Moradi, N., Ferreira, A., Puladi, B., Kleesiek, J., Fatehzadeh, E., Luijten, G., ... & Egger, J. (2024). Comparative Analysis of nnUNet and MedNeXt for Head and Neck Tumor Segmentation in MRI-guided Radiotherapy. arXiv preprint arXiv:2411.14752.
This research paper presents the TUMOR team's approach to the HNTS-MRG24 MICCAI Challenge, which focused on the automated segmentation of primary gross tumor volumes (GTVp) and metastatic lymph node gross tumor volume (GTVn) in pre-radiotherapy (pre-RT) and mid-radiotherapy (mid-RT) MRI images. The study aimed to evaluate and compare the performance of two state-of-the-art deep learning models, nnUNet and MedNeXt, for this challenging task.
The researchers utilized the HNTS-MRG24 dataset, comprising 150 MRI scans from HNC patients, including pre-RT and mid-RT T2-weighted images with corresponding segmentation masks. They explored various configurations of nnUNet (3D Full Resolution U-Net, 3D U-Net Cascade, 3D FullRes U-Net with Large Residual Encoder Presets) and MedNeXt (small and large models with 3x3x3 and 5x5x5 kernel sizes). The models were trained and evaluated on two tasks: segmenting tumors in pre-RT images (Task 1) and mid-RT images (Task 2). The team employed a multi-level ensemble strategy to combine predictions from different models and configurations. Additionally, they investigated the impact of pretraining with the BraTS24 Meningioma Radiotherapy Dataset. Model performance was evaluated using the Aggregated Dice Similarity Coefficient (DSCagg) and mean Dice Similarity Coefficient (DSC) for each label (GTVp, GTVn).
The study highlights the potential of deep learning models, specifically nnUNet and MedNeXt, for automating and improving the segmentation of head and neck tumors in MRI. The authors conclude that incorporating prior time point data, such as registered pre-RT segmentation masks, can significantly enhance the accuracy of mid-RT tumor segmentation.
This research contributes to the growing body of work on applying deep learning to medical image analysis, particularly in the context of radiotherapy planning for head and neck cancer. The findings have implications for improving the precision and efficiency of tumor delineation, potentially leading to better treatment outcomes for patients.
The study faced challenges with the stability of MedNeXt during training for Task 2, limiting the exploration of its full potential. Future research could investigate methods to address these stability issues and further optimize model architectures and training strategies. Additionally, exploring other external datasets and domain adaptation techniques could further enhance model performance.
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