1454                                     Journal of Software  软件学报 Vol.32, No.5,  May 2021

                 [73]    Jia YQ, Shelhamer E, Donahue J, Karayev S, Long J, Girshick R, Guadarrama S, Darrell T. Caffe: Convolutional architecture for
                      fast feature embedding. In: Proc. of the ACM Int’l Conf. on Multimedia. 2014. 675−678.
                 [74]    Bastien F, Lamblin P, Pascanu R, Bergstra J, Goodfellow I, Bergeron A, Bouchard N, Bengio Y. Theano: New features and speed
                      improvements. arXiv preprint arXiv:1211.5590, 2012.
                 [75]    Song  YY,  Zhang L, Chen  SP, Ni D, Lei BY, Wang TF. Accurate  segmentation  of cervical cytoplasm and  nuclei  based  on
                      multiscale convolutional network and graph partitioning. IEEE Trans. on Biomedical Engineering, 2015,62(10):2421−2433.
                 [76]    Xie YP, Xing  FY, Kong XF,  Su H, Yang L. Beyond  classification:  Structured  regression  for  robust cell detection  using
                      convolutional neural network. In: Proc. of the Int’l Conf. on Medical Image Computing and Computer Assisted Intervention. 2015.
                      358−365.
                 [77]    Albarqouni S, Baur C, Achilles F, Belagiannis V, Demirci S, Navab N. AggNet: Deep learning from crowds for mitosis detection
                      in breast cancer histology images. IEEE Trans. on Medical Imaging, 2016,35(5):1313−1321.
                 [78]    Chen H, Wang X, Heng PA. Automated mitosis detection with deep regression networks. In: Proc. of the IEEE Int’l Symp. on
                      Biomedical Imaging. 2016. 1204−1207.
                 [79]    Sirinukunwattana K, Raza SEA, Tsang YW, Snead DRJ, Cree IA, Rajpoot NM. Locality sensitive deep learning for detection and
                      classification of nuclei in routine colon cancer histology images. IEEE Trans. on Medical Imaging, 2016,35(5):1196−1206.
                 [80]    Xing FY, Xie YP, Yang L. An automatic learning-based framework for robust nucleus segmentation. IEEE Trans. on Medical
                      Imaging, 2016,35(2):550−566.
                 [81]    Xu J, Xiang L, Liu QS, Gilmore H, Wu JZ, Tang JH, Madabhushi A. Stacked sparse autoencoder (SSAE) for nuclei detection on
                      breast cancer histopathology images. IEEE Trans. on Medical Imaging, 2016,35(1):119−130.
                 [82]    Yang  L,  Zhang YZ,  Guldner IH,  Zhang SY, Chen  DZ. 3D segmentation  of glial  cells using fully  convolutional networks and
                      k-terminal cut. In: Proc. of the Int’l Conf. on Medical Image Computing and Computer Assisted Intervention. 2016. 658−666.
                 [83]    BenTaieb A, Kawahara J, Hamarneh G. Multi-loss convolutional networks for gland analysis in microscopy. In: Proc. of the IEEE
                      Int’l Symp. on Biomedical Imaging. 2016. 642−645.
                 [84]    Chen  JX, Yang L, Zhang YZ, Alber  M, Chen DZ. Combining  fully convolutional and  recurrent  neural networks  for  3D
                      biomedical image segmentation. In: Proc. of the Conf. on Neural Information Processing Systems. 2016. 3036−3044.
                 [85]    Xie YP, Zhang ZZ, Sapkota M, Yang L. Spatial clockwork recurrent neural network for muscle perimysium segmentation. In:
                      Proc. of the Int’l Conf. on Medical Image Computing and Computer Assisted Intervention. 2016. 185−193.
                 [86]    Xie YP, Kong XF, Xing FY, Liu FJ, Su H, Yang L. Deep voting: A robust approach toward nucleus localization in microscopy
                      images. In: Proc. of the Int’l Conf. on Medical Image Computing and Computer Assisted Intervention. 2015. 374−382.
                 [87]    Fakhry  A, Peng  HC, Ji S. Deep  models for brain  EM image segmentation: Novel  insights  and improved performance.
                      Bioinformtics, 2016,32(15):2352−2358.
                 [88]    Stollenga MF, Byeon W, Liwicki M,  Schmidhuber  J.  Parallel multi-dimensional  LSTM,  with application to  fast  biomedical
                      volumetric image segmentation. In: Proc. of the Conf. on Neural Information Processing Systems. 2015. 2998−3006.
                 [89]    Xu Y, Li Y, Liu MY, Wang YP, Lai MD, Chang EIC. Gland instance segmentation by deep multichannel side supervision. In:
                      Proc. of the Int’l Conf. on Medical Image Computing and Computer Assisted Intervention. 2016. 496−504.
                 [90]    Chen H, Qi XJ, Cheng JZ, Heng PA. Deep contextual networks for neuronal structure segmentation. In: Proc. of the AAAI Conf.
                      on Artificial Intelligence. 2016. 1167−1173.
                 [91]    Chen H, Qi XJ, Yu LQ, Dou Q, Qin J, Heng PA. DCAN: Deep contour-aware networks for object instance segmentation from
                      histology images. Medical Image Analysis, 2017,36:135−146.
                 [92]    Song YY, Tan EL, Jiang XD, Cheng JZ, Ni D, Chen SP, Lei BY, Wang TF. Accurate cervical cell segmentation from overlapping
                      clumps in PAP smear images. IEEE Trans. on Medical Imaging, 2017,36(1):288−300.
                 [93]    Fakhry A, Zeng T, Ji SW. Residual deconvolutional networks for brain electron microscopy image segmentation. IEEE Trans. on
                      Medical Imaging, 2017,36(2):447−456.
                 [94]    Li YX, Shen LL, Yu SQ. HEp-2 specimen image segmentation and classification using very deep fully convolutional network.
                      IEEE Trans. on Medical Imaging, 2017,36(7):1561−1572.
                 [95]    Li RJ, Zeng T, Peng HC, Ji SW. Deep learning segmentation of optical microscopy images improves 3-D neuron reconstruction.
                      IEEE Trans. on Medical Imaging, 2017,36(7):1533−1541.