Faculty, Staff and Student Publications

Publication Date

7-1-2024

Journal

Journal of Applied Clinical Medical Physics

Abstract

Purpose: Volumetric-modulated arc therapy (VMAT) is a widely accepted treatment method for head and neck (HN) and cervical cancers; however, creating contours and plan optimization for VMAT plans is a time-consuming process. Our group has created an automated treatment planning tool, the Radiation Planning Assistant (RPA), that uses deep learning models to generate organs at risk (OARs), planning structures and automates plan optimization. This study quantitatively evaluates the quality of contours generated by the RPA tool.

Methods: For patients with HN (54) and cervical (39) cancers, we retrospectively generated autoplans using the RPA. Autoplans were generated using deep-learning and RapidPlan models developed in-house. The autoplans were, then, applied to the original, physician-drawn contours, which were used as a ground truth (GT) to compare with the autocontours (RPA). Using a "two one-sided tests" (TOST) procedure, we evaluated whether the autocontour normal tissue dose was equivalent to that of the ground truth by a margin, δ, that we determined based on clinical judgement. We also calculated the number of plans that met established clinically accepted dosimetric criteria.

Results: For HN plans, 91.8% and 91.7% of structures met dosimetric criteria for automatic and manual contours, respectively; for cervical plans, 95.6% and 95.7% of structures met dosimetric criteria for automatic and manual contours, respectively. Autocontours were equivalent to the ground truth for 71% and 75% of common DVH metrics for the HN and cervix, respectively.

Conclusions: This study shows that dosimetrically equivalent normal tissue contours can be created for HN and cervical cancers using deep learning techniques. In general, differences between the contours did not affect the passing or failing of clinical dose tolerances.

Keywords

Humans, Radiotherapy Planning, Computer-Assisted, Head and Neck Neoplasms, Radiotherapy, Intensity-Modulated, Organs at Risk, Radiotherapy Dosage, Female, Retrospective Studies, Uterine Cervical Neoplasms, Deep Learning, Algorithms, auto‐contour evaluation

DOI

10.1002/acm2.14338

PMID

38610118

PMCID

PMC11244666

PubMedCentral® Posted Date

4-12-2024

PubMedCentral® Full Text Version

Post-print

Published Open-Access

yes

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