Articles producció científica> Ciències Mèdiques Bàsiques

Impact of the dose quantity used in MV photon optimization on dose distribution, robustness, and complexity

  • Dades identificatives

    Identificador: imarina:9241744
    Autors:
    Jurado-Bruggeman, DMuñoz-Montplet, CHernandez, VSaez, JFuentes-Raspall, R
    Resum:
    Purpose Convolution/superposition algorithms used in megavoltage (MV) photon radiotherapy model radiation transport in water, yielding dose to water-in-water (D-w,D-w). Advanced algorithms constitute a step forward, but their dose distributions in terms of dose to medium-in-medium (D-m,D-m) or dose to water-in-medium (D-w,D-m) can be problematic when used in plan optimization due to their different dose responses to some atomic composition heterogeneities. Failure to take this into account can lead to undesired overcorrections and thus to unnoticed suboptimal and unrobust plans. Dose to reference-like medium (D-ref,D-m*) was recently introduced to overcome these limitations while ensuring accurate transport. This work evaluates and compares the performance of these four dose quantities in planning target volume (PTV)-based optimization. Methods We considered three cases with heterogeneities inside the PTV: virtual phantom with water surrounded by bone; head and neck; and lung. These cases were planned with volumetric modulated arc therapy (VMAT) technique, optimizing with the same setup and objectives for each dose quantity. We used different algorithms of the Varian Eclipse treatment planning system (TPS): Acuros XB (AXB) for D-m,D-m and D-w,D-m, and Analytical Anisotropic Algorithm (AAA) for D-w,D-w. D-ref,D-m* was obtained from D-m,D-m distributions using an in-house software considering water as the reference medium (D-w,D-m*). The optimization process consisted of: (1) common first optimization, (2) dose distribution computed for each quantity, (3) re-optimization, and (4) final calculation for each dose quantity. The dose distribution, robustness to patient setup errors, and complexity of the plans were analyzed and compared. Results The quantities showed similar
  • Altres:

    Autor segons l'article: Jurado-Bruggeman, D; Muñoz-Montplet, C; Hernandez, V; Saez, J; Fuentes-Raspall, R
    Departament: Ciències Mèdiques Bàsiques
    Autor/s de la URV: Hernandez Masgrau, Victor
    Paraules clau: Water To-medium Tissue Superposition algorithms Specification Robustness Radiotherapy, intensity-modulated Radiotherapy planning, computer-assisted Radiotherapy dosage Radiotherapy Radiation-therapy Radiation transport Plan quality Photons Phantoms, imaging Optimization Optimisations Metrics Megavoltage photons Humans Dose-to-water Dose-to-reference-like medium Dose-to-medium Dose distributions Convolution/superposition Convolution Carlo-based photon Calculation algorithms Algorithms
    Resum: Purpose Convolution/superposition algorithms used in megavoltage (MV) photon radiotherapy model radiation transport in water, yielding dose to water-in-water (D-w,D-w). Advanced algorithms constitute a step forward, but their dose distributions in terms of dose to medium-in-medium (D-m,D-m) or dose to water-in-medium (D-w,D-m) can be problematic when used in plan optimization due to their different dose responses to some atomic composition heterogeneities. Failure to take this into account can lead to undesired overcorrections and thus to unnoticed suboptimal and unrobust plans. Dose to reference-like medium (D-ref,D-m*) was recently introduced to overcome these limitations while ensuring accurate transport. This work evaluates and compares the performance of these four dose quantities in planning target volume (PTV)-based optimization. Methods We considered three cases with heterogeneities inside the PTV: virtual phantom with water surrounded by bone; head and neck; and lung. These cases were planned with volumetric modulated arc therapy (VMAT) technique, optimizing with the same setup and objectives for each dose quantity. We used different algorithms of the Varian Eclipse treatment planning system (TPS): Acuros XB (AXB) for D-m,D-m and D-w,D-m, and Analytical Anisotropic Algorithm (AAA) for D-w,D-w. D-ref,D-m* was obtained from D-m,D-m distributions using an in-house software considering water as the reference medium (D-w,D-m*). The optimization process consisted of: (1) common first optimization, (2) dose distribution computed for each quantity, (3) re-optimization, and (4) final calculation for each dose quantity. The dose distribution, robustness to patient setup errors, and complexity of the plans were analyzed and compared. Results The quantities showed similar dose distributions after the optimization but differed in terms of plan robustness. The cases with soft tissue and high-density heterogeneities followed the same pattern. For AXB D-m,D-m, cold regions appeared in the heterogeneities after the first optimization. They were compensated in the second optimization through local fluence increases, but any positional mismatch impacted robustness, with clinical target volume (CTV) variations from the nominal scenario around +3% for bone and up to +7% for metal. For AXB D-w,D-m the pattern was inverse (hot regions compensated by fluence decreases) and more pronounced, with CTV dose variations around -7% for bone and up to -17% for metal. Neither AXB D-w,D-m* nor AAA D-w,D-w presented these dose inhomogeneities, which resulted in more robust plans. However, D-w,D-w differed markedly from the other quantities in the lung case because of its lower radiation transport accuracy. AXB D-m,D-m was the most complex of the four dose quantities and AXB D-w,D-m* the least complex, though we observed no major differences in this regard. Conclusions The dose quantity used in MV photon optimization can affect plan robustness. D-w,D-w distributions from convolution/superposition algorithms are robust but may not provide sufficient radiation transport accuracy in some cases. D-m,D-m and D-w,D-m from advanced algorithms can compromise robustness because their different responses to some composition heterogeneities introduce additional fluence compensations.D-ref,D-m* offers advantages in plan optimization and evaluation, producing accurate and robust plans without increasing complexity. D-ref,D-m* can be easily implemented as a built-in feature of the TPS and can facilitate and simplify the treatment planning process when using advanced algorithms. Final reporting can be kept in D-m,D-m or D-w,D-m for clinical correlations.
    Àrees temàtiques: Radiology, nuclear medicine and imaging Radiology, nuclear medicine & medical imaging Medicine (miscellaneous) Medicina ii Medicina i Interdisciplinar General medicine Engenharias iv Engenharias ii Ciências biológicas iii Ciências biológicas ii Ciências biológicas i Ciência da computação Biotecnología Biophysics Astronomia / física Antropologia / arqueologia
    Accès a la llicència d'ús: https://creativecommons.org/licenses/by/3.0/es/
    Adreça de correu electrònic de l'autor: victor.hernandez@urv.cat
    Identificador de l'autor: 0000-0003-3770-8486
    Data d'alta del registre: 2024-09-07
    Versió de l'article dipositat: info:eu-repo/semantics/submittedVersion
    URL Document de llicència: https://repositori.urv.cat/ca/proteccio-de-dades/
    Referència a l'article segons font original: Medical Physics. 49 (1): 648-665
    Referència de l'ítem segons les normes APA: Jurado-Bruggeman, D; Muñoz-Montplet, C; Hernandez, V; Saez, J; Fuentes-Raspall, R (2022). Impact of the dose quantity used in MV photon optimization on dose distribution, robustness, and complexity. Medical Physics, 49(1), 648-665. DOI: 10.1002/mp.15389
    Entitat: Universitat Rovira i Virgili
    Any de publicació de la revista: 2022
    Tipus de publicació: Journal Publications
  • Paraules clau:

    Biophysics,Medicine (Miscellaneous),Radiology, Nuclear Medicine & Medical Imaging,Radiology, Nuclear Medicine and Imaging
    Water
    To-medium
    Tissue
    Superposition algorithms
    Specification
    Robustness
    Radiotherapy, intensity-modulated
    Radiotherapy planning, computer-assisted
    Radiotherapy dosage
    Radiotherapy
    Radiation-therapy
    Radiation transport
    Plan quality
    Photons
    Phantoms, imaging
    Optimization
    Optimisations
    Metrics
    Megavoltage photons
    Humans
    Dose-to-water
    Dose-to-reference-like medium
    Dose-to-medium
    Dose distributions
    Convolution/superposition
    Convolution
    Carlo-based photon
    Calculation algorithms
    Algorithms
    Radiology, nuclear medicine and imaging
    Radiology, nuclear medicine & medical imaging
    Medicine (miscellaneous)
    Medicina ii
    Medicina i
    Interdisciplinar
    General medicine
    Engenharias iv
    Engenharias ii
    Ciências biológicas iii
    Ciências biológicas ii
    Ciências biológicas i
    Ciência da computação
    Biotecnología
    Biophysics
    Astronomia / física
    Antropologia / arqueologia
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