BACKGROUND: Online adaptive radiotherapy using cone beam computed tomography (CBCT) of the pelvis can account for anatomical variations during cervical cancer treatment. However, the limitations of CBCT and existing auto-segmentation methods, such as deformable image registration (DIR), hinder contouring and dosimetric accuracy. PURPOSE: We propose a test-time adaptation (TTA)-driven patient-specific segmentation framework to enhance the accuracy and workflow efficiency of CBCT-guided online adaptive radiotherapy in cervical cancer. METHODS: Our retrospective analysis included 20 patients with cervical/endometrial cancer (530 CBCT scans) treated on the Varian Ethos platform. A patient-specific UNet variant pre-trained on the CTPelvic1K dataset using Bootstrap Your Own Latent (BYOL) contrastive learning was fine-tuned on individual reference CT scans. During daily adaptation, the model incorporated TTA with segmentation (cross entropy + Dice loss) and consistency objectives, leveraging prior CBCT/CT images to constrain anatomical variations. Performance was evaluated using the Dice similarity coefficient (DSC), 95th percentile Hausdorff Distance (HD95), and contouring time reduction compared to DIR-based methods. RESULTS: The proposed method significantly outperformed DIR, achieving higher DSC (e.g., postoperative clinical target volume (CTV) of the vaginal cuff and upper vaginal region: 0.89 vs. 0.73; definitive CTV of the pelvic lymphatic drainage area: 0.83 vs. 0.71) and lower HD95 (e.g., rectum: 24.9 vs. 30.7 mm) values. TTA further improved the accuracy, particularly for the bowel (DSC: 0.81 vs. 0.76) and target volumes. Clinically, the proposed method reduced the contouring time by 250 s (postoperative) and 230 s (definitive) per fraction (p < 0.01), with reduced time variability. Structures with clear boundaries required one or two fractions for training, whereas motion-prone organs required four or five fractions. CONCLUSIONS: This study presents the first retrospective demonstration of TTA-driven patient-specific segmentation for pelvic CBCT-guided online adaptive radiotherapy. The proposed framework enhances segmentation accuracy, workflow efficiency, and temporal consistency by addressing the inherent challenges and data scarcity of CBCT through adaptive learning.
Wang et al. (Fri,) studied this question.