Toward a human-centric co-design methodology for AI detection of differences between planned and delivered dose in radiotherapy

Luca M. Heising; Frank Verhaegen; Stefan G. Scheib; Maria J. G. Jacobs; Carol X. J. Ou; Viola Mottarella; Yin-Ho Chong; Mariangela Zamburlini; Sebastiaan M. J. J. G. Nijsten; Ans Swinnen; Michel Ollers; Cecile J. A. Wolfs

doi:10.1002/acm2.70071

Toward a human-centric co-design methodology for AI detection of differences between planned and delivered dose in radiotherapy

Luca M. Heising, Frank Verhaegen, Stefan G. Scheib, Maria J. G. Jacobs, Carol X. J. Ou, Viola Mottarella, Yin-Ho Chong, Mariangela Zamburlini, Sebastiaan M. J. J. G. Nijsten, Ans Swinnen, Michel Ollers, Cecile J. A. Wolfs

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

Abstract

IntroductionMany artificial intelligence (AI) solutions have been proposed to enhance the radiotherapy (RT) workflow, but limited applications have been implemented to date, suggesting an implementation gap. One contributing factor to this gap is a misalignment between AI systems and their users. To address the AI implementation gap, we propose a human-centric methodology, novel in RT, for an interface design of an AI-driven RT treatment error detection system.MethodsA 5-day design sprint was set up with a multi-disciplinary team of clinical and research staff and a commercial company. In the design sprint, an interface was prototyped to aid medical physicists in catching treatment errors during daily treatment fractions using dose-guided RT (DGRT) with a portal imager.ResultsThe design sprint resulted in a simulated prototype of an interface supported by all stakeholders. Important features of an interface include the AI certainty metric, explainable AI features, feedback options, and decision aid. The prototype was well-received by expert users.Conclusion/discussionUsing a co-creation strategy, which is a novel approach in RT, we were able to prototype a novel human-interpretable interface to detect RT treatment errors and aid the DGRT workflow. Users showed confidence that the overall design method and the proposed prototype could lead to a viable clinical implementation.

Original language	English
Article number	e70071
Number of pages	11
Journal	Journal of applied clinical medical physics
Volume	26
Issue number	6
DOIs	https://doi.org/10.1002/acm2.70071
Publication status	Published - Jun 2025

Keywords

Artificial intelligence
Dose-guided radiotherapy
Explainable artificial intelligence
human-AI interaction
Human-centric design
In vivo dosimetry
Radiotherapy

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10.1002/acm2.70071

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Heising, L. M., Verhaegen, F., Scheib, S. G., Jacobs, M. J. G., Ou, C. X. J., Mottarella, V., Chong, Y.-H., Zamburlini, M., Nijsten, S. M. J. J. G., Swinnen, A., Ollers, M., & Wolfs, C. J. A. (2025). Toward a human-centric co-design methodology for AI detection of differences between planned and delivered dose in radiotherapy. Journal of applied clinical medical physics, 26(6), Article e70071. https://doi.org/10.1002/acm2.70071

@article{d0ddf168245c44959fc59128df4ae4c9,

title = "Toward a human-centric co-design methodology for AI detection of differences between planned and delivered dose in radiotherapy",

abstract = "IntroductionMany artificial intelligence (AI) solutions have been proposed to enhance the radiotherapy (RT) workflow, but limited applications have been implemented to date, suggesting an implementation gap. One contributing factor to this gap is a misalignment between AI systems and their users. To address the AI implementation gap, we propose a human-centric methodology, novel in RT, for an interface design of an AI-driven RT treatment error detection system.MethodsA 5-day design sprint was set up with a multi-disciplinary team of clinical and research staff and a commercial company. In the design sprint, an interface was prototyped to aid medical physicists in catching treatment errors during daily treatment fractions using dose-guided RT (DGRT) with a portal imager.ResultsThe design sprint resulted in a simulated prototype of an interface supported by all stakeholders. Important features of an interface include the AI certainty metric, explainable AI features, feedback options, and decision aid. The prototype was well-received by expert users.Conclusion/discussionUsing a co-creation strategy, which is a novel approach in RT, we were able to prototype a novel human-interpretable interface to detect RT treatment errors and aid the DGRT workflow. Users showed confidence that the overall design method and the proposed prototype could lead to a viable clinical implementation.",

keywords = "Artificial intelligence, Dose-guided radiotherapy, Explainable artificial intelligence, human-AI interaction, Human-centric design, In vivo dosimetry, Radiotherapy",

author = "Heising, {Luca M.} and Frank Verhaegen and Scheib, {Stefan G.} and Jacobs, {Maria J. G.} and Ou, {Carol X. J.} and Viola Mottarella and Yin-Ho Chong and Mariangela Zamburlini and Nijsten, {Sebastiaan M. J. J. G.} and Ans Swinnen and Michel Ollers and Wolfs, {Cecile J. A.}",

year = "2025",

month = jun,

doi = "10.1002/acm2.70071",

language = "English",

volume = "26",

journal = "Journal of applied clinical medical physics",

issn = "1526-9914",

publisher = "John Wiley and Sons Ltd",

number = "6",

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Heising, LM, Verhaegen, F, Scheib, SG, Jacobs, MJG , Ou, CXJ, Mottarella, V, Chong, Y-H, Zamburlini, M, Nijsten, SMJJG, Swinnen, A, Ollers, M & Wolfs, CJA 2025, 'Toward a human-centric co-design methodology for AI detection of differences between planned and delivered dose in radiotherapy', Journal of applied clinical medical physics, vol. 26, no. 6, e70071. https://doi.org/10.1002/acm2.70071

TY - JOUR

T1 - Toward a human-centric co-design methodology for AI detection of differences between planned and delivered dose in radiotherapy

AU - Heising, Luca M.

AU - Verhaegen, Frank

AU - Scheib, Stefan G.

AU - Jacobs, Maria J. G.

AU - Ou, Carol X. J.

AU - Mottarella, Viola

AU - Chong, Yin-Ho

AU - Zamburlini, Mariangela

AU - Nijsten, Sebastiaan M. J. J. G.

AU - Swinnen, Ans

AU - Ollers, Michel

AU - Wolfs, Cecile J. A.

PY - 2025/6

Y1 - 2025/6

N2 - IntroductionMany artificial intelligence (AI) solutions have been proposed to enhance the radiotherapy (RT) workflow, but limited applications have been implemented to date, suggesting an implementation gap. One contributing factor to this gap is a misalignment between AI systems and their users. To address the AI implementation gap, we propose a human-centric methodology, novel in RT, for an interface design of an AI-driven RT treatment error detection system.MethodsA 5-day design sprint was set up with a multi-disciplinary team of clinical and research staff and a commercial company. In the design sprint, an interface was prototyped to aid medical physicists in catching treatment errors during daily treatment fractions using dose-guided RT (DGRT) with a portal imager.ResultsThe design sprint resulted in a simulated prototype of an interface supported by all stakeholders. Important features of an interface include the AI certainty metric, explainable AI features, feedback options, and decision aid. The prototype was well-received by expert users.Conclusion/discussionUsing a co-creation strategy, which is a novel approach in RT, we were able to prototype a novel human-interpretable interface to detect RT treatment errors and aid the DGRT workflow. Users showed confidence that the overall design method and the proposed prototype could lead to a viable clinical implementation.

AB - IntroductionMany artificial intelligence (AI) solutions have been proposed to enhance the radiotherapy (RT) workflow, but limited applications have been implemented to date, suggesting an implementation gap. One contributing factor to this gap is a misalignment between AI systems and their users. To address the AI implementation gap, we propose a human-centric methodology, novel in RT, for an interface design of an AI-driven RT treatment error detection system.MethodsA 5-day design sprint was set up with a multi-disciplinary team of clinical and research staff and a commercial company. In the design sprint, an interface was prototyped to aid medical physicists in catching treatment errors during daily treatment fractions using dose-guided RT (DGRT) with a portal imager.ResultsThe design sprint resulted in a simulated prototype of an interface supported by all stakeholders. Important features of an interface include the AI certainty metric, explainable AI features, feedback options, and decision aid. The prototype was well-received by expert users.Conclusion/discussionUsing a co-creation strategy, which is a novel approach in RT, we were able to prototype a novel human-interpretable interface to detect RT treatment errors and aid the DGRT workflow. Users showed confidence that the overall design method and the proposed prototype could lead to a viable clinical implementation.

KW - Artificial intelligence

KW - Dose-guided radiotherapy

KW - Explainable artificial intelligence

KW - human-AI interaction

KW - Human-centric design

KW - In vivo dosimetry

KW - Radiotherapy

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Toward a human-centric co-design methodology for AI detection of differences between planned and delivered dose in radiotherapy

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