Deep Learning-Based Dose Prediction for Automated, Individualized   Quality Assurance of Head and Neck Radiation Therapy Plans

Mary P. Gronberg (1; 2); Beth M. Beadle (3); Adam S. Garden (4),; Heath Skinner (5); Skylar Gay (1; 2); Tucker Netherton (1; 2); Wenhua; Cao (1); Carlos E. Cardenas (6); Christine Chung (1); David Fuentes (2 and; 7); Clifton D. Fuller (2; 4); Rebecca M. Howell (1; 2); Anuja Jhingran; (4); Tze Yee Lim (1; 2); Barbara Marquez (1; 2); Raymond Mumme (1),; Adenike M. Olanrewaju (1); Christine B. Peterson (2; 8); Ivan Vazquez (1),; Thomas J. Whitaker (1; 2); Zachary Wooten (8; 9); Ming Yang (1; 2),; Laurence E. Court (1; 2) ((1) Department of Radiation Physics; The; University of Texas MD Anderson Cancer Center; (2) The University of Texas MD; Anderson Cancer Center UTHealth Houston Graduate School of Biomedical; Sciences; (3) Department of Radiation Oncology; Stanford University; (4); Department of Radiation Oncology; The University of Texas MD Anderson Cancer; Center; (5) Department of Radiation Oncology; University of Pittsburgh; (6); Department of Radiation Oncology; The University of Alabama at Birmingham,; (7) Department of Imaging Physics; The University of Texas MD Anderson Cancer; Center; (8) Department of Biostatistics; The University of Texas MD Anderson; Cancer Center; (9) Department of Statistics; Rice University)

arXiv:2209.14277·physics.med-ph·April 26, 2023

Deep Learning-Based Dose Prediction for Automated, Individualized Quality Assurance of Head and Neck Radiation Therapy Plans

Mary P. Gronberg (1, 2), Beth M. Beadle (3), Adam S. Garden (4),, Heath Skinner (5), Skylar Gay (1, 2), Tucker Netherton (1, 2), Wenhua, Cao (1), Carlos E. Cardenas (6), Christine Chung (1), David Fuentes (2 and, 7), Clifton D. Fuller (2, 4), Rebecca M. Howell (1, 2)

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TL;DR

This study develops a deep learning model to predict dose distributions in head and neck radiation therapy plans, enabling automated assessment of plan quality and identification of suboptimal plans, potentially improving clinical workflow.

Contribution

Introduces a 3D Dense Dilated U-Net for dose prediction that supports automated, individualized quality assessment of radiation therapy plans.

Findings

01

Predicted dose distributions closely match KBP plans.

02

Model effectively flags suboptimal OAR sparing.

03

High variability among physicians' quality assessments.

Abstract

Purpose: This study aimed to use deep learning-based dose prediction to assess head and neck (HN) plan quality and identify suboptimal plans. Methods: A total of 245 VMAT HN plans were created using RapidPlan knowledge-based planning (KBP). A subset of 112 high-quality plans was selected under the supervision of an HN radiation oncologist. We trained a 3D Dense Dilated U-Net architecture to predict 3-dimensional dose distributions using 3-fold cross-validation on 90 plans. Model inputs included CT images, target prescriptions, and contours for targets and organs at risk (OARs). The model's performance was assessed on the remaining 22 test plans. We then tested the application of the dose prediction model for automated review of plan quality. Dose distributions were predicted on 14 clinical plans. The predicted versus clinical OAR dose metrics were compared to flag OARs with suboptimal…

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Taxonomy

TopicsAdvanced Radiotherapy Techniques · Head and Neck Cancer Studies · Medical Imaging and Analysis