宋杰  等:基于深度学习的数字病理图像分割综述与展望                                                      1459


                 [183]    Liang XD, Hu ZT, Zhang H, Lin L, Xing EP. Symbolic graph reasoning meets convolutions. In: Proc. of the Conf. on Neural
                      Information Processing Systems. 2018. 1853−1863.
                 [184]    Li QL, Feng BW, Xie LP, Liang P, Zhang HS, Wang TF. A cross-modality learning approach for vessel segmentation in retinal
                      images. IEEE Trans. on Medical Imaging. 2016,35(1):109−118.
                 [185]    Fu HZ, Xu  YW,  Wong  DWK,  Liu  J. Retinal vessel segmentation via deep learning network  and  fully-connected  conditional
                      random fields. In: Proc. of the IEEE Int’l Symp. on Biomedical Imaging. 2016. 698−701.
                 [186]    Liskowski P, Krawiec K. Segmenting retinal blood vessels with deep neural networks. IEEE Trans. on Medical Imaging. 2016,35:
                      2369−2380.
                 [187]    Orlando JI, Prokofyeva E, Blaschko MB. A discriminatively trained fully connected conditional random field model for blood
                      vessel segmentation in fundus images. IEEE Trans. on Biomedical Engineering, 2016,64:16−27.
                 [188]    Dasgupta  A, Singh S.  A fully  convolutional neural network based structured prediction  approach  towards  the retinal vessel
                      segmentation. In: Proc. of the IEEE Int’l Symp. on Biomedical Imaging. 2017. 248−251.
                 [189]    Srinidhi CL, Aparna P, Rajan J. A visual attention guided unsupervised feature learning for robust vessel delineation in retinal
                      images. Biomedical Signal Processing and Control, 2018,44:110−126.
                 [190]    Alom  MZ,  Hasan M, Yakopcic  C, Taha  TM,  Asari VK.  Recurrent residual  convolutional neural network based on  U-Net
                      (R2U-Net) for medical image segmentation. arXiv preprint arXiv:1802.06955, 2018.
                 [191]    Wu YC, Xia Y, Song Y, Zhang YN, Cai WD. Multiscale network followed network model for retinal vessel segmentation. In:
                      Proc. of the Int’l Conf. on Medical Image Computing and Computer Assisted Intervention. 2018. 119−126.
                 [192]    Soomro TA, Afifi  AJ, Gao JB, Hellwich O, Zheng LH,  Paul M.  Strided  fully convolutional  neural  network  for  boosting  the
                      sensitivity of retinal blood vessels segmentation. Expert Systems with Applications, 2019,134:36−52.
                 [193]    Adeyinka AA, Adebiyi MO, Akande NO, Ogundokun  RO, Kayode AA, Oladele TO. A  deep convolutional encoder-decoder
                      architecture for retinal blood vessels segmentation. In: Proc. of the Int’l Conf. on Computational Science and Its Applications.
                      2019. 180−189.
                 [194]    Wu  YC, Xia Y,  Song Y,  Zhang DH, Liu DN, Zhang CY, Cai  WD.  Vessel-Net: Retinal  vessel segmentation under multi-path
                      supervision. In: Proc. of the Int’l Conf. on Medical Image Computing and Computer Assisted Intervention. 2019. 264−272.
                 [195]    Guo S, Wang K, Kang H, Zhang YJ, Gao YQ, Li T. BTS-DSN: Deeply supervised neural network with short connections for
                      retinal vessel segmentation. Int’l Journal of Medical Informatics, 2019,126:105−113.
                 [196]    Ma  WN, Yu  S,  Ma K,  Wang JX, Ding XH, Zheng YF. Multi-task  neural  networks with spatial activation  for  retinal  vessel
                      segmentation  and  artery/vein  classification. In: Proc. of the Int’l Conf. on Medical Image  Computing  and  Computer  Assisted
                      Intervention. 2019. 769−778.
                 [197]    Wang  B,  Qiu S,  He HG, Dual  encoding  U-Net for retinal vessel segmentation. In: Proc. of the Int’l Conf. on Medical Image
                      Computing and Computer Assisted Intervention. 2019. 84−92.
                 [198]    Wang  DY,  Haytham  A, Pottenburgh J, Saeedi  O,  Tao Y. Hard  attention net for  automatic retinal vessel segmentation. IEEE
                      Journal of Biomedical and Health Informatics, 2020,24(12):3384−3396. [doi: 10.1109/JBHI.2020.3002985]
                 [199]    Rodrigues EO, Conci A, Liatsis P. ELEMENT: Multi-modal retinal vessel segmentation based on a coupled region growing and
                      machine learning  approach. IEEE Journal of  Biomedical  and  Health Informatics, 2020,24(12):3507−3519. [doi: 10.1109/JBHI.
                      2020.2999257]
                 [200]    Wu YC, Xia Y, Song Y, Zhang YN, Cai WD. NFN+: A novel network followed network for retinal vessel segmentation. Neural
                      Networks, 2020,126:153−162.
                 [201]    Zeiler MD, Fergus R. Visualizing and understanding convolutional networks. In: Proc. of the European Conf. on Computer Vision.
                      2014. 818−833.
                 [202]    Samek W, Binder A, Montavon G, Lapuschkin S, Müller KR. Evaluating the visualization of what a deep neural network has
                      learned. IEEE Trans. on Neural Networks and Learning Systems, 2017,28(11):2660−2673.
                 [203]    Hou BJ, Zhou ZH. Learning with interpretable structure from gated RNN. IEEE Trans. on Neural Networks and Learning Systems,
                      2020,31(7):2267−2279.