Validation of clinical acceptability of deep-learning-based automated segmentation of organs-at-risk for head-and-neck radiotherapy treatment planning

J. John Lucido; Todd A. DeWees; Todd R. Leavitt; Aman Anand; Chris J. Beltran; Mark D. Brooke; Justine R. Buroker; Robert L. Foote; Olivia R. Foss; Angela M. Gleason; Teresa L. Hodge; Cían O. Hughes; Ashley E. Hunzeker; Nadia N. Laack; Tamra K. Lenz; Michelle Livne; Megumi Morigami; Douglas J. Moseley; Lisa M. Undahl; Yojan Patel; Erik J. Tryggestad; Megan Z. Walker; Alexei Zverovitch; Samir H. Patel

doi:10.3389/fonc.2023.1137803

Validation of clinical acceptability of deep-learning-based automated segmentation of organs-at-risk for head-and-neck radiotherapy treatment planning

J. John Lucido, Todd A. DeWees, Todd R. Leavitt, Aman Anand, Chris J. Beltran, Mark D. Brooke, Justine R. Buroker, Robert L. Foote, Olivia R. Foss, Angela M. Gleason, Teresa L. Hodge, Cían O. Hughes, Ashley E. Hunzeker, Nadia N. Laack, Tamra K. Lenz, Michelle Livne, Megumi Morigami, Douglas J. Moseley, Lisa M. Undahl, Yojan PatelErik J. Tryggestad, Megan Z. Walker, Alexei Zverovitch, Samir H. Patel

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

Abstract

Introduction: Organ-at-risk segmentation for head and neck cancer radiation therapy is a complex and time-consuming process (requiring up to 42 individual structure, and may delay start of treatment or even limit access to function-preserving care. Feasibility of using a deep learning (DL) based autosegmentation model to reduce contouring time without compromising contour accuracy is assessed through a blinded randomized trial of radiation oncologists (ROs) using retrospective, de-identified patient data. Methods: Two head and neck expert ROs used dedicated time to create gold standard (GS) contours on computed tomography (CT) images. 445 CTs were used to train a custom 3D U-Net DL model covering 42 organs-at-risk, with an additional 20 CTs were held out for the randomized trial. For each held-out patient dataset, one of the eight participant ROs was randomly allocated to review and revise the contours produced by the DL model, while another reviewed contours produced by a medical dosimetry assistant (MDA), both blinded to their origin. Time required for MDAs and ROs to contour was recorded, and the unrevised DL contours, as well as the RO-revised contours by the MDAs and DL model were compared to the GS for that patient. Results: Mean time for initial MDA contouring was 2.3 hours (range 1.6-3.8 hours) and RO-revision took 1.1 hours (range, 0.4-4.4 hours), compared to 0.7 hours (range 0.1-2.0 hours) for the RO-revisions to DL contours. Total time reduced by 76% (95%-Confidence Interval: 65%-88%) and RO-revision time reduced by 35% (95%-CI,-39%-91%). All geometric and dosimetric metrics computed, agreement with GS was equivalent or significantly greater (p<0.05) for RO-revised DL contours compared to the RO-revised MDA contours, including volumetric Dice similarity coefficient (VDSC), surface DSC, added path length, and the 95%-Hausdorff distance. 32 OARs (76%) had mean VDSC greater than 0.8 for the RO-revised DL contours, compared to 20 (48%) for RO-revised MDA contours, and 34 (81%) for the unrevised DL OARs. Conclusion: DL autosegmentation demonstrated significant time-savings for organ-at-risk contouring while improving agreement with the institutional GS, indicating comparable accuracy of DL model. Integration into the clinical practice with a prospective evaluation is currently underway.

Original language	English (US)
Article number	1137803
Journal	Frontiers in Oncology
Volume	13
DOIs	https://doi.org/10.3389/fonc.2023.1137803
State	Published - 2023

Keywords

autosegmentation
clinical validation
comprehensive
deep learning
head and neck cancer
organs-at-risk
radiation therapy

ASJC Scopus subject areas

Oncology
Cancer Research

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10.3389/fonc.2023.1137803

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Lucido, J. J., DeWees, T. A., Leavitt, T. R., Anand, A., Beltran, C. J., Brooke, M. D., Buroker, J. R., Foote, R. L., Foss, O. R., Gleason, A. M., Hodge, T. L., Hughes, C. O., Hunzeker, A. E., Laack, N. N., Lenz, T. K., Livne, M., Morigami, M., Moseley, D. J., Undahl, L. M., ... Patel, S. H. (2023). Validation of clinical acceptability of deep-learning-based automated segmentation of organs-at-risk for head-and-neck radiotherapy treatment planning. Frontiers in Oncology, 13, Article 1137803. https://doi.org/10.3389/fonc.2023.1137803

Lucido, JJ, DeWees, TA, Leavitt, TR, Anand, A, Beltran, CJ, Brooke, MD, Buroker, JR, Foote, RL, Foss, OR, Gleason, AM, Hodge, TL, Hughes, CO, Hunzeker, AE, Laack, NN, Lenz, TK, Livne, M, Morigami, M, Moseley, DJ, Undahl, LM, Patel, Y, Tryggestad, EJ, Walker, MZ, Zverovitch, A & Patel, SH 2023, 'Validation of clinical acceptability of deep-learning-based automated segmentation of organs-at-risk for head-and-neck radiotherapy treatment planning', Frontiers in Oncology, vol. 13, 1137803. https://doi.org/10.3389/fonc.2023.1137803

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title = "Validation of clinical acceptability of deep-learning-based automated segmentation of organs-at-risk for head-and-neck radiotherapy treatment planning",

abstract = "Introduction: Organ-at-risk segmentation for head and neck cancer radiation therapy is a complex and time-consuming process (requiring up to 42 individual structure, and may delay start of treatment or even limit access to function-preserving care. Feasibility of using a deep learning (DL) based autosegmentation model to reduce contouring time without compromising contour accuracy is assessed through a blinded randomized trial of radiation oncologists (ROs) using retrospective, de-identified patient data. Methods: Two head and neck expert ROs used dedicated time to create gold standard (GS) contours on computed tomography (CT) images. 445 CTs were used to train a custom 3D U-Net DL model covering 42 organs-at-risk, with an additional 20 CTs were held out for the randomized trial. For each held-out patient dataset, one of the eight participant ROs was randomly allocated to review and revise the contours produced by the DL model, while another reviewed contours produced by a medical dosimetry assistant (MDA), both blinded to their origin. Time required for MDAs and ROs to contour was recorded, and the unrevised DL contours, as well as the RO-revised contours by the MDAs and DL model were compared to the GS for that patient. Results: Mean time for initial MDA contouring was 2.3 hours (range 1.6-3.8 hours) and RO-revision took 1.1 hours (range, 0.4-4.4 hours), compared to 0.7 hours (range 0.1-2.0 hours) for the RO-revisions to DL contours. Total time reduced by 76% (95%-Confidence Interval: 65%-88%) and RO-revision time reduced by 35% (95%-CI,-39%-91%). All geometric and dosimetric metrics computed, agreement with GS was equivalent or significantly greater (p<0.05) for RO-revised DL contours compared to the RO-revised MDA contours, including volumetric Dice similarity coefficient (VDSC), surface DSC, added path length, and the 95%-Hausdorff distance. 32 OARs (76%) had mean VDSC greater than 0.8 for the RO-revised DL contours, compared to 20 (48%) for RO-revised MDA contours, and 34 (81%) for the unrevised DL OARs. Conclusion: DL autosegmentation demonstrated significant time-savings for organ-at-risk contouring while improving agreement with the institutional GS, indicating comparable accuracy of DL model. Integration into the clinical practice with a prospective evaluation is currently underway.",

keywords = "autosegmentation, clinical validation, comprehensive, deep learning, head and neck cancer, organs-at-risk, radiation therapy",

author = "Lucido, {J. John} and DeWees, {Todd A.} and Leavitt, {Todd R.} and Aman Anand and Beltran, {Chris J.} and Brooke, {Mark D.} and Buroker, {Justine R.} and Foote, {Robert L.} and Foss, {Olivia R.} and Gleason, {Angela M.} and Hodge, {Teresa L.} and Hughes, {C{\'i}an O.} and Hunzeker, {Ashley E.} and Laack, {Nadia N.} and Lenz, {Tamra K.} and Michelle Livne and Megumi Morigami and Moseley, {Douglas J.} and Undahl, {Lisa M.} and Yojan Patel and Tryggestad, {Erik J.} and Walker, {Megan Z.} and Alexei Zverovitch and Patel, {Samir H.}",

note = "Publisher Copyright: Copyright {\textcopyright} 2023 Lucido, DeWees, Leavitt, Anand, Beltran, Brooke, Buroker, Foote, Foss, Gleason, Hodge, Hughes, Hunzeker, Laack, Lenz, Livne, Morigami, Moseley, Undahl, Patel, Tryggestad, Walker, Zverovitch and Patel.",

year = "2023",

doi = "10.3389/fonc.2023.1137803",

language = "English (US)",

volume = "13",

journal = "Frontiers in Oncology",

issn = "2234-943X",

publisher = "Frontiers Media S. A.",

}

TY - JOUR

T1 - Validation of clinical acceptability of deep-learning-based automated segmentation of organs-at-risk for head-and-neck radiotherapy treatment planning

AU - Lucido, J. John

AU - DeWees, Todd A.

AU - Leavitt, Todd R.

AU - Anand, Aman

AU - Beltran, Chris J.

AU - Brooke, Mark D.

AU - Buroker, Justine R.

AU - Foote, Robert L.

AU - Foss, Olivia R.

AU - Gleason, Angela M.

AU - Hodge, Teresa L.

AU - Hughes, Cían O.

AU - Hunzeker, Ashley E.

AU - Laack, Nadia N.

AU - Lenz, Tamra K.

AU - Livne, Michelle

AU - Morigami, Megumi

AU - Moseley, Douglas J.

AU - Undahl, Lisa M.

AU - Patel, Yojan

AU - Tryggestad, Erik J.

AU - Walker, Megan Z.

AU - Zverovitch, Alexei

AU - Patel, Samir H.

N1 - Publisher Copyright: Copyright © 2023 Lucido, DeWees, Leavitt, Anand, Beltran, Brooke, Buroker, Foote, Foss, Gleason, Hodge, Hughes, Hunzeker, Laack, Lenz, Livne, Morigami, Moseley, Undahl, Patel, Tryggestad, Walker, Zverovitch and Patel.

PY - 2023

Y1 - 2023

N2 - Introduction: Organ-at-risk segmentation for head and neck cancer radiation therapy is a complex and time-consuming process (requiring up to 42 individual structure, and may delay start of treatment or even limit access to function-preserving care. Feasibility of using a deep learning (DL) based autosegmentation model to reduce contouring time without compromising contour accuracy is assessed through a blinded randomized trial of radiation oncologists (ROs) using retrospective, de-identified patient data. Methods: Two head and neck expert ROs used dedicated time to create gold standard (GS) contours on computed tomography (CT) images. 445 CTs were used to train a custom 3D U-Net DL model covering 42 organs-at-risk, with an additional 20 CTs were held out for the randomized trial. For each held-out patient dataset, one of the eight participant ROs was randomly allocated to review and revise the contours produced by the DL model, while another reviewed contours produced by a medical dosimetry assistant (MDA), both blinded to their origin. Time required for MDAs and ROs to contour was recorded, and the unrevised DL contours, as well as the RO-revised contours by the MDAs and DL model were compared to the GS for that patient. Results: Mean time for initial MDA contouring was 2.3 hours (range 1.6-3.8 hours) and RO-revision took 1.1 hours (range, 0.4-4.4 hours), compared to 0.7 hours (range 0.1-2.0 hours) for the RO-revisions to DL contours. Total time reduced by 76% (95%-Confidence Interval: 65%-88%) and RO-revision time reduced by 35% (95%-CI,-39%-91%). All geometric and dosimetric metrics computed, agreement with GS was equivalent or significantly greater (p<0.05) for RO-revised DL contours compared to the RO-revised MDA contours, including volumetric Dice similarity coefficient (VDSC), surface DSC, added path length, and the 95%-Hausdorff distance. 32 OARs (76%) had mean VDSC greater than 0.8 for the RO-revised DL contours, compared to 20 (48%) for RO-revised MDA contours, and 34 (81%) for the unrevised DL OARs. Conclusion: DL autosegmentation demonstrated significant time-savings for organ-at-risk contouring while improving agreement with the institutional GS, indicating comparable accuracy of DL model. Integration into the clinical practice with a prospective evaluation is currently underway.

AB - Introduction: Organ-at-risk segmentation for head and neck cancer radiation therapy is a complex and time-consuming process (requiring up to 42 individual structure, and may delay start of treatment or even limit access to function-preserving care. Feasibility of using a deep learning (DL) based autosegmentation model to reduce contouring time without compromising contour accuracy is assessed through a blinded randomized trial of radiation oncologists (ROs) using retrospective, de-identified patient data. Methods: Two head and neck expert ROs used dedicated time to create gold standard (GS) contours on computed tomography (CT) images. 445 CTs were used to train a custom 3D U-Net DL model covering 42 organs-at-risk, with an additional 20 CTs were held out for the randomized trial. For each held-out patient dataset, one of the eight participant ROs was randomly allocated to review and revise the contours produced by the DL model, while another reviewed contours produced by a medical dosimetry assistant (MDA), both blinded to their origin. Time required for MDAs and ROs to contour was recorded, and the unrevised DL contours, as well as the RO-revised contours by the MDAs and DL model were compared to the GS for that patient. Results: Mean time for initial MDA contouring was 2.3 hours (range 1.6-3.8 hours) and RO-revision took 1.1 hours (range, 0.4-4.4 hours), compared to 0.7 hours (range 0.1-2.0 hours) for the RO-revisions to DL contours. Total time reduced by 76% (95%-Confidence Interval: 65%-88%) and RO-revision time reduced by 35% (95%-CI,-39%-91%). All geometric and dosimetric metrics computed, agreement with GS was equivalent or significantly greater (p<0.05) for RO-revised DL contours compared to the RO-revised MDA contours, including volumetric Dice similarity coefficient (VDSC), surface DSC, added path length, and the 95%-Hausdorff distance. 32 OARs (76%) had mean VDSC greater than 0.8 for the RO-revised DL contours, compared to 20 (48%) for RO-revised MDA contours, and 34 (81%) for the unrevised DL OARs. Conclusion: DL autosegmentation demonstrated significant time-savings for organ-at-risk contouring while improving agreement with the institutional GS, indicating comparable accuracy of DL model. Integration into the clinical practice with a prospective evaluation is currently underway.

KW - autosegmentation

KW - clinical validation

KW - comprehensive

KW - deep learning

KW - head and neck cancer

KW - organs-at-risk

KW - radiation therapy

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U2 - 10.3389/fonc.2023.1137803

DO - 10.3389/fonc.2023.1137803

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SN - 2234-943X

VL - 13

JO - Frontiers in Oncology

JF - Frontiers in Oncology

M1 - 1137803

ER -

Validation of clinical acceptability of deep-learning-based automated segmentation of organs-at-risk for head-and-neck radiotherapy treatment planning

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