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Paper detail

Enhancing Organ at Risk Segmentation with Improved Deep Neural Networks

Organ at risk (OAR) segmentation is a crucial step for treatment planning and outcome determination in radiotherapy treatments of cancer patients. Several deep learning based segmentation algorithms have been developed in recent years, however, U-Net remains the de facto algorithm designed specifically for biomedical image segmentation and has spawned many variants with known weaknesses. In this study, our goal is to present simple architectural changes in U-Net to improve its accuracy and generalization properties. Unlike many other available studies evaluating their algorithms on single center data, we thoroughly evaluate several variations of U-Net as well as our proposed enhanced architecture on multiple data sets for an extensive and reliable study of the OAR segmentation problem. Our enhanced segmentation model includes (a)architectural changes in the loss function, (b)optimization framework, and (c)convolution type. Testing on three publicly available multi-object segmentation data sets, we achieved an average of 80% dice score compared to the baseline U-Net performance of 63%.

preprint2022arXivOpen access
Ilkin IslerCurtis LisleJustin RineerPatrick KellyDamla TurgutJacob RicciUlas Bagci
eess.IVComputer Vision
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Ilkin IslerCurtis LisleJustin RineerPatrick KellyDamla TurgutJacob RicciUlas Bagci

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