal vasculature using depth information in OCT. Med Biol Eng Comput 55(12): 2209–2225, 2017CrossRef

32.

de Moura J, Novo J, Rouco J, Penedo M, Ortega M (2017) Automatic identification of intraretinal cystoid regions in Optical Coherence Tomography. In: Conference on artificial intelligence in medicine in Europe, pp 305–315

33.

Novo J, Penedo M, Santos J (2008) Optic disc segmentation by means of GA-optimized Topological Active Nets. In: International conference image analysis and recognition, pp 807–816

34.

Ortega M, Barreira N, Novo J, Penedo M, Pose-Reino A, Gómez-Ulla F: Sirius: a web-based system for retinal image analysis. Int J Med Inf 79(10): 722–732, 2010CrossRef

35.

Philip KP, Dove EL, McPherson DD, Gotteiner NL, Stanford W, Chandran KB: The fuzzy hough transform-feature extraction in medical images. IEEE Trans Med Imaging 13(2): 235–240, 1994CrossRef

36.

Puzyeyeva O, Lam WC, Flanagan JG, Brent MH, Devenyi RG, Mandelcorn MS, Wong T, Hudson C: High-resolution Optical Coherence Tomography retinal imaging: a case series illustrating potential and limitations. J Ophthalmol 2011: 1–6, 2011CrossRef

37.

Relan D, MacGillivray T, Ballerini L, Trucco E (2013) Retinal vessel classification: sorting arteries and veins. In: Engineering in medicine and biology society, 2013 35th annual international conference of the IEEE, pp 7396–7399

38.

Relan D, MacGillivray T, Ballerini L, Trucco E (2014) Automatic retinal vessel classification using a least square-support vector machine in vampire. In: 2014 36th annual international conference of the IEEE Engineering in medicine and biology society, pp 142–145

39.

Rothaus K, Jiang X, Rhiem P: Separation of the retinal vascular graph in arteries and veins based upon structural knowledge. Image Vis Comput 27(7): 864–875, 2009CrossRef

40.

Samagaio G, Estévez A, de Moura J, Novo J, Fernandez MI: Ortega, m.: automatic macular edema identification and characterization using OCT images. Comput Methods Programs Biomed 21: 327–335, 2018

41.

Sánchez L, Barreira N, Penedo M, de Tuero GC (2014) Computer aided diagnosis system for retinal analysis: automatic assessment of the vascular tortuosity. In: Studies in health technology and informatics: Innovation in medicine and healthcare, pp 55–64

42.

Sánchez-Tocino H., Alvarez-Vidal A, Maldonado MJ, Moreno-Montaṅés J, Garcia-Layana A: Retinal thickness study with Optical Coherence Tomography in patients with diabetes. Invest Ophthalmol Vis Sci 43(5): 1588–1594, 2002PubMed

43.

Schmitt JM: Optical Coherence Tomography (OCT): a review. IEEE J Sel Top Quantum Electron 5(4): 1205–1215, 1999CrossRef

44.

Simó A, de Ves E: Segmentation of macular fluorescein angiographies. A statistical approach. Pattern Recogn 34(4): 795–809, 2001CrossRef

45.

Sinthanayothin C, Boyce JF, Cook HL, Williamson TH: Automated localisation of the optic disc, fovea, and retinal blood vessels from digital colour fundus images. Br J Ophthalmol 83(8): 902–910, 1999CrossRef

46.

Vázquez S, Cancela B, Barreira N, Penedo M, Rodríguez-blanco M, Seijo MP, de Tuero GC, Barceló MA, Saez M: Improving retinal artery and vein classification by means of a minimal path approach. Mach Vis Appl 24(5): 919–930, 2013CrossRef

47.

Williams ZY, Schuman JS, Gamell L, Nemi A, Hertzmark E, Fujimoto JG, Mattox C, Simpson J, Wollstein G: Optical Coherence Tomography measurement of nerve fiber layer thickness and the likelihood of a visual field defect. Amer J Ophthalmol 134(4): 538–546, 2002CrossRef

48.

Wong TY, Klein R, Sharrett AR, Schmidt MI, Pankow JS, Couper DJ, Klein BE, Hubbard LD, Duncan BB: Retinal arteriolar narrowing and risk of diabetes mellitus in middle-aged persons. J Amer Med Assoc 287(19): 2528–2533, 2002CrossRef

49.

Xu X, Ding W, Abràmoff MD, Cao R: An improved arteriovenous classification method for the early diagnostics of various diseases in retinal image. Comput Methods Programs Biomed 141: 3–9, 2017CrossRef

50.

Yang Y, Bu W, Wang K, Zheng Y, Wu X (2016) Automated artery-vein classification in fundus color images. In: International conference of young computer scientists, engineers and educators, pp 228–237

51.

Yu S, Wei Z, Deng RH, Yao H, Zhao Z, Ngoh LH, Wu Y (2008) A tele-ophthalmology system based on secure video-conferencing and white-board. In: 2008. Healthcom 2008. 10th international conference E-health networking, applications and services, pp 51–52

Titel: Artery/Vein Vessel Tree Identification in Near-Infrared Reflectance Retinographies
verfasst von: Joaquim de Moura
Jorge Novo
José Rouco
Pablo Charlón
Marcos Ortega
Publikationsdatum: 29.05.2019
Verlag: Springer International Publishing
Erschienen in: Journal of Imaging Informatics in Medicine / Ausgabe 6/2019
Print ISSN: 2948-2925
Elektronische ISSN: 2948-2933
DOI: https://doi.org/10.1007/s10278-019-00235-x

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Artery/Vein Vessel Tree Identification in Near-Infrared Reflectance Retinographies

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