The paper presents a novel distance-aware conditional diffusion model, named DoseDiff, for precise prediction of dose distribution in radiotherapy. The key highlights are:
DoseDiff defines dose prediction as a sequence of denoising steps, where the predicted dose distribution map is generated with the conditions of the computed tomography (CT) image and signed distance maps (SDMs). The SDMs provide the distance from each pixel in the image to the outline of the targets or organs-at-risk (OARs).
A multi-encoder and multi-scale fusion network (MMFNet) is proposed to enhance information fusion between the CT image and SDMs at the feature level, enabling effective extraction and integration of local and global features.
Extensive experiments on two in-house datasets (breast cancer and nasopharyngeal cancer) and a public dataset demonstrate that DoseDiff outperforms state-of-the-art dose prediction methods in terms of both quantitative performance and visual quality.
Ablation studies validate the contributions of the proposed components, including the PSDM (physical signed distance map), multi-scale fusion, and transformer-based fusion module. The results show that incorporating distance information and enhancing the fusion strategy can significantly improve the accuracy of dose distribution prediction.
Compared to previous methods, DoseDiff can better capture the characteristics of radiation paths in the predicted dose distribution maps, providing valuable information for medical physicists to optimize radiotherapy planning.
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