Prospective deployment of an automated implementation solution for artificial intelligence translation to clinical radiation oncology

Christopher E Kehayias; Yujie Yan; Dennis Bontempi; Sarah Quirk; Danielle S Bitterman; Jeremy S Bredfeldt; Hugo J W L Aerts; Raymond H Mak; Christian V Guthier

doi:10.3389/fonc.2023.1305511

Prospective deployment of an automated implementation solution for artificial intelligence translation to clinical radiation oncology

Front Oncol. 2024 Jan 4:13:1305511. doi: 10.3389/fonc.2023.1305511. eCollection 2023.

Authors

Christopher E Kehayias¹, Yujie Yan¹, Dennis Bontempi^{2

3}, Sarah Quirk¹, Danielle S Bitterman¹, Jeremy S Bredfeldt¹, Hugo J W L Aerts^{1

2

3}, Raymond H Mak^{1

2}, Christian V Guthier^{1

2}

Affiliations

¹ Department of Radiation Oncology, Brigham and Women's Hospital, Dana-Farber Cancer Institute, Harvard Medical School, Boston, MA, United States.
² Artificial Intelligence in Medicine (AIM) Program, Mass General Brigham, Harvard Medical School, Boston, MA, United States.
³ Radiology and Nuclear Medicine, CARIM & GROW, Maastricht University, Maastricht, Netherlands.

Abstract

Introduction: Artificial intelligence (AI)-based technologies embody countless solutions in radiation oncology, yet translation of AI-assisted software tools to actual clinical environments remains unrealized. We present the Deep Learning On-Demand Assistant (DL-ODA), a fully automated, end-to-end clinical platform that enables AI interventions for any disease site featuring an automated model-training pipeline, auto-segmentations, and QA reporting.

Materials and methods: We developed, tested, and prospectively deployed the DL-ODA system at a large university affiliated hospital center. Medical professionals activate the DL-ODA via two pathways (1): On-Demand, used for immediate AI decision support for a patient-specific treatment plan, and (2) Ambient, in which QA is provided for all daily radiotherapy (RT) plans by comparing DL segmentations with manual delineations and calculating the dosimetric impact. To demonstrate the implementation of a new anatomy segmentation, we used the model-training pipeline to generate a breast segmentation model based on a large clinical dataset. Additionally, the contour QA functionality of existing models was assessed using a retrospective cohort of 3,399 lung and 885 spine RT cases. Ambient QA was performed for various disease sites including spine RT and heart for dosimetric sparing.

Results: Successful training of the breast model was completed in less than a day and resulted in clinically viable whole breast contours. For the retrospective analysis, we evaluated manual-versus-AI similarity for the ten most common structures. The DL-ODA detected high similarities in heart, lung, liver, and kidney delineations but lower for esophagus, trachea, stomach, and small bowel due largely to incomplete manual contouring. The deployed Ambient QAs for heart and spine sites have prospectively processed over 2,500 cases and 230 cases over 9 months and 5 months, respectively, automatically alerting the RT personnel.

Discussion: The DL-ODA capabilities in providing universal AI interventions were demonstrated for On-Demand contour QA, DL segmentations, and automated model training, and confirmed successful integration of the system into a large academic radiotherapy department. The novelty of deploying the DL-ODA as a multi-modal, fully automated end-to-end AI clinical implementation solution marks a significant step towards a generalizable framework that leverages AI to improve the efficiency and reliability of RT systems.

Keywords: automated deployment; automated report generation; autosegmentation; clinical translation; deep learning - artificial intelligence; end-to-end solution; quality assurance.

Grants and funding

The author(s) declare that no financial support was received for the research, authorship, and/or publication of this article.