A Multi-Organ Nucleus Segmentation Challenge

Neeraj Kumar(University of Illinois Chicago), Ruchika Verma(Case Western Reserve University), Deepak Anand(Indian Institute of Technology Bombay), Yanning Zhou(Chinese University of Hong Kong), Omer Fahri Onder, Efstratios Tsougenis, Hao Chen, Pheng‐Ann Heng(Chinese University of Hong Kong), Jiahui Li(Beijing University of Posts and Telecommunications), Zhiqiang Hu(Peking University), Yunzhi Wang(Tongji University), Navid Alemi Koohbanani(University of Warwick), Mostafa Jahanifar(University of Warwick), Neda Zamani Tajeddin(University of Warwick), Ali Gooya(University of Warwick), Nasir Rajpoot(University of Warwick), Xuhua Ren(Shanghai Jiao Tong University), Sihang Zhou(University of North Carolina at Chapel Hill), Qian Wang(Shanghai Jiao Tong University), Dinggang Shen(University of North Carolina at Chapel Hill), Cheng-Kun Yang, Chi-Hung Weng, Wei-Hsiang Yu, Chao‐Yuan Yeh, Shuang Yang(Zhejiang University), Shuoyu Xu(Sun Yat-sen University), Pak Hei Yeung(Chinese University of Hong Kong), Peng Sun(Sun Yat-sen University), Amirreza Mahbod(Medical University of Vienna), Gerald Schaefer(Loughborough University), Isabella Ellinger(Medical University of Vienna), Rupert Ecker, Örjan Smedby(KTH Royal Institute of Technology), Chunliang Wang(KTH Royal Institute of Technology), Benjamin Chidester(Carnegie Mellon University), That-Vinh Ton(University of Illinois Urbana-Champaign), Minh–Triet Tran(Vietnam National University Ho Chi Minh City), Jian Ma(Nanjing University of Science and Technology), N. Minh(University of Illinois Urbana-Champaign), Simon Graham(University of Warwick), Quoc Dang Vu(Sejong University), Jin Tae Kwak(Sejong University), Akshaykumar Gunda(Indian Institute of Technology Madras), Raviteja Chunduri(Indian Institute of Technology Bombay), Corey Hu(University of California, Berkeley), Xiaoyang Zhou(Hong Kong University of Science and Technology), Dariush Lotfi(Qazvin Islamic Azad University), Reza Safdari(Qazvin Islamic Azad University), Antanas Kascenas(Canon (Japan)), Alison O’Neil(Canon (Japan)), Dennis Eschweiler(RWTH Aachen University), Johannes Stegmaier(RWTH Aachen University), Yanping Cui(University of Science and Technology of China), Baocai Yin, Kailin Chen, Xinmei Tian(University of Science and Technology of China), Philipp Gruening(University of Lübeck), Erhardt Barth(University of Lübeck), Elad Arbel, Itay Remer, Amir Ben‐Dor, Ekaterina Sirazitdinova, Matthias Kohl, Stefan Braunewell, Yuexiang Li(Shenzhen University), Xinpeng Xie(Shenzhen University), Linlin Shen(Shenzhen University), Jun Ma(Nanjing University of Science and Technology), Krishanu Das Baksi(Tata Consultancy Services (India)), Mohammad Azam Khan(Korea University), Jaegul Choo(Korea University), Adrián Colomer(Universitat Politècnica de València), Valery Naranjo(Universitat Politècnica de València), Linmin Pei(Old Dominion University), Khan M. Iftekharuddin(Old Dominion University), Kaushiki Roy(Jadavpur University), Debotosh Bhattacharjee(Jadavpur University), Aníbal Pedraza(University of Castilla-La Mancha), Maria Gloria Bueno(University of Castilla-La Mancha), Sabarinathan Devanathan(Cognizant (India)), Saravanan Radhakrishnan(Cognizant (India)), Praveen Koduganty(Cognizant (India)), Zihan Wu(Xiamen University), Guanyu Cai(Tongji University), Xiaojie Liu(Tongji University), Yuqin Wang(Tongji University), Amit Sethi(Indian Institute of Technology Bombay)
IEEE Transactions on Medical Imaging
October 23, 2019
10.1109/tmi.2019.2947628
Cited by 535Open Access
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Abstract

Generalized nucleus segmentation techniques can contribute greatly to reducing the time to develop and validate visual biomarkers for new digital pathology datasets. We summarize the results of MoNuSeg 2018 Challenge whose objective was to develop generalizable nuclei segmentation techniques in digital pathology. The challenge was an official satellite event of the MICCAI 2018 conference in which 32 teams with more than 80 participants from geographically diverse institutes participated. Contestants were given a training set with 30 images from seven organs with annotations of 21,623 individual nuclei. A test dataset with 14 images taken from seven organs, including two organs that did not appear in the training set was released without annotations. Entries were evaluated based on average aggregated Jaccard index (AJI) on the test set to prioritize accurate instance segmentation as opposed to mere semantic segmentation. More than half the teams that completed the challenge outperformed a previous baseline. Among the trends observed that contributed to increased accuracy were the use of color normalization as well as heavy data augmentation. Additionally, fully convolutional networks inspired by variants of U-Net, FCN, and Mask-RCNN were popularly used, typically based on ResNet or VGG base architectures. Watershed segmentation on predicted semantic segmentation maps was a popular post-processing strategy. Several of the top techniques compared favorably to an individual human annotator and can be used with confidence for nuclear morphometrics.

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