AI Article Synopsis
- The study assessed the accuracy of different segmentation methods in adaptive radiotherapy for head-and-neck cancer, specifically focusing on atlas-based auto-segmentation (ABAS), deformable image registration (DIR), and deep learning auto-segmentation (DLAS).
- Seventeen patients were examined, using various datasets for the segmentation methods, including an atlas of 30 patients for ABAS and a training set of 143 for DLAS.
- Results showed that DIR provided the highest accuracy in delineating organs at risk, while mABAS slightly outperformed standard ABAS; no significant accuracy differences were found between ABAS and DLAS, indicating DIR as the best method overall.
Article Abstract
Aims: This study aimed to evaluate the geometrical accuracy of atlas-based auto-segmentation (ABAS), deformable image registration (DIR), and deep learning auto-segmentation (DLAS) in adaptive radiotherapy (ART) for head-and-neck cancer (HNC).
Subjects And Methods: Seventeen patients who underwent replanning for ART were retrospectively studied, and delineated contours on their replanning computed tomography (CT2) images were delineated. For DIR, the planning CT image (CT1) of the evaluated patients was utilized. In contrast, ABAS was performed using an atlas dataset comprising 30 patients who were not part of the evaluated group. DLAS was trained with 143 patients from different patients from the evaluated patients. The ABAS model was improved, and a modified ABAS (mABAS) was created by adding the evaluated patients' own CT1 to the atlas datasets of ABAS (number of patients of the atlas dataset, 31). The geometrical accuracy of DIR, DLAS, ABAS, and mABAS was evaluated.
Results: The Dice similarity coefficient in DIR was the highest, at >0.8 at all organs at risk. The mABAS was delineated slightly more accurately than the standard ABAS. There was no significant difference between ABAS and DLAS in delineation accuracy. DIR had the lowest Hausdorff distance (HD) value (within 10 mm). The HD values in ABAS, mABAS, and DLAS were within 16 mm.
Conclusions: DIR delineation is the most geometrically accurate ART for HNC.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11548068 | PMC |
| http://dx.doi.org/10.4103/jmp.jmp_39_24 | DOI Listing |
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