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Automatic segmentation of high‐risk clinical target volume for tandem‐and‐ovoids brachytherapy patients using an asymmetric dual‐path convolutional neural network

Yufeng Cao, April Vassantachart, Omar Ragab, Shelly X. Bian, Priya Mitra, Zhengzheng Xu, Audrey Zhuang Gallogly, Jing Cui, Zhilei Liu Shen, Salim Balik, Michael Gribble, Eric L. Chang, Zhaoyang Fan, Wensha Yang

2022Medical Physics22 citationsDOIOpen Access PDF

Abstract

Abstract Purposes Preimplant diagnostic magnetic resonance imaging is the gold standard for image‐guided tandem‐and‐ovoids (T&O) brachytherapy for cervical cancer. However, high dose rate brachytherapy planning is typically done on postimplant CT‐based high‐risk clinical target volume (HR‐CTV CT ) because the transfer of preimplant Magnetic resonance (MR)‐based HR‐CTV (HR‐CTV MR ) to the postimplant planning CT is difficult due to anatomical changes caused by applicator insertion, vaginal packing, and the filling status of the bladder and rectum. This study aims to train a dual‐path convolutional neural network (CNN) for automatic segmentation of HR‐CTV CT on postimplant planning CT with guidance from preimplant diagnostic MR. Methods Preimplant T2‐weighted MR and postimplant CT images for 65 (48 for training, eight for validation, and nine for testing) patients were retrospectively solicited from our institutional database. MR was aligned to the corresponding CT using rigid registration. HR‐CTV CT and HR‐CTV MR were manually contoured on CT and MR by an experienced radiation oncologist. All images were then resampled to a spatial resolution of 0.5 × 0.5 × 1.25 mm. A dual‐path 3D asymmetric CNN architecture with two encoding paths was built to extract CT and MR image features. The MR was masked by HR‐CTV MR contour while the entire CT volume was included. The network put an asymmetric weighting of 18:6 for CT: MR. Voxel‐based dice similarity coefficient (DSC V ), sensitivity, precision, and 95% Hausdorff distance (95‐HD) were used to evaluate model performance. Cross‐validation was performed to assess model stability. The study cohort was divided into a small tumor group (<20 cc), medium tumor group (20–40 cc), and large tumor group (>40 cc) based on the HR‐CTV CT for model evaluation. Single‐path CNN models were trained with the same parameters as those in dual‐path models. Results For this patient cohort, the dual‐path CNN model improved each of our objective findings, including DSC V , sensitivity, and precision, with an average improvement of 8%, 7%, and 12%, respectively. The 95‐HD was improved by an average of 1.65 mm compared to the single‐path model with only CT images as input. In addition, the area under the curve for different networks was 0.86 (dual‐path with CT and MR) and 0.80 (single‐path with CT), respectively. The dual‐path CNN model with asymmetric weighting achieved the best performance with DSC V of 0.65 ± 0.03 (0.61–0.70), 0.79 ± 0.02 (0.74–0.85), and 0.75 ± 0.04 (0.68–0.79) for small, medium, and large group. 95‐HD were 7.34 (5.35–10.45) mm, 5.48 (3.21–8.43) mm, and 6.21 (5.34–9.32) mm for the three size groups, respectively. Conclusions An asymmetric CNN model with two encoding paths from preimplant MR (masked by HR‐CTV MR ) and postimplant CT images was successfully developed for automatic segmentation of HR‐CTV CT for T&O brachytherapy patients.

Topics & Concepts

BrachytherapyConvolutional neural networkPath (computing)Computer scienceTandemRadiation therapyNuclear medicineMedicineArtificial intelligenceRadiologyComputer networkComposite materialMaterials scienceRadiomics and Machine Learning in Medical ImagingAdvanced Radiotherapy TechniquesMedical Imaging and Analysis