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Deep learning empowered volume delineation of whole-body organs-at-risk for accelerated radiotherapy

Author

Listed:
  • Feng Shi

    (Shanghai United Imaging Intelligence Co., Ltd.)

  • Weigang Hu

    (Fudan University Shanghai Cancer Center
    Fudan University)

  • Jiaojiao Wu

    (Shanghai United Imaging Intelligence Co., Ltd.)

  • Miaofei Han

    (Shanghai United Imaging Intelligence Co., Ltd.)

  • Jiazhou Wang

    (Fudan University Shanghai Cancer Center
    Fudan University)

  • Wei Zhang

    (Shanghai United Imaging Healthcare Co., Ltd.)

  • Qing Zhou

    (Shanghai United Imaging Intelligence Co., Ltd.)

  • Jingjie Zhou

    (Shanghai United Imaging Healthcare Co., Ltd.)

  • Ying Wei

    (Shanghai United Imaging Intelligence Co., Ltd.)

  • Ying Shao

    (Shanghai United Imaging Intelligence Co., Ltd.)

  • Yanbo Chen

    (Shanghai United Imaging Intelligence Co., Ltd.)

  • Yue Yu

    (Shanghai United Imaging Intelligence Co., Ltd.)

  • Xiaohuan Cao

    (Shanghai United Imaging Intelligence Co., Ltd.)

  • Yiqiang Zhan

    (Shanghai United Imaging Intelligence Co., Ltd.)

  • Xiang Sean Zhou

    (Shanghai United Imaging Intelligence Co., Ltd.)

  • Yaozong Gao

    (Shanghai United Imaging Intelligence Co., Ltd.)

  • Dinggang Shen

    (Shanghai United Imaging Intelligence Co., Ltd.
    ShanghaiTech University
    Shanghai Clinical Research and Trial Center)

Abstract

In radiotherapy for cancer patients, an indispensable process is to delineate organs-at-risk (OARs) and tumors. However, it is the most time-consuming step as manual delineation is always required from radiation oncologists. Herein, we propose a lightweight deep learning framework for radiotherapy treatment planning (RTP), named RTP-Net, to promote an automatic, rapid, and precise initialization of whole-body OARs and tumors. Briefly, the framework implements a cascade coarse-to-fine segmentation, with adaptive module for both small and large organs, and attention mechanisms for organs and boundaries. Our experiments show three merits: 1) Extensively evaluates on 67 delineation tasks on a large-scale dataset of 28,581 cases; 2) Demonstrates comparable or superior accuracy with an average Dice of 0.95; 3) Achieves near real-time delineation in most tasks with

Suggested Citation

  • Feng Shi & Weigang Hu & Jiaojiao Wu & Miaofei Han & Jiazhou Wang & Wei Zhang & Qing Zhou & Jingjie Zhou & Ying Wei & Ying Shao & Yanbo Chen & Yue Yu & Xiaohuan Cao & Yiqiang Zhan & Xiang Sean Zhou & Y, 2022. "Deep learning empowered volume delineation of whole-body organs-at-risk for accelerated radiotherapy," Nature Communications, Nature, vol. 13(1), pages 1-13, December.
    • Handle: RePEc:nat:natcom:v:13:y:2022:i:1:d:10.1038_s41467-022-34257-x
    DOI: 10.1038/s41467-022-34257-x
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    References listed on IDEAS

    as
    1. Stephen P. Jackson & Jiri Bartek, 2009. "The DNA-damage response in human biology and disease," Nature, Nature, vol. 461(7267), pages 1071-1078, October.
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