Abstract

PurposeWe recently described the validation of deep learning-based auto-segmented contour (DC) models for organs at risk (OAR) and clinical target volumes (CTV). In this study, we evaluate the performance of implemented DC models in the clinical radiotherapy (RT) planning workflow and report on user experience.Methods and materialsDC models were implemented at two cancer centers and used to generate OAR and CTVs for all patients undergoing RT for a central nervous system (CNS), head and neck (H&N), or prostate cancer. Radiation Therapists/Dosimetrists and Radiation Oncologists completed post-contouring surveys rating the degree of edits required for DCs (1 = minimal, 5 = significant) and overall DC satisfaction (1 = poor, 5 = high). Unedited DCs were compared to the edited treatment approved contours using Dice similarity coefficient (DSC) and 95% Hausdorff distance (HD).ResultsBetween September 19, 2019 and March 6, 2020, DCs were generated on approximately 551 eligible cases. 203 surveys were collected on 27 CNS, 54 H&N, and 93 prostate RT plans, resulting in an overall survey compliance rate of 32%. The majority of OAR DCs required minimal edits subjectively (mean editing score ≤ 2) and objectively (mean DSC and 95% HD was ≥ 0.90 and ≤ 2.0 mm). Mean OAR satisfaction score was 4.1 for CNS, 4.4 for H&N, and 4.6 for prostate structures. Overall CTV satisfaction score (n = 25), which encompassed the prostate, seminal vesicles, and neck lymph node volumes, was 4.1.ConclusionsPreviously validated OAR DC models for CNS, H&N, and prostate RT planning required minimal subjective and objective edits and resulted in a positive user experience, although low survey compliance was a concern. CTV DC model evaluation was even more limited, but high user satisfaction suggests that they may have served as appropriate starting points for patient specific edits.

Highlights

  • Manual contouring of organs at risk (OAR) and clinical target volumes (CTV) is an essential task in radiotherapy (RT) planning

  • Between September 19, 2019 and March 6, 2020, deep-learning based auto-segmented contours (DC) were generated on approximately 551 eligible cases. 203 surveys were collected on 27 central nervous system (CNS), 54 head and neck (H&N), and 93 prostate RT plans, resulting in an overall survey compliance rate of 32%

  • CTV DC model evaluation was even more limited, but high user satisfaction suggests that they may have served as appropriate starting points for patient specific edits

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Summary

Introduction

Manual contouring of organs at risk (OAR) and clinical target volumes (CTV) is an essential task in radiotherapy (RT) planning. This process can be time consuming, depends on staff availability, and is a large contributor to RT treatment planning lead time. Deep learning-based auto-segmentation is not yet widely used in clinical practice [3]. In our previous report [4], we compared deep-learning based auto-segmented contours (DC) with multiple expert Radiation Oncologist contours for central nervous system (CNS), head and neck (H&N), and prostate OARs and CTVs and observed close similarity between the two contour sets. Considering the results of our previous study, these autosegmentation models were approved at our institutions for implementation and testing in the clinical workflow with the intention of facilitating current manual contouring processes

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