Practical robustness evaluation in radiotherapy - A photon and proton-proof alternative to PTV-based plan evaluation

Erik W Korevaar; Steven J M Habraken; Daniel Scandurra; Roel G J Kierkels; Mirko Unipan; Martijn G C Eenink; Roel J H M Steenbakkers; Stephanie G Peeters; Jaap D Zindler; Mischa Hoogeman; Johannes A Langendijk

doi:10.1016/j.radonc.2019.08.005

Practical robustness evaluation in radiotherapy - A photon and proton-proof alternative to PTV-based plan evaluation

Erik W Korevaar, Steven J M Habraken, Daniel Scandurra, Roel G J Kierkels, Mirko Unipan, Martijn G C Eenink, Roel J H M Steenbakkers, Stephanie G Peeters, Jaap D Zindler, Mischa Hoogeman, Johannes A Langendijk

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Abstract

Background and purpose: A planning target volume (PTV) in photon treatments aims to ensure that the clinical target volume (CTV) receives adequate dose despite treatment uncertainties. The underlying static dose cloud approximation (the assumption that the dose distribution is invariant to errors) is problematic in intensity modulated proton treatments where range errors should be taken into account as well. The purpose of this work is to introduce a robustness evaluation method that is applicable to photon and proton treatments and is consistent with (historic) PTV-based treatment plan evaluations.

Materials and methods: The limitation of the static dose cloud approximation was solved in a multi-scenario simulation by explicitly calculating doses for various treatment scenarios that describe possible errors in the treatment course. Setup errors were the same as the CTV-PTV margin and the underlying theory of 3D probability density distributions was extended to 4D to include range errors, maintaining a 90% confidence level. Scenario dose distributions were reduced to voxel-wise minimum and maximum dose distributions; the first to evaluate CTV coverage and the second for hot spots. Acceptance criteria for CTV D98 and D2 were calibrated against PTV-based criteria from historic photon treatment plans.

Results: CTV D98 in worst case scenario dose and voxel-wise minimum dose showed a very strong correlation with scenario average D98 (R-2 > 0.99). The voxel-wise minimum dose visualised CTV dose conformity and coverage in 3D in agreement with PTV-based evaluation in photon therapy. Criteria for CTV D98 and D2 of the voxel-wise minimum and maximum dose showed very strong correlations to PTV D98 and D2 (R-2 > 0.99) and on average needed corrections of -0.9% and +2.3%, respectively.

Conclusions: A practical approach to robustness evaluation was provided and clinically implemented for PTV-less photon and proton treatment planning, consistent with PTV evaluations but without its static dose cloud approximation. (C) 2019 The Authors. Published by Elsevier B.V.

Original language	English
Pages (from-to)	267-274
Number of pages	8
Journal	Radiotherapy and Oncology
Volume	141
Early online date	3-Sept-2019
DOIs	https://doi.org/10.1016/j.radonc.2019.08.005
Publication status	Published - Dec-2019

Keywords

Photon therapy
Proton therapy
Setup error
Range error
Margins
Robustness evaluation
TREATMENT UNCERTAINTIES
OROPHARYNGEAL CANCER
RANGE UNCERTAINTIES
RADIATION-THERAPY
SETUP ERRORS
OPTIMIZATION
SENSITIVITY
MARGINS
IMPT
VMAT

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Korevaar, E. W., Habraken, S. J. M., Scandurra, D., Kierkels, R. G. J., Unipan, M., Eenink, M. G. C., Steenbakkers, R. J. H. M., Peeters, S. G., Zindler, J. D., Hoogeman, M., & Langendijk, J. A. (2019). Practical robustness evaluation in radiotherapy - A photon and proton-proof alternative to PTV-based plan evaluation. Radiotherapy and Oncology, 141, 267-274. https://doi.org/10.1016/j.radonc.2019.08.005

@article{61eb2174f7a942e49b0b577a1183f0aa,

title = "Practical robustness evaluation in radiotherapy - A photon and proton-proof alternative to PTV-based plan evaluation",

abstract = "Background and purpose: A planning target volume (PTV) in photon treatments aims to ensure that the clinical target volume (CTV) receives adequate dose despite treatment uncertainties. The underlying static dose cloud approximation (the assumption that the dose distribution is invariant to errors) is problematic in intensity modulated proton treatments where range errors should be taken into account as well. The purpose of this work is to introduce a robustness evaluation method that is applicable to photon and proton treatments and is consistent with (historic) PTV-based treatment plan evaluations.Materials and methods: The limitation of the static dose cloud approximation was solved in a multi-scenario simulation by explicitly calculating doses for various treatment scenarios that describe possible errors in the treatment course. Setup errors were the same as the CTV-PTV margin and the underlying theory of 3D probability density distributions was extended to 4D to include range errors, maintaining a 90% confidence level. Scenario dose distributions were reduced to voxel-wise minimum and maximum dose distributions; the first to evaluate CTV coverage and the second for hot spots. Acceptance criteria for CTV D98 and D2 were calibrated against PTV-based criteria from historic photon treatment plans.Results: CTV D98 in worst case scenario dose and voxel-wise minimum dose showed a very strong correlation with scenario average D98 (R-2 > 0.99). The voxel-wise minimum dose visualised CTV dose conformity and coverage in 3D in agreement with PTV-based evaluation in photon therapy. Criteria for CTV D98 and D2 of the voxel-wise minimum and maximum dose showed very strong correlations to PTV D98 and D2 (R-2 > 0.99) and on average needed corrections of -0.9% and +2.3%, respectively.Conclusions: A practical approach to robustness evaluation was provided and clinically implemented for PTV-less photon and proton treatment planning, consistent with PTV evaluations but without its static dose cloud approximation. (C) 2019 The Authors. Published by Elsevier B.V.",

keywords = "Photon therapy, Proton therapy, Setup error, Range error, Margins, Robustness evaluation, TREATMENT UNCERTAINTIES, OROPHARYNGEAL CANCER, RANGE UNCERTAINTIES, RADIATION-THERAPY, SETUP ERRORS, OPTIMIZATION, SENSITIVITY, MARGINS, IMPT, VMAT",

author = "Korevaar, {Erik W} and Habraken, {Steven J M} and Daniel Scandurra and Kierkels, {Roel G J} and Mirko Unipan and Eenink, {Martijn G C} and Steenbakkers, {Roel J H M} and Peeters, {Stephanie G} and Zindler, {Jaap D} and Mischa Hoogeman and Langendijk, {Johannes A}",

year = "2019",

month = dec,

doi = "10.1016/j.radonc.2019.08.005",

language = "English",

volume = "141",

pages = "267--274",

journal = "Radiotherapy and Oncology",

issn = "0167-8140",

publisher = "ELSEVIER IRELAND LTD",

}

Korevaar, EW, Habraken, SJM, Scandurra, D, Kierkels, RGJ, Unipan, M, Eenink, MGC, Steenbakkers, RJHM, Peeters, SG, Zindler, JD, Hoogeman, M & Langendijk, JA 2019, 'Practical robustness evaluation in radiotherapy - A photon and proton-proof alternative to PTV-based plan evaluation', Radiotherapy and Oncology, vol. 141, pp. 267-274. https://doi.org/10.1016/j.radonc.2019.08.005

TY - JOUR

T1 - Practical robustness evaluation in radiotherapy - A photon and proton-proof alternative to PTV-based plan evaluation

AU - Korevaar, Erik W

AU - Habraken, Steven J M

AU - Scandurra, Daniel

AU - Kierkels, Roel G J

AU - Unipan, Mirko

AU - Eenink, Martijn G C

AU - Steenbakkers, Roel J H M

AU - Peeters, Stephanie G

AU - Zindler, Jaap D

AU - Hoogeman, Mischa

AU - Langendijk, Johannes A

PY - 2019/12

Y1 - 2019/12

N2 - Background and purpose: A planning target volume (PTV) in photon treatments aims to ensure that the clinical target volume (CTV) receives adequate dose despite treatment uncertainties. The underlying static dose cloud approximation (the assumption that the dose distribution is invariant to errors) is problematic in intensity modulated proton treatments where range errors should be taken into account as well. The purpose of this work is to introduce a robustness evaluation method that is applicable to photon and proton treatments and is consistent with (historic) PTV-based treatment plan evaluations.Materials and methods: The limitation of the static dose cloud approximation was solved in a multi-scenario simulation by explicitly calculating doses for various treatment scenarios that describe possible errors in the treatment course. Setup errors were the same as the CTV-PTV margin and the underlying theory of 3D probability density distributions was extended to 4D to include range errors, maintaining a 90% confidence level. Scenario dose distributions were reduced to voxel-wise minimum and maximum dose distributions; the first to evaluate CTV coverage and the second for hot spots. Acceptance criteria for CTV D98 and D2 were calibrated against PTV-based criteria from historic photon treatment plans.Results: CTV D98 in worst case scenario dose and voxel-wise minimum dose showed a very strong correlation with scenario average D98 (R-2 > 0.99). The voxel-wise minimum dose visualised CTV dose conformity and coverage in 3D in agreement with PTV-based evaluation in photon therapy. Criteria for CTV D98 and D2 of the voxel-wise minimum and maximum dose showed very strong correlations to PTV D98 and D2 (R-2 > 0.99) and on average needed corrections of -0.9% and +2.3%, respectively.Conclusions: A practical approach to robustness evaluation was provided and clinically implemented for PTV-less photon and proton treatment planning, consistent with PTV evaluations but without its static dose cloud approximation. (C) 2019 The Authors. Published by Elsevier B.V.

AB - Background and purpose: A planning target volume (PTV) in photon treatments aims to ensure that the clinical target volume (CTV) receives adequate dose despite treatment uncertainties. The underlying static dose cloud approximation (the assumption that the dose distribution is invariant to errors) is problematic in intensity modulated proton treatments where range errors should be taken into account as well. The purpose of this work is to introduce a robustness evaluation method that is applicable to photon and proton treatments and is consistent with (historic) PTV-based treatment plan evaluations.Materials and methods: The limitation of the static dose cloud approximation was solved in a multi-scenario simulation by explicitly calculating doses for various treatment scenarios that describe possible errors in the treatment course. Setup errors were the same as the CTV-PTV margin and the underlying theory of 3D probability density distributions was extended to 4D to include range errors, maintaining a 90% confidence level. Scenario dose distributions were reduced to voxel-wise minimum and maximum dose distributions; the first to evaluate CTV coverage and the second for hot spots. Acceptance criteria for CTV D98 and D2 were calibrated against PTV-based criteria from historic photon treatment plans.Results: CTV D98 in worst case scenario dose and voxel-wise minimum dose showed a very strong correlation with scenario average D98 (R-2 > 0.99). The voxel-wise minimum dose visualised CTV dose conformity and coverage in 3D in agreement with PTV-based evaluation in photon therapy. Criteria for CTV D98 and D2 of the voxel-wise minimum and maximum dose showed very strong correlations to PTV D98 and D2 (R-2 > 0.99) and on average needed corrections of -0.9% and +2.3%, respectively.Conclusions: A practical approach to robustness evaluation was provided and clinically implemented for PTV-less photon and proton treatment planning, consistent with PTV evaluations but without its static dose cloud approximation. (C) 2019 The Authors. Published by Elsevier B.V.

KW - Photon therapy

KW - Proton therapy

KW - Setup error

KW - Range error

KW - Margins

KW - Robustness evaluation

KW - TREATMENT UNCERTAINTIES

KW - OROPHARYNGEAL CANCER

KW - RANGE UNCERTAINTIES

KW - RADIATION-THERAPY

KW - SETUP ERRORS

KW - OPTIMIZATION

KW - SENSITIVITY

KW - MARGINS

KW - IMPT

KW - VMAT

U2 - 10.1016/j.radonc.2019.08.005

DO - 10.1016/j.radonc.2019.08.005

M3 - Article

C2 - 31492443

SN - 0167-8140

VL - 141

SP - 267

EP - 274

JO - Radiotherapy and Oncology

JF - Radiotherapy and Oncology

ER -

Practical robustness evaluation in radiotherapy - A photon and proton-proof alternative to PTV-based plan evaluation

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Keywords

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