Related papers: Patient-Specific Finetuning of Deep Learning Models for Adaptive Radiotherapy in Prostate CT

Patient-Specific Finetuning of Deep Learning Models for Adaptive Radiotherapy in Prostate CT

URL: http://arxiv.org/abs/2002.06927v1
Date: Mon, 17 Feb 2020 12:53:37 GMT
Title: Patient-Specific Finetuning of Deep Learning Models for Adaptive Radiotherapy in Prostate CT
Authors: Mohamed S. Elmahdy, Tanuj Ahuja, U. A. van der Heide, and Marius Staring
Abstract summary: Contouring of the target volume and Organs-At-Risk (OARs) is a crucial step in radiotherapy treatment planning. In this work, we leverage personalized anatomical knowledge accumulated over the treatment sessions, to improve the segmentation accuracy of a pre-trained Convolution Neural Network (CNN) We investigate a transfer learning approach, fine-tuning the baseline CNN model to a specific patient, based on imaging acquired in earlier treatment fractions.
Score: 1.3124513975412255
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Contouring of the target volume and Organs-At-Risk (OARs) is a crucial step in radiotherapy treatment planning. In an adaptive radiotherapy setting, updated contours need to be generated based on daily imaging. In this work, we leverage personalized anatomical knowledge accumulated over the treatment sessions, to improve the segmentation accuracy of a pre-trained Convolution Neural Network (CNN), for a specific patient. We investigate a transfer learning approach, fine-tuning the baseline CNN model to a specific patient, based on imaging acquired in earlier treatment fractions. The baseline CNN model is trained on a prostate CT dataset from one hospital of 379 patients. This model is then fine-tuned and tested on an independent dataset of another hospital of 18 patients, each having 7 to 10 daily CT scans. For the prostate, seminal vesicles, bladder and rectum, the model fine-tuned on each specific patient achieved a Mean Surface Distance (MSD) of $1.64 \pm 0.43$ mm, $2.38 \pm 2.76$ mm, $2.30 \pm 0.96$ mm, and $1.24 \pm 0.89$ mm, respectively, which was significantly better than the baseline model. The proposed personalized model adaptation is therefore very promising for clinical implementation in the context of adaptive radiotherapy of prostate cancer.

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