[1] Marin D, Aquino A, Gegunde-Zarias M E, et al. A new super-vised method for blood vessel segmentation in retinal images by using gray-level and moment invariants-based features[J]. IEEE Transactions on Medical Imaging, 2011, 30(1): 146–158.

[2] Zhao Y Q, Wang X H, Wang X F, et al. Retinal vessels seg-mentation based on level set and region growing[J]. Pattern Recognition, 2014, 47(7): 2437–2446.

[4] Chaudhuri S, Chatterjee S, Katz N, et al. Detection of blood vessels in retinal images using two-dimensional matched fil-ters[J]. IEEE Transactions on Medical Imaging, 1989, 8(3): 263–269.

[5] Jiang X Y, Mojon D. Adaptive local thresholding by verifica-tion-based multithreshold probing with application to vessel detection in retinal images[J]. IEEE Transactions on Pattern Analysis and Machine Intelligence, 2003, 25(1): 131–137.

[6] Gang L, Chutatape O, Krishnan S M. Detection and measure-ment of retinal vessels in fundus images using amplitude mod-ified second-order Gaussian filter[J]. IEEE Transactions on Biomedical Engineering, 2002, 49(2): 168–172.

[7] Zhang B, Zhang L, Zhang L, et al. Retinal vessel extraction by matched filter with first-order derivative of Gaussian[J]. Com-puters in Biology and Medicine, 2010, 40(4): 438–445.

[8] Soares J V B, Leandro J J G, Cesar R M, et al. Retinal vessel segmentation using the 2-D Gabor wavelet and supervised classification[J]. IEEE Transactions on Medical Imaging, 2006, 25(9): 1214–1222.

[9] Gwetu M V, Tapamo J R, Viriri S. Segmentation of retinal blood vessels using normalized Gabor filters and automatic thre-sholding[J]. South African Computer Journal, 2014, 55(1): 12–24.

[10] Zhang L, Fisher M, Wang W J. Retinal vessel segmentation using multi-scale textons derived from keypoints[J]. Compute-rized Medical Imaging and Graphics, 2015, 45: 47–56.

[11] Zou P, Chan P, Rockett P. A model-based consecutive scanline tracking method for extracting vascular networks from 2-D dig-ital subtraction angiograms[J]. IEEE Transactions on Medical Imaging, 2009, 28(2): 241–249.

[12] Vlachos M, Dermatas E. Multi-scale retinal vessel segmenta-tion using line tracking[J]. Computerized Medical Imaging and Graphics, 2010, 34(3): 213–227.

[13] Zana F, Klein J C. Segmentation of vessel-like patterns using mathematical morphology and curvature evaluation[J]. IEEE Transactions on Image Process, 2001, 10(7): 1010–1019.

[14] Espona L, Carreira M J, Penedo M G, et al. Retinal vessel tree segmentation using a deformable contour mod-el[C]//Proceedings of the 19th International Conference on Pattern Recognition, 2008: 1–4.

[18] Jiang W, Zhou H Y, Shen Y, et al. Image segmentation with pulse-coupled neural network and Canny operators[J]. Com-puters & Electrical Engineering, 2015, 46: 528–538.

[19] Lu Y F, Miao J, Duan L J, et al. A new approach to image segmentation based on simplified region growing PCNN[J]. Applied Mathematics and Computation, 2008, 205(2): 807–814.

[21] Oloumi F, Rangayyan R M, Oloumi F, et al. Digital image processing and pattern recognition techniques for the analysis of fundus images of the retina[R]. Alberta, Canada: Department of Electrical and Computer Engineering, University of Calgary, 2010: 8.

[22] Reza A M. Realization of the contrast limited adaptive histo-gram equalization (CLAHE) for real-time image enhance-ment[J]. Journal of VLSI Signal Processing Systems for Signal, Image and Video Technology, 2004, 38(1): 35–44.

[23] Gwetu M V, Tapamo J R, Viriri S. Segmentation of retinal blood vessels using normalized Gabor filters and automatic thre-sholding[J]. South African Computer Journal, 2014, 53(55): 12–24.

[28] Stewart R D, Fermin I, Opper M. Region growing with pulse-coupled neural networks: an alternative to seeded region growing[J]. IEEE Transactions on Neural Networks, 2002, 13(6): 1557–1562.