A risk assessment of automated treatment planning and recommendations for clinical deployment

Kisling, Kelly; Johnson, Jennifer L.; Simonds, Hannah; Zhang, Lifei; Jhingran, Anuja; Beadle, Beth M.; Burger, Hester; Toit, Monique du; Joubert, Nanette; Makufa, Remigio; Shaw, William V.; Trauernicht, Christoph; Balter, Peter A; Howell, Rebecca M.; Schmeler, Kathleen M.; Court, Laurence Edward

doi:10.1002/mp.13552

Cited by 27 publications

(33 citation statements)

References 14 publications

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“…For example, the Radiation Planning Assistant (RPA, https:// rpa.mdanderson.org) is being developed at The University of Texas MD Anderson Cancer Center to fully automate the radiation treatment planning process with no or minimal user interventions. [45][46][47][48] For such a system to be effective in reducing the workload at busy clinics with limited resources, including radiation oncologists, high-quality automatic contouring is essential. 23 The present study showed that deep learning can achieve this, and we are integrating these tools to autosegment normal tissue and target volumes into the RAP system.…”

Section: Discussionmentioning

confidence: 99%

Generating High-Quality Lymph Node Clinical Target Volumes for Head and Neck Cancer Radiation Therapy Using a Fully Automated Deep Learning-Based Approach

Cárdenas

Beadle

Garden

et al. 2021

International Journal of Radiation Oncology*Biology*Physics

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Purpose: To develop a deep learning model that generates consistent, high-quality lymph node clinical target volumes (CTV) contours for head and neck cancer (HNC) patients, as an integral part of a fully automated radiation treatment planning workflow. Methods and Materials: Computed tomography (CT) scans from 71 HNC patients were retrospectively collected and split into training (n Z 51), cross-validation (n Z 10), and test (n Z 10) data sets. All had target volume delineations covering lymph node levels Ia through V (Ia-V), Ib through V (Ib-V), II through IV (II-IV), and retropharyngeal (RP) nodes, which were previously approved by a radiation oncologist specializing in HNC. Volumes of interest (VOIs) about nodal levels were automatically identified using computer vision techniques. The VOI (cropped CT image) and approved contours were used to train a U-Net autosegmentation model. Each lymph node level was trained independently, with model parameters optimized by assessing performance on the cross-validation data set. Once optimal model parameters were identified, overlap and distance metrics were calculated between ground truth and autosegmentations on the test set. Lastly, this final model was used

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Section: Discussionmentioning

confidence: 99%

Generating High-Quality Lymph Node Clinical Target Volumes for Head and Neck Cancer Radiation Therapy Using a Fully Automated Deep Learning-Based Approach

Cárdenas

Beadle

Garden

et al. 2021

International Journal of Radiation Oncology*Biology*Physics

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“…In a previous risk assessment of automated treatment planning using failure modes and effects analysis, it was found that beam aperture creation was 1 of the high-risk areas subject to failure. 25 Currently, standard practice relies solely on 1 physician to determine the clinical acceptability of the beam apertures; there is no secondary check by an independent expert. To our knowledge, the QA technique presented in this work is the first technique to automatically verify the clinical acceptability of beam apertures.…”

Section: Discussionmentioning

confidence: 99%

Automatic Verification of Beam Apertures for Cervical Cancer Radiation Therapy

Kisling

Cárdenas

Anderson

et al. 2020

Practical Radiation Oncology

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Automated tools can help identify radiation treatment plans of unacceptable quality. To this end, we developed a quality verification technique to automatically verify the clinical acceptability of beam apertures for 4-field box treatments of patients with cervical cancer. By comparing the beam apertures to be used for treatment with a secondary set of beam apertures developed automatically, this quality verification technique can flag beam apertures that may need to be edited to be acceptable for treatment. Methods and Materials: The automated methodology for creating verification beam apertures uses a deep learning model trained on beam apertures and digitally reconstructed radiographs from 255 clinically acceptable planned treatments (as rated by physicians). These verification apertures were then compared with the treatment apertures using spatial comparison metrics to detect unacceptable treatment apertures. We tested the quality verification technique on beam apertures from 80 treatment plans. Each plan was rated by physicians, where 57 were rated clinically acceptable and 23 were rated clinically unacceptable. Results: Using various comparison metrics (the mean surface distance, Hausdorff distance, and Dice similarity coefficient) for the 2 sets of beam apertures, we found that treatment beam apertures rated acceptable had significantly better agreement with the verification beam apertures than those rated unacceptable (P < .01). Upon receiver operating characteristic analysis, we found the area under the curve for all metrics to be 0.89 to 0.95, which demonstrated the high sensitivity and specificity of our quality verification technique. Conclusions: We found that our technique of automatically verifying the beam aperture is an effective tool for flagging potentially unacceptable beam apertures during the treatment plan review process. Accordingly, we will clinically deploy this quality verification technique as part of a fully automated treatment planning tool and automated plan quality assurance program.

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“…This dual expert approach performs treatment planning tasks (e.g., contouring, isocenter detection, field aperture creation) using independent models, and flags erroneous contours or plans based on metrics which quantify agreement between the two methods. Such an approach has been found to be effective in increasing the detectability of treatment planning failures when assessed by FMEA for cervix and ROC analysis for the head and neck [45, 46].…”

Section: Past Transformative Innovationsmentioning

confidence: 99%

The Emergence of Artificial Intelligence within Radiation Oncology Treatment Planning

et al. 2020

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Background: The future of artificial intelligence (AI) heralds unprecedented change for the field of radiation oncology. Commercial vendors and academic institutions have created AI tools for radiation oncology, but such tools have not yet been widely adopted into clinical practice. In addition, numerous discussions have prompted careful thoughts about AI’s impact upon the future landscape of radiation oncology: How can we preserve innovation, creativity, and patient safety? When will AI-based tools be widely adopted into the clinic? Will the need for clinical staff be reduced? How will these devices and tools be developed and regulated? Summary: In this work, we examine how deep learning, a rapidly emerging subset of AI, fits into the broader historical context of advancements made in radiation oncology and medical physics. In addition, we examine a representative set of deep learning-based tools that are being made available for use in external beam radiotherapy treatment planning and how these deep learning-based tools and other AI-based tools will impact members of the radiation treatment planning team. Key Messages: Compared to past transformative innovations explored in this article, such as the Monte Carlo method or intensity-modulated radiotherapy, the development and adoption of deep learning-based tools is occurring at faster rates and promises to transform practices of the radiation treatment planning team. However, accessibility to these tools will be determined by each clinic’s access to the internet, web-based solutions, or high-performance computing hardware. As seen by the trends exhibited by many technologies, high dependence on new technology can result in harm should the product fail in an unexpected manner, be misused by the operator, or if the mitigation to an expected failure is not adequate. Thus, the need for developers and researchers to rigorously validate deep learning-based tools, for users to understand how to operate tools appropriately, and for professional bodies to develop guidelines for their use and maintenance is essential. Given that members of the radiation treatment planning team perform many tasks that are automatable, the use of deep learning-based tools, in combination with other automated treatment planning tools, may refocus tasks performed by the treatment planning team and may potentially reduce resource-related burdens for clinics with limited resources.

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A risk assessment of automated treatment planning and recommendations for clinical deployment

Cited by 27 publications

References 14 publications

Generating High-Quality Lymph Node Clinical Target Volumes for Head and Neck Cancer Radiation Therapy Using a Fully Automated Deep Learning-Based Approach

Generating High-Quality Lymph Node Clinical Target Volumes for Head and Neck Cancer Radiation Therapy Using a Fully Automated Deep Learning-Based Approach

Automatic Verification of Beam Apertures for Cervical Cancer Radiation Therapy

The Emergence of Artificial Intelligence within Radiation Oncology Treatment Planning

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