Knowledge-based planning for fully automated radiation therapy treatment planning of 10 different cancer sites

Christine V. Chung; Meena S. Khan; Adenike Olanrewaju; Mary Pham; Quyen T. Nguyen; Tina Patel; Prajnan Das; Michael S. O'Reilly; Valerie K. Reed; Anuja Jhingran; Hannah Simonds; Ethan B. Ludmir; Karen E. Hoffman; Komeela Naidoo; Jeannette Parkes; Ajay Aggarwal; Lauren L. Mayo; Shalin J. Shah; Chad Tang; Beth M. Beadle; Julie Wetter; Gary Walker; Simon Hughes; Vinod Mullassery; Stephen Skett; Christopher Thomas; Lifei Zhang; Son Nguyen; Raymond P. Mumme; Raphael J. Douglas; Hana Baroudi; Laurence E. Court

doi:10.1016/j.radonc.2024.110609

Knowledge-based planning for fully automated radiation therapy treatment planning of 10 different cancer sites

Christine V. Chung, Meena S. Khan, Adenike Olanrewaju, Mary Pham, Quyen T. Nguyen, Tina Patel, Prajnan Das, Michael S. O'Reilly, Valerie K. Reed, Anuja Jhingran, Hannah Simonds, Ethan B. Ludmir, Karen E. Hoffman, Komeela Naidoo, Jeannette Parkes, Ajay Aggarwal, Lauren L. Mayo, Shalin J. Shah, Chad Tang, Beth M. BeadleJulie Wetter, Gary Walker, Simon Hughes, Vinod Mullassery, Stephen Skett, Christopher Thomas, Lifei Zhang, Son Nguyen, Raymond P. Mumme, Raphael J. Douglas, Hana Baroudi, Laurence E. Court

Research output: Contribution to journal › Article › peer-review

4 Scopus citations

Abstract

Purpose: Radiation treatment planning is highly complex and can have significant inter- and intra-planner inconsistency, as well as variability in planning time and plan quality. Knowledge-based planning (KBP) is a tool that can be used to efficiently produce high-quality, consistent, clinically acceptable plans, independent of planner skills and experience. In this study, we created and validated multiple clinically acceptable and fully automatable KBP models, with the goal of creating VMAT plans without user intervention. Methods: Ten KBP models were configured using high quality clinical plans from a single institution. They were then honed to be part of a fully automatable system by incorporating scriptable planning structures, plan creation, and plan optimization. These models were verified and validated using quantitative (model statistics) and qualitative (dose-volume histogram estimation review) analysis. The resulting KBP-generated plans were reviewed by physicians and rated for clinical acceptability. Results: Autoplanning models were created for anorectal, bladder, breast/chest wall, cervix, esophagus, head and neck, liver, lung/mediastinum, prostate, and prostate with nodes treatment sites. All models were successfully created to be part of a fully automated system without the need for human intervention to create a fully optimized plan. The physician review indicated that, on average, 88% of all KBP-generated plans were “acceptable as is” and 98% were “acceptable after minor edits.” Conclusion: KBP models for multiple treatment sites were used as a basis to generate fully automatable, efficient, consistent, high-quality, and clinically acceptable plans. These plans do not require human intervention, demonstrating the potential this work has to significantly impact treatment planning workflows.

Original language	English (US)
Article number	110609
Journal	Radiotherapy and Oncology
Volume	202
DOIs	https://doi.org/10.1016/j.radonc.2024.110609
State	Published - Jan 2025

Keywords

Artificial intelligence
Automation
Knowledge-Based Planning
Treatment planning
VMAT

ASJC Scopus subject areas

Hematology
Oncology
Radiology Nuclear Medicine and imaging

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10.1016/j.radonc.2024.110609

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Chung, C. V., Khan, M. S., Olanrewaju, A., Pham, M., Nguyen, Q. T., Patel, T., Das, P., O'Reilly, M. S., Reed, V. K., Jhingran, A., Simonds, H., Ludmir, E. B., Hoffman, K. E., Naidoo, K., Parkes, J., Aggarwal, A., Mayo, L. L., Shah, S. J., Tang, C., ... Court, L. E. (2025). Knowledge-based planning for fully automated radiation therapy treatment planning of 10 different cancer sites. Radiotherapy and Oncology, 202, Article 110609. https://doi.org/10.1016/j.radonc.2024.110609

Chung, CV, Khan, MS, Olanrewaju, A, Pham, M, Nguyen, QT, Patel, T, Das, P , O'Reilly, MS , Reed, VK , Jhingran, A, Simonds, H, Ludmir, EB , Hoffman, KE, Naidoo, K, Parkes, J, Aggarwal, A, Mayo, LL , Shah, SJ , Tang, C, Beadle, BM, Wetter, J, Walker, G, Hughes, S, Mullassery, V, Skett, S, Thomas, C, Zhang, L, Nguyen, S, Mumme, RP, Douglas, RJ, Baroudi, H & Court, LE 2025, 'Knowledge-based planning for fully automated radiation therapy treatment planning of 10 different cancer sites', Radiotherapy and Oncology, vol. 202, 110609. https://doi.org/10.1016/j.radonc.2024.110609

@article{0bc5cf61f6cc4826b71b8d8e685d7d89,

title = "Knowledge-based planning for fully automated radiation therapy treatment planning of 10 different cancer sites",

abstract = "Purpose: Radiation treatment planning is highly complex and can have significant inter- and intra-planner inconsistency, as well as variability in planning time and plan quality. Knowledge-based planning (KBP) is a tool that can be used to efficiently produce high-quality, consistent, clinically acceptable plans, independent of planner skills and experience. In this study, we created and validated multiple clinically acceptable and fully automatable KBP models, with the goal of creating VMAT plans without user intervention. Methods: Ten KBP models were configured using high quality clinical plans from a single institution. They were then honed to be part of a fully automatable system by incorporating scriptable planning structures, plan creation, and plan optimization. These models were verified and validated using quantitative (model statistics) and qualitative (dose-volume histogram estimation review) analysis. The resulting KBP-generated plans were reviewed by physicians and rated for clinical acceptability. Results: Autoplanning models were created for anorectal, bladder, breast/chest wall, cervix, esophagus, head and neck, liver, lung/mediastinum, prostate, and prostate with nodes treatment sites. All models were successfully created to be part of a fully automated system without the need for human intervention to create a fully optimized plan. The physician review indicated that, on average, 88% of all KBP-generated plans were “acceptable as is” and 98% were “acceptable after minor edits.” Conclusion: KBP models for multiple treatment sites were used as a basis to generate fully automatable, efficient, consistent, high-quality, and clinically acceptable plans. These plans do not require human intervention, demonstrating the potential this work has to significantly impact treatment planning workflows.",

keywords = "Artificial intelligence, Automation, Knowledge-Based Planning, Treatment planning, VMAT",

author = "Chung, {Christine V.} and Khan, {Meena S.} and Adenike Olanrewaju and Mary Pham and Nguyen, {Quyen T.} and Tina Patel and Prajnan Das and O'Reilly, {Michael S.} and Reed, {Valerie K.} and Anuja Jhingran and Hannah Simonds and Ludmir, {Ethan B.} and Hoffman, {Karen E.} and Komeela Naidoo and Jeannette Parkes and Ajay Aggarwal and Mayo, {Lauren L.} and Shah, {Shalin J.} and Chad Tang and Beadle, {Beth M.} and Julie Wetter and Gary Walker and Simon Hughes and Vinod Mullassery and Stephen Skett and Christopher Thomas and Lifei Zhang and Son Nguyen and Mumme, {Raymond P.} and Douglas, {Raphael J.} and Hana Baroudi and Court, {Laurence E.}",

note = "Publisher Copyright: {\textcopyright} 2024 The Authors",

year = "2025",

month = jan,

doi = "10.1016/j.radonc.2024.110609",

language = "English (US)",

volume = "202",

journal = "Radiotherapy and Oncology",

issn = "0167-8140",

publisher = "Elsevier Ireland Ltd",

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TY - JOUR

T1 - Knowledge-based planning for fully automated radiation therapy treatment planning of 10 different cancer sites

AU - Chung, Christine V.

AU - Khan, Meena S.

AU - Olanrewaju, Adenike

AU - Pham, Mary

AU - Nguyen, Quyen T.

AU - Patel, Tina

AU - Das, Prajnan

AU - O'Reilly, Michael S.

AU - Reed, Valerie K.

AU - Jhingran, Anuja

AU - Simonds, Hannah

AU - Ludmir, Ethan B.

AU - Hoffman, Karen E.

AU - Naidoo, Komeela

AU - Parkes, Jeannette

AU - Aggarwal, Ajay

AU - Mayo, Lauren L.

AU - Shah, Shalin J.

AU - Tang, Chad

AU - Beadle, Beth M.

AU - Wetter, Julie

AU - Walker, Gary

AU - Hughes, Simon

AU - Mullassery, Vinod

AU - Skett, Stephen

AU - Thomas, Christopher

AU - Zhang, Lifei

AU - Nguyen, Son

AU - Mumme, Raymond P.

AU - Douglas, Raphael J.

AU - Baroudi, Hana

AU - Court, Laurence E.

PY - 2025/1

Y1 - 2025/1

N2 - Purpose: Radiation treatment planning is highly complex and can have significant inter- and intra-planner inconsistency, as well as variability in planning time and plan quality. Knowledge-based planning (KBP) is a tool that can be used to efficiently produce high-quality, consistent, clinically acceptable plans, independent of planner skills and experience. In this study, we created and validated multiple clinically acceptable and fully automatable KBP models, with the goal of creating VMAT plans without user intervention. Methods: Ten KBP models were configured using high quality clinical plans from a single institution. They were then honed to be part of a fully automatable system by incorporating scriptable planning structures, plan creation, and plan optimization. These models were verified and validated using quantitative (model statistics) and qualitative (dose-volume histogram estimation review) analysis. The resulting KBP-generated plans were reviewed by physicians and rated for clinical acceptability. Results: Autoplanning models were created for anorectal, bladder, breast/chest wall, cervix, esophagus, head and neck, liver, lung/mediastinum, prostate, and prostate with nodes treatment sites. All models were successfully created to be part of a fully automated system without the need for human intervention to create a fully optimized plan. The physician review indicated that, on average, 88% of all KBP-generated plans were “acceptable as is” and 98% were “acceptable after minor edits.” Conclusion: KBP models for multiple treatment sites were used as a basis to generate fully automatable, efficient, consistent, high-quality, and clinically acceptable plans. These plans do not require human intervention, demonstrating the potential this work has to significantly impact treatment planning workflows.

AB - Purpose: Radiation treatment planning is highly complex and can have significant inter- and intra-planner inconsistency, as well as variability in planning time and plan quality. Knowledge-based planning (KBP) is a tool that can be used to efficiently produce high-quality, consistent, clinically acceptable plans, independent of planner skills and experience. In this study, we created and validated multiple clinically acceptable and fully automatable KBP models, with the goal of creating VMAT plans without user intervention. Methods: Ten KBP models were configured using high quality clinical plans from a single institution. They were then honed to be part of a fully automatable system by incorporating scriptable planning structures, plan creation, and plan optimization. These models were verified and validated using quantitative (model statistics) and qualitative (dose-volume histogram estimation review) analysis. The resulting KBP-generated plans were reviewed by physicians and rated for clinical acceptability. Results: Autoplanning models were created for anorectal, bladder, breast/chest wall, cervix, esophagus, head and neck, liver, lung/mediastinum, prostate, and prostate with nodes treatment sites. All models were successfully created to be part of a fully automated system without the need for human intervention to create a fully optimized plan. The physician review indicated that, on average, 88% of all KBP-generated plans were “acceptable as is” and 98% were “acceptable after minor edits.” Conclusion: KBP models for multiple treatment sites were used as a basis to generate fully automatable, efficient, consistent, high-quality, and clinically acceptable plans. These plans do not require human intervention, demonstrating the potential this work has to significantly impact treatment planning workflows.

KW - Artificial intelligence

KW - Automation

KW - Knowledge-Based Planning

KW - Treatment planning

KW - VMAT

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ER -

Knowledge-based planning for fully automated radiation therapy treatment planning of 10 different cancer sites

Abstract

Keywords

ASJC Scopus subject areas

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