作者
Junqiang Ma,Luyi Han,Henry H. Y. Tong,Dengqiang Jia,Hui Xie,Anne W. M. Lee,Hing Ming Hung,Tao Tan,Sung Inda Soong,Yue Sun
摘要
Accurate and simultaneous labeling of multiple structures, including gross tumor volumes, clinical target volumes, and organs at risk, is a fundamental multi-task requirement for radiotherapy planning in nasopharyngeal carcinoma. However, conventional manual labeling is labor-intensive and suffers from substantial inter-observer variability. This variability poses a significant challenge to the multi-modal interpretation of CT and MRI scans. Against this backdrop, automated approaches, particularly multi-modal and multi-task learning, are promising solutions. However, their clinical adoption is limited by three urgent needs: attention mechanisms that fuse multi-modal information at both local and global views, explicit incorporation of anatomical priors to regularize predictions, and a unified framework that enables concurrent segmentation of all desired structures. To overcome these limitations, we propose M $^{3}$ SegNet, a novel multi-modal and multi-branch framework that concurrently performs all clinically relevant segmentation tasks, integrating feature fusion and anatomical guidance. Our primary contributions are threefold. First, we introduce the Synergistic Global-Local Attention that extracts informative features from various imaging modalities (CT, T1-weighted, T2-weighted, and T1 contrast). Second, we propose an Anatomy-Aware Hierarchical Learning strategy that uses OAR spatial information to guide tumor segmentation. We also integrate Random Modality Dropout to enhance robustness against missing modalities. We validated M $^{3}$ SegNet on an internal 257-patient NPC dataset and confirmed its generalizability on three external datasets. In experiments, our framework significantly outperformed state-of-the-art methods. By providing a mechanism to leverage multi-modal information and anatomical priors, our M $^{3}$ SegNet offers a reliable, automated, and clinically translatable solution for NPC radiotherapy planning.