Abstract
Recently, there has been an advancement in the development of innovative computer-aided techniques for the segmentation and classification of retinal vessels, the application of which is predominant in clinical applications. Consequently, this study aims to provide a detailed overview of the techniques available for segmentation and classification of retinal vessels. Initially, retinal fundus photography and retinal image patterns are briefly introduced. Then, an introduction to the pre-processing operations and advanced methods of identifying retinal vessels is deliberated. In addition, a discussion on the validation stage and assessment of the outcomes of retinal vessels segmentation is presented. In this paper, the proposed methods of classifying arteries and veins in fundus images are extensively reviewed, which are categorized into automatic and semi-automatic categories. There are some challenges associated with the classification of vessels in images of the retinal fundus, which include the low contrast accompanying the fundus image and the inhomogeneity of the background lighting. The inhomogeneity occurs as a result of the process of imaging, whereas the low contrast which accompanies the image is caused by the variation between the background and the contrast of the various blood vessels. This means that the contrast of thicker vessels is higher than those that are thinner. Another challenge is related to the color changes that occur in the retina from different subjects, which are rooted in biological features. Most of the techniques used for the classification of the retinal vessels are based on geometric and visual characteristics that set the veins apart from the arteries. In this study, different major contributions are summarized as review studies that adopted deep learning approaches and machine learning techniques to address each of the limitations and problems in retinal blood vessel segmentation and classification techniques. We also review the current challenges, knowledge gaps and open issues, limitations and problems in retinal blood vessel segmentation and classification techniques.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Abd Ghani MK et al (2018) Decision-level fusion scheme for nasopharyngeal carcinoma identification using machine learning techniques. Neural Comput Appl 32(3):625–638
Abdallah MB, Malek J, Krissian K and Tourki R (2011) An automated vessel segmentation of retinal images using multiscale vesselness. . In eighth international multi-conference on systems, signals and devices IEEE (1–6)
Abdulhay E et al (2018) Computer aided solution for automatic segmenting and measurements of blood leucocytes using static microscope images. J Med Syst 42(4):58
Adel M, Rasigni M, Gaidon T, Fossati C and Bourennane S (2009) Statistical-based linear vessel structure detection in medical images. In 2009 16th IEEE international conference on image processing (ICIP) (649–652)
Akhavan RAFK (2014) A novel retinal blood vessel segmentation algorithm using fuzzy segmentation. Int J Elect Comp Eng 4(4):561
Akram MU, Tariq A and Khan SA (2009) Retinal image blood vessel segmentation. In 2009 international conference on information and communication technologies IEEE (181–192)
Al-Dhief FT, Latiff NMA, Malik NNNA, Sabri N, Baki MM, Albadr MAA, Abbas AF, Hussein YM, Mohammed MA (2020) Voice pathology detection using machine learning technique. In: 2020 IEEE 5th international symposium on telecommunication technologies (ISTT). IEEE, pp 99–104
Al-Fahdawi S et al (2016) A fully automatic nerve segmentation and morphometric parameter quantification system for early diagnosis of diabetic neuropathy in corneal images. Comput Methods Programs Biomed 135:151–166
Al-Fahdawi S et al (2018) A fully automated cell segmentation and morphometric parameter system for quantifying corneal endothelial cell morphology. Comput Methods Programs Biomed 160:11–23
Al-Rawi M, Qutaishat M, Arrar M (2007) An improved matched filter for blood vessel detection of digital retinal images. Comput Biol Med 37(2):262–267
Aparna CLSP, Rajan J (2017) Recent advancements in retinal vessel segmentation. J Med Syst 41(4):70
Arunkumar N et al (2018) K-Means clustering and neural network for object detecting and identifying abnormality of brain tumor. Soft Comput 23(19):9083–9096
Arunkumar N et al (2018) Fully automatic model-based segmentation and classification approach for MRI brain tumor using artificial neural networks. Concurr Comput Pract Exp 32:1
Azuaje F, Witten IH, Frank E (2006) Data mining: practical machine learning tools and techniques 2nd edition. BioMed Eng OnLine 5:51. https://doi.org/10.1186/1475-925X-5-51
Babaud J, Witkin AP, Baudin M, Duda RO (1986) Uniqueness of the Gaussian kernel for scale-space filtering. IEEE Trans Pattern Anal Mach Intell 1:26–33
Bankhead P et al (2012) Fast retinal vessel detection and measurement using wavelets and edge location refinement. PLoS ONE 7(3):e32435
Binh NT, Tuyet VTH, Hien NM, Thuy NT (2019) Retinal vessels segmentation by improving salient region combined with Sobel operator condition. In: International conference on future data and security engineering. Springer, Cham, pp 608–617
Brancati N, Frucci M, Gragnaniello D, Riccio D (2018) Retinal vessels segmentation based on a convolutional neural network. In: Iberoamerican congress on pattern recognition. Springer, Cham, pp 119–126
Budai A, Michelson G and Hornegger J (2010) Multiscale blood vessel segmentation in retinal fundus images. In Bildverarbeitung für die Medizin 2010 - Algorithmen, Systeme, Anwendungen, pp 261–265
Cao L, Li H, Zhang Y (2020) Retinal image enhancement using low-pass filtering and α-rooting. Signal Processing 170:107445
Chanwimaluang TAF (2003) G, <an-efficient-algorithm-for-extraction-of-anatomical-structures-i.pdf>. IEEE. (In proceedings 2003 international conference on image processing): (Cat. No. 03CH37429. (1, I-1093)
Chapman N, Dell’Omo G, Sartini MS, Witt N, Hughes A, Thom S, Pedrinelli R (2002) Peripheral vascular disease is associated with abnormal arteriolar diameter relationships at bifurcations in the human retina. Clin Sci 103(2):111–116
Chaudhuri S, Chatterjee S, Katz N, Nelson M, Goldbaum M (1989) Detection of blood vessels in retinal images using two-dimensional matched filters. IEEE Trans Med Imaging 8(3):263–269
Christodoulidis A et al (2016) A multi-scale tensor voting approach for small retinal vessel segmentation in high resolution fundus images. Comput Med Imaging Graph 52:28–43
Chutatape O, Zheng L and Krishnan SM (1998) Retinal blood vessel detection and tracking by matched Gaussian and Kalman filters. . In proceedings of the 20th annual international conference of the IEEE engineering in medicine and biology society, biomedical engineering towards the year 2000 and Beyond (Cat. No. 98CH36286) (6 3144–3149)
Couper DJ, Klein R, Hubbard LD, Wong TY, Sorlie PD, Cooper LS, Brothers RJ, Nieto FJ (2002) Reliability of retinal photography in the assessment of retinal microvascular characteristics: the atherosclerosis risk in communities study. Am J Ophthalmol 133(1):78–88
da Rocha DA et al (2020) An unsupervised approach to improve contrast and segmentation of blood vessels in retinal images using CLAHE, 2D Gabor wavelet, and morphological operations. Res Biomed Eng 36(1):67–75
Dan Y et al (2021) Retinal blood vessel segmentation method based on multi scale convolution kernel U net model. J Northeast Univ (Nat Sci) 42:1
Dasgupta AASS (2017) A fully convolutional neural network based structured prediction approach towards the retinal vessel segmentation. In 2017 IEEE 14th international symposium on biomedical imaging (ISBI 2017), (248–251)
Dashtbozorg B, Mendonça AM, Campilho A (2013) An automatic graph-based approach for artery/vein classification in retinal images. IEEE Trans Image Process 23(3):1073–1083
De J, Cheng L, Zhang X, Lin F, Li H, Ong KH, Yu W, Yu Y, Ahmed S (2015) A graph-theoretical approach for tracing filamentary structures in neuronal and retinal images. IEEE Trans Med Imaging 35(1):257–272
Decencière E et al (2014) Feedback on a publicly distributed image database: the messidor database. Image Anal Stereol 33(3):231
De Silva A, Perera MV, Wijethilake N, Jayasinghe S, Nanayakkara ND, De Silva A (2021) A thickness sensitive vessel extraction framework for retinal and conjunctival vascular tortuosity analysis. arXiv preprint arXiv:2101.00435
Dharmawan DA et al (2019) A new hybrid algorithm for retinal vessels segmentation on fundus images. IEEE Access 7:41885–41896
Diabetes Control and Complications Trial Research Group (1987) Color photography vs. fluorescein angiography in the detection of diabetic retinopathy in the Diabetes Control and Complications Trial. Arch Ophthalmol 105:1344–1351
Dizdaro B, Ataer-Cansizoglu E, Kalpathy-Cramer J, Keck K, Chiang MF and Erdogmus D (2012) Level sets for retinal vasculature segmentation using seeds from ridges and edges from phase maps. In 2012 IEEE international workshop on machine learning for signal processing. IEEE (1–6)
Efron B (1983) Estimating the error rate of a prediction rule: improvement on cross-validation. J Am Stat Assoc 78(382):316–331
Elhoseny M, Mohammed MA, Mostafa SA, Abdulkareem KH, Maashi MS et al (2021) A new multi-agent feature wrapper machine learning approach for heart disease diagnosis. Comput Mater Contin 67(1):51–71
Emary E, Zawbaa HM, Hassanien AE, Schaefer G and Azar AT (2014) Retinal vessel segmentation based on possibilistic fuzzy c-means clustering optimised with cuckoo search. In 2014 international joint conference on neural networks (IJCNN) IEEE (1792–1796)
Estrada R, Tomasi C, Schmidler SC, Farsiu S (2014) Tree topology estimation. IEEE Trans Pattern Anal Mach Intell 37(8):1688–1701
Estrada R et al (2015) Retinal Artery-Vein Classification via Topology Estimation. IEEE Trans Med Imaging 34(12):2518–2534
Foracchia M, Grisan E, Ruggeri A (2005) Luminosity and contrast normalization in retinal images. Med Image Anal 9(3):179–190
Forouhi NG et al (2012) Circulating 25-hydroxyvitamin D concentration and the risk of type 2 diabetes: results from the European Prospective Investigation into Cancer (EPIC)-Norfolk cohort and updated meta-analysis of prospective studies. Diabetologia 55(8):2173–2182
Francia GA, Pedraza C, Aceves M, Tovar-Arriaga S (2020) Chaining a U-net with a residual U-net for retinal blood vessels segmentation. IEEE Access 8:38493–38500
Frangi AF, Niessen WJ, Vincken KL, Viergever MA (1998) Multiscale vessel enhancement filtering. In International conference on medical image computing and computer-assisted intervention. Springer 1998:130–137
Fraz MM et al (2012) Blood vessel segmentation methodologies in retinal images–a survey. Comput Methods Programs Biomed 108(1):407–433
Fraz MM, Remagnino P, Hoppe A, Uyyanonvara B, Rudnicka AR, Owen CG, Barman SA (2012) An ensemble classification-based approach applied to retinal blood vessel segmentation. IEEE Trans Biomed Eng 59(9):2538–2548
Fraz MM, Rudnicka AR, Owen CG, Strachan DP and Barman SA (2014) Automated arteriole and venule recognition in retinal images using ensemble classification. International conference on computer vision theory and applications (VISAPP). IEEE (3: 194–202): 194–202
Frucci M, Riccio D, Di Baja GS, Serino L (2014) Using contrast and directional information for retinal vessels segmentation. In: 2014 tenth international conference on signal-image technology and internet-based systems. IEEE, pp 592–597
Fu H, Xu,Y, Lin S, Wong DWK, Liu J (2016) Retinal vessel segmentation via deep learning network and fully-connected conditional random fields. In: International conference on medical image computing and computer-assisted intervention. Springer, Cham, pp 132–139
Gao X, Cai Y, Qiu C and Cui Y (2017) Retinal blood vessel segmentation based on the Gaussian matched filter and U-net. In 2017 10th international congress on image and signal processing, Biomedical engineering and informatics (CISP-BMEI) IEEE (1–5)
Gongt H, Li Y, Liu G, Wu W and Chen G (2015) A level set method for retina image vessel segmentation based on the local cluster value via bias correction. In 2015 8th international congress on image and signal processing (CISP) IEEE (413–417)
Grisan EARA (2003) A divide et impera strategy for automatic classification of retinal vessels into arteries and veins. In Proceedings of the 25th annual international conference of the IEEE engineering in medicine and biology society (IEEE Cat. No. 03CH37439). (1: 890–893). IEEE
Gu L (2015) and L. Learning to boost filamentary structure segmentation, Cheng, pp 639–647
Guo Y et al (2017) A retinal vessel detection approach based on shearlet transform and Indeterminacy Filtering on Fundus Images. Symmetry 9(10):235
Guo Y et al (2018) A retinal vessel detection approach using convolution neural network with reinforcement sample learning strategy. Measurement 125:586–591
Hajabdollahi M, Esfandiarpoor R, Najarian K, Karimi N, Samavi S and Reza-Soroushmeh SM (2018) Low complexity convolutional neural network for vessel segmentation in portable retinal diagnostic devices. In 2018 25th IEEE international conference on image processing (ICIP). (2785–2789)
Hall MA (1999) Correlation-based feature selection for machine learning, Doctor of Philosophy at The University of Waikato, Hamilton, New Zealand
Hamad H et al (2020) Exudates as Landmarks Identified through FCM Clustering in Retinal Images. Appl Sci 11(1):142
Hatami NAGM (2016) Automatic identification of retinal arteries and veins in fundus images using local binary patterns. arXiv preprint arXiv: 1605.00763
Hatamizadeh A, Hosseini H, Liu Z, Schwartz SD and Terzopoulos D (2019) Deep dilated convolutional nets for the automatic segmentation of retinal vessels. . arXiv preprint arXiv:, 1905.12120
Heslinga Pluim FG, Houben JPAJHM, Schram MT, Henry RM, Stehouwer CD, Van Greevenbroek MJ, Veta BTTM (2020) Direct classification of type 2 diabetes from retinal fundus images in a population-based sample from The Maastricht Study In Medical Imaging 2020: computer-Aided Diagnosis. Int Soc Opt Photon 11314:113141N
Hoover AD, Kouznetsova V, Goldbaum M (2000) Locating blood vessels in retinal images by piecewise threshold probing of a matched filter response. IEEE Trans Med Imaging 19(3):203–210
Hu K et al (2018) Retinal vessel segmentation of color fundus images using multiscale convolutional neural network with an improved cross-entropy loss function. Neurocomputing 309:179–191
Huang J-H, Huck Yang C-H, Liu F, Tian M, Liu Y-C, Wu T-W, Lin I (2021) DeepOpht: medical report generation for retinal images via deep models and visual explanation. In: Proceedings of the IEEE/CVF winter conference on applications of computer vision, pp 2442–2452
Isavand Rahmani A, Akbari H, Esmaili S (2020) Retinal blood vessel segmentation using gabor filter and morphological reconstruction. Sign Process Renew Energy 4(1):77–88
Jebaseeli TJ, Durai CAD, Peter JD (2019) Extraction of retinal blood vessels on fundus images by kirsch’s template and Fuzzy C-Means. J Med Phys 44(1):21
Jelinek HF, Depardieu C, Lucas C, Cornforth DJ, Huang W, Cree MJ (2005) Towards vessel characterization in the vicinity of the optic disc in digital retinal images. Image Vis Comput Conf 2:7
Jena R, Singla S, Batmanghelich K (2021) Self-supervised vessel enhancement using flow-based consistencies. arXiv preprint arXiv:2101.05145.
Jiang XAMD (2003) Adaptive local thresholding by verification-based multithreshold probing with application to vessel detection in retinal images. IEEE Transactions Patt Anal Mach Intell 25(1):131–137
Jiang Z et al (2017) Fast, accurate and robust retinal vessel segmentation system. Biocybern Biomed Eng 37(3):412–421
Jiang Y, Tan N, Peng T, Zhang H (2019) Retinal vessels segmentation based on dilated multi-scale convolutional neural network. IEEE Access 7:76342–76352
Jiang Y et al (2020) A multi-scale residual attention network for retinal vessel segmentation. Symmetry 13(1):24
Jin Q et al (2019) DUNet: a deformable network for retinal vessel segmentation. Knowl-Based Syst 178:149–162
Joshi VS, Reinhardt JM, Garvin MK, Abramoff MD (2014) Automated method for identification and artery-venous classification of vessel trees in retinal vessel networks. PLoS ONE 9:2
Kamran SA, Hossain KF, Tavakkoli A (2021) RV-GAN: retinal vessel segmentation from fundus images using multi-scale generative adversarial networks. arXiv: 2101.00535v1
Karssemeijer N et al (2010) Automated detection and classification of major retinal vessels for determination of diameter ratio of arteries and veins 7624:76240J
Kauppi T, Kalesnykiene V, Kamarainen J-K, Lensu L, Sorri I, Raninen A, Voutilainen R, Uusitalo H, Kälviäinen H, Pietilä J (2007) The diaretdb1 diabetic retinopathy database and evaluation protocol. In: BMVC, vol 1, pp 1–10
Khaing TT et al (2021) Glaucoma detection in mobile phone retinalimages based on adi-gvf segmentation withem initialization. ECTI Transactions on Computer Inform Technol 15:1
Khowaja SA, Khuwaja P, Ismaili IA (2018) A framework for retinal vessel segmentation from fundus images using hybrid feature set and hierarchical classification. SIViP 13(2):379–387
Kingsbury N (1998) The dual-tree complex wavelet transform: a new efficient tool for image restoration and enhancement. In 9th European signal processing conference (EUSIPCO 1998) (1–4). IEEE
Kirbas CAQF (2004) A review of vessel extraction techniques and algorithms. ACM Comput Surv (CSUR) 36(2):81–121
Kondermann C, Kondermann D, Yan M (2007) Blood vessel classification into arteries and veins in retinal images. In: Medical imaging 2007: image processing, vol 6512. International Society for Optics and Photonics, p 651247
Krinidis SACV (2010) A robust fuzzy local information C-means clustering algorithm. IEEE Transactions Image Process 19(5):1328–1337
Kumar D, Pramanik A, Kar SS and Maity SP (2016) Retinal blood vessel segmentation using matched filter and laplacian of gaussian. In 2016 international conference on signal processing and communications (SPCOM) IEEE June. (1–5)
Kundu AACRK (2012) Retinal vessel segmentation using morphological angular scale-space. In 2012 third international conference on emerging applications of information technology. IEEE (316–319)
Lahiri A, Roy AG, Sheet D and Biswas PK (2016) Deep neural ensemble for retinal vessel segmentation in fundus images towards achieving label-free angiography. In 2016 38th annual international conference of the IEEE engineering in medicine and biology society (EMBC) (1340–1343)
Lenskiy AA, Lee J (2010) Rugged terrain segmentation based on salient features. ICCAS 2010, Gyeonggi-do, Korea (South), pp 1737–1740. https://doi.org/10.1109/ICCAS.2010.5669787
Lesage D et al (2009) A review of 3D vessel lumen segmentation techniques: models, features and extraction schemes. Med Image Anal 13(6):819–845
Li H, Hsu W, Lee ML and Wang H (2003) A piecewise Gaussian model for profiling and differentiating retinal vessels. In Proceedings 2003 international conference on image processing (Cat. No. 03CH37429). IEEE (1: I-1069)
Li H, Hsu W, Lee ML, Wong TY (2005) Automatic grading of retinal vessel caliber. IEEE Trans Biomed Eng 52(7):1352–1355
Li H, Zhang J, Nie Q and Cheng L (2013) A retinal vessel tracking method based on bayesian theory. In 2013 IEEE 8th conference on industrial electronics and applications (ICIEA) (232–235)
Liantoni F et al (2021) Gradient based ant spread modification on ant colony optimization method for retinal blood vessel edge detection. IOP Conf Ser Mater Sci Eng 1010:012021
Lindeberg T (2011) Scale-space theory: a basic tool for analyzing structures at different scales. J Appl Stat 21(1–2):225–270
Liskowski PAKK (2016) Segmenting retinal blood vessels with deep neural networks. IEEE Transactions Med Imaging 35(11):2369–2380 (9901)
Lv Y, Ma H, Li J, Liu S (2020) Attention guided U-net with atrous convolution for accurate retinal vessels segmentation. IEEE Access 8:32826–32839
Ma ZALH (2015) Retinal vessel profiling based on four piecewise Gaussian model. IEEE international conference on digital signal processing DSP 1094–1097
Maji D, Santara A, Ghosh S, Sheet D and Mitra P (2015) Deep neural network and random forest hybrid architecture for learning to detect retinal vessels in fundus images. In 2015 37th annual international conference of the IEEE engineering in medicine and biology society (EMBC) (3029–3032)
Maji D, Santara A, Mitra P and Sheet D (2016) Ensemble of deep convolutional neural networks for learning to detect retinal vessels in fundus images. arXiv preprint arXiv:, 2016. 1603.04833
Martinez-Perez ME, Highes AD, Stanton AV, Thorn SA, Chapman N, Bharath AA, Parker KH (2002) Retinal vascular tree morphology: a semi-automatic quantification. IEEE Trans Biomed Eng 49(8):912–917
McInerney T, Terzopoulos D (1996) Deformable models in medical image analysis: a survey. Med Image Anal 1(2):91–108
Mirsharif Q, Tajeripour F, Pourreza H (2013) Automated characterization of blood vessels as arteries and veins in retinal images. Comput Med Imaging Graph 37(7–8):607–617
Moghimirad E, Rezatofighi SH and Soltanian-Zadeh H (2010) Multi-scale approach for retinal vessel segmentation using medialness function. In 2010 IEEE international symposium on biomedical imaging: from nano to macro (29–32)
Mohammed MA et al (2017a) Analysis of an electronic methods for nasopharyngeal carcinoma: prevalence, diagnosis, challenges and technologies. J Comput Sci 21:241–254
Mohammed MA et al (2017b) Artificial neural networks for automatic segmentation and identification of nasopharyngeal carcinoma. J Comput Sci 21:263–274
Mohammed MA et al (2018) A real time computer aided object detection of nasopharyngeal carcinoma using genetic algorithm and artificial neural network based on Haar feature fear. Futur Gener Comput Syst 89:539–547
Mostafa SA et al (2019) Examining multiple feature evaluation and classification methods for improving the diagnosis of Parkinson’s disease. Cogn Syst Res 54:90–99
Mou L et al (2021) CS(2)-Net: deep learning segmentation of curvilinear structures in medical imaging. Med Image Anal 67:101874
Muramatsu C, Hatanaka Y, Iwase T, Hara T, Fujita H (2010) Automated detection and classification of major retinal vessels for determination of diameter ratio of arteries and veins. In: Medical imaging 2010: computer-aided diagnosis, vol 7624. International Society for Optics and Photonics, p 76240J
Narasimha-Iyer H, Beach JM, Khoobehi B, Roysam B (2007) Automatic identification of retinal arteries and veins from dual-wavelength images using structural and functional features. IEEE Trans Biomed Eng 54(8):1427–1435
Naveed K et al (2021) Towards automated eye diagnosis: an improved retinal vessel segmentation framework using ensemble block matching 3D filter. Diagnostics (Basel) 11:1
Nayak J et al (2008) Automated identification of diabetic retinopathy stages using digital fundus images. J Med Syst 32(2):107–115
Nekovei RASY (1995) Back-propagation network and its configuration for blood vessel detection in angiograms. IEEE Transactions Neural Netw 6(1):64–72
Niemeijer M, Xu X, Dumitrescu AV, Gupta P, Van Ginneken B, Folk JC, Abramoff MD (2011) Automated measurement of the arteriolar-to-venular width ratio in digital color fundus photographs. IEEE Trans Med Imaging 30(11):1941–1950
Obaid OI, Mohammed MA, Ghani MKA, Mostafa A, Taha F (2018) Evaluating the performance of machine learning techniques in the classification of Wisconsin breast cancer. Int J Eng Technol 7(4.36):160–166
Odstrcilik J et al (2013) Retinal vessel segmentation by improved matched filtering: evaluation on a new high-resolution fundus image database. IET Image Proc 7(4):373–383
Patton N et al (2006) Retinal image analysis: concepts, applications and potential. Am J Ophthalmol 141(3):603
Poplin R et al (2018) Prediction of cardiovascular risk factors from retinal fundus photographs via deep learning. Nat Biomed Eng 2(3):158–164
Qureshi TA, Habib M, Hunter A and Al-Diri B (2013) A manually-labeled, artery/vein classified benchmark for the DRIVE dataset. In proceedings of the 26th IEEE international symposium on computer-based medical systems (485–488)
Rattathanapad S, Mittrapiyanuruk P, Kaewtrakulpong P, Uyyanonvara B and Sinthanayothin C (2012) Vessel extraction in retinal images using multilevel line detection. . In proceedings of 2012 IEEE-EMBS international conference on biomedical and health informatics (345–349)
Relan D, Ballerini L, Trucco E, MacGillivray T (2016) Retinal vessel classification based on maximization of squared-loss mutual information. In: Machine intelligence and signal processing. Springer, New Delhi, pp 77–84
Relan D, Relan R (2020) Unsupervised sorting of retinal vessels using locally consistent Gaussian mixtures. Comput Methods Programs Biomed 199:105894
Relan D, MacGillivray T, Ballerini L and Trucco E (2013) Retinal vessel classification: sorting arteries and veins. In 2013 35th annual international conference of the IEEE engineering in medicine and biology society (EMBC) (7396–7399)
Relan D, MacGillivray T, Ballerini L and 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 (142–145)
Rothaus K, Jiang X (2011) Classification of arteries and veins in retinal images using vessel profile features. In: AIP conference proceedings, vol 1371, no 1. American Institute of Physics, pp 9–18
Rothaus K, Rhiem P and Jiang X (2007) Separation of the retinal vascular graph in arteries and veins. In International Workshop on Graph-Based Representations in Pattern Recognition. Springer, Berlin, Heidelberg 251–262
Rothaus K, Jiang X, Rhiem P (2009) Separation of the retinal vascular graph in arteries and veins based upon structural knowledge. Image Vis Comput 27(7):864–875
Roy AGASD (2015) Dasa: domain adaptation in stacked autoencoders using systematic dropout. In 2015 3rd IAPR Asian conference on pattern recognition (ACPR). IEEE (735–739)
Ruggeri A, Grisan E and De Luca M (2007) An automatic system for the estimation of generalized arteriolar narrowing in retinal images. In 2007 29th annual international conference of the IEEE engineering in medicine and biology society (6463–6466). IEEE
Saha Tchinda B et al (2021) Retinal blood vessels segmentation using classical edge detection filters and the neural network. Inform Med Unlock 23:100521
Salem SAS, NMAK Nandi (2006) Segmentation of retinal blood vessels using a novel clustering algorithm. In proceedings of the 2006 14th European signal processing conference, Florence, Italy, 1–5
Sarah Husham AM, Mostafa SA, Al-Obaidi MK, Mohammed MA (2020) comparative analysis between active contour and otsuthresholding segmentation algorithms in segmenting braintumor magnetic resonance imaging. J Inform Technol Manag. https://doi.org/10.22059/jitm.2020.78889
Saroj SK, Kumar R, Singh NP (2020) Frechet PDF based matched filter approach for retinal blood vessels segmentation. Comput Methods Programs Biomed 194:105490
Sharma SAWEV (2015) Retinal blood vessel segmentation using fuzzy logic. J Netw Commun Emerg Technol 4:3
Singh NP, Srivastava R (2016) Retinal blood vessels segmentation by using Gumbel probability distribution function based matched filter. Comput Methods Programs Biomed 129:40–50
Singh NP, Kumar R and Srivastava R (2015) Local entropy thresholding based fast retinal vessels segmentation by modifying matched filter. In international conference on computing, communication and automation IEEE (1166–1170)
Sofka MASCV (2006) Retinal vessel centerline extraction using multiscale matched filters, confidence and edge measures. IEEE Transactions Med Imaging 25(12):1531–1546
Soomro TA et al (2018) Impact of ICA-based image enhancement technique on retinal blood vessels segmentation. IEEE Access 6:3524–3538
Soomro TA et al (2019) Strided fully convolutional neural network for boosting the sensitivity of retinal blood vessels segmentation. Expert Syst Appl 134:36–52
Staal J, Abràmoff MD, Niemeijer M, Viergever MA, Van Ginneken B (2004) Ridge-based vessel segmentation in color images of the retina. IEEE Trans Med Imaging 23(4):501–509
Subathra MSP, Mohammed MA, Maashi MS, Garcia-Zapirain B, Sairamya NJ, George ST (2020) Detection of focal and non-focal electroencephalogram signals using fast Walsh-Hadamard transform and artificial neural network. Sensors 20(17):4952
Tankyevych O, Talbot H, Dokladal P (2008) Curvilinear morpho-Hessian filter. IEEE Int Symp Biomed Imaging 2008:1011–1014
Tianyu Ma HZ (2021) Hanley Ong. Ensembling Low Precision Models for Binary Biomedical Image Segmentation, IEEE Access
Tramontan L, Grisan E and Ruggeri A (2008) An improved system for the automatic estimation of the Arteriolar-to-Venular diameter Ratio (AVR) in retinal images. In 2008 30th annual international conference of the IEEE engineering in medicine and biology society (3550–3553). IEEE
Usman A, Muhammad A, Martinez-Enriquez AM, Muhammad A (2020) Classification of diabetic retinopathy and retinal vein occlusion in human eye fundus images by transfer learning. In: Future of information and communication conference. Springer, Cham, pp 642–653
Vázquez SG et al (2012) Improving retinal artery and vein classification by means of a minimal path approach. Mach Vis Appl 24(5):919–930
Villalobos-Castaldi FM, Felipe-Riverón EM, Sánchez-Fernández LP (2010) A fast, efficient and automated method to extract vessels from fundus images. J Visual 13(3):263–270
Walter T, Klein JC, Massin P, Erginay A (2002) A contribution of image processing to the diagnosis of diabetic retinopathy-detection of exudates in color fundus images of the human retina. IEEE Trans Med Imaging 21(10):1236–1243
Weiss K, Khoshgoftaar TM, Wang D (2016) A survey of transfer learning. J Big Data 3:1
Wu Y, Xia Y, Song Y, Zhang Y, Cai W (2018) Multiscale network followed network model for retinal vessel segmentation. In: International conference on medical image computing and computer-assisted intervention. Springer, Cham, pp 119–126
Wu CH, Agam G and Stanchev P (2007) A general framework for vessel segmentation in retinal images. In 2007 international symposium on computational intelligence in robotics and automation. IEEE (37–42)
Wu Y et al (2020) NFN: a novel network followed network for retinal vessel segmentation. Neural Netw 126:153–162
Wang W, Wu X, Yuan X, Gao Z (2020) An experiment-based review of low-light image enhancement methods. IEEE Access 8:87884–87917
Xie S (2013) and H. Retinal Vascular Image Segmentation Using Genetic Algorithm Plus FCM Clustering, Nie, pp 1225–1228
Xiuqin P, Zhang Q, Zhang H, Li S (2019) A fundus retinal vessels segmentation scheme based on the improved deep learning U-Net model. IEEE Access 7:122634–122643
Yang Y, Huang S, Rao N (2008) An automatic hybrid method for retinal blood vessel extraction. Int J Appl Math Comput Sci 18(3):399–407
Yedidya T (2008) and R. Tracking of Blood Vessels in Retinal Images Using Kalman Filter, Hartley, pp 52–58
Yin Y, Adel M, Guillaume M and Bourennane S (2010) A probabilistic based method for tracking vessels in retinal images. In 2010 IEEE international conference on image processing (4081–4084)
Zahra Amini HR (2016) Classification of medical image modeling methods: a review. IEEE 12(2):130–148
Zamperini A, Giachetti A, Trucco E and Chin KS (2012) Effective features for artery-vein classification in digital fundus images. In 2012 25th IEEE international symposium on computer-based medical systems (CBMS) (1–6)
Zhang Y, CACS (2018) Deep supervision with additional labels for retinal vessel segmentation task. In: Frangi A, Schnabel J, Davatzikos C, Alberola-López C, Fichtinger G (eds) Medical image computing and computer assisted intervention: MICCAI 2018. MICCAI 2018. Lecture Notes in computer science Springer, Cham vol 11071.
Zhang Z, Yin FS, Liu J, Wong WK, Tan NM, Lee BH, Cheng J and Wong TY (2010) Origa-light: an online retinal fundus image database for glaucoma analysis and research. In 2010 annual international conference of the IEEE engineering in medicine and biology (3065–3068). IEEE
Zhang B et al (2010) Retinal vessel extraction by matched filter with first-order derivative of Gaussian. Comput Biol Med 40(4):438–445
Zhang J, Tang Z, Gui W and Liu J (2015) Retinal vessel image segmentation based on correlational open active contours model. . In 2015 Chinese automation congress (CAC). IEEE (993–998)
Zhao Y et al (2015) Automated vessel segmentation using infinite perimeter active contour model with hybrid region information with application to retinal images. IEEE Trans Med Imaging 34(9):1797–1807
Zhou C, Zhang X, Chen H (2020) A new robust method for blood vessel segmentation in retinal fundus images based on weighted line detector and hidden Markov model. Comput Methods Programs Biomed 187:105231
Zhu T (2010) Fourier cross-sectional profile for vessel detection on retinal images. Comput Med Imaging Graph 34(3):203–212
Zhu TASG (2011) Retinal vessel extraction using a piecewise Gaussian scaled model. In 2011 annual international conference of the IEEE engineering in medicine and biology society, 2011, August. (pp. 5008–5011)
Zhu C et al (2017) Retinal vessel segmentation in colour fundus images using extreme learning machine. Comput Med Imaging Graph 55:68–77
Zolfagharnasab HANNAR (2014) Cauchy based matched filter for retinal vessels detection. J Med Sign Sens 4(1):1
Zou B et al (2020) Multi-label classification scheme based on local regression for retinal vessel segmentation. In: IEEE/ACM transactions on computational biology and bioinformatics. https://doi.org/10.1109/TCBB.2020.2980233
Funding
This study was not funded.
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Conflict of interest
There is no conflict of interests.
Ethical approval
This article does not contain any studies with human participants or animals performed by any of the authors.
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
About this article
Cite this article
Abdulsahib, A.A., Mahmoud, M.A., Mohammed, M.A. et al. Comprehensive review of retinal blood vessel segmentation and classification techniques: intelligent solutions for green computing in medical images, current challenges, open issues, and knowledge gaps in fundus medical images. Netw Model Anal Health Inform Bioinforma 10, 20 (2021). https://doi.org/10.1007/s13721-021-00294-7
Received:
Revised:
Accepted:
Published:
DOI: https://doi.org/10.1007/s13721-021-00294-7