Long‐term stability assessment of a 4D tumor tracking system integrated into a gimbaled linear accelerator

We assessed long‐term stability of tracking accuracy using the Vero4DRT system. This metric was observed between September 2012 and March 2015. A programmable respiratory motion phantom, designed to move phantoms synchronously with respiratory surrogates, was used. The infrared (IR) markers moved in...

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Autores principales: Akimoto, Mami, Nakamura, Mitsuhiro, Miyabe, Yuki, Mukumoto, Nobutaka, Yokota, Kenji, Mizowaki, Takashi, Hiraoka, Masahiro
Formato: Online Artículo Texto
Lenguaje:English
Publicado: John Wiley and Sons Inc. 2015
Materias:
Radiation Oncology Physics
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5690148/
https://www.ncbi.nlm.nih.gov/pubmed/26699328
http://dx.doi.org/10.1120/jacmp.v16i5.5679
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author Akimoto, Mami
Nakamura, Mitsuhiro
Miyabe, Yuki
Mukumoto, Nobutaka
Yokota, Kenji
Mizowaki, Takashi
Hiraoka, Masahiro
author_facet Akimoto, Mami
Nakamura, Mitsuhiro
Miyabe, Yuki
Mukumoto, Nobutaka
Yokota, Kenji
Mizowaki, Takashi
Hiraoka, Masahiro
author_sort Akimoto, Mami
collection PubMed
description We assessed long‐term stability of tracking accuracy using the Vero4DRT system. This metric was observed between September 2012 and March 2015. A programmable respiratory motion phantom, designed to move phantoms synchronously with respiratory surrogates, was used. The infrared (IR) markers moved in the anterior–posterior (AP) direction as respiratory surrogates, while a cube phantom with a steel ball at the center, representing the tumor, and with radiopaque markers around it moved in the superior–inferior (SI) direction with one‐dimensional (1D) sinusoidal patterns. A correlation model between the tumor and IR marker motion (4D model) was created from the training data obtained for 20 s just before beam delivery. The irradiation field was set to [Formula: see text] and 300 monitor units (MUs) of desired MV X‐ray beam were delivered. The gantry and ring angles were set to 0° and 45°, respectively. During beam delivery, the system recorded approximately 60 electronic portal imaging device (EPID) images. We analyzed: 1) the predictive accuracy of the 4D model ([Formula: see text]), defined as the difference between the detected and predicted target positions during 4D model creation, and 2) the tracking accuracy ([Formula: see text]), defined as the difference between the center of the steel ball and the MV X‐ray field on the EPID image. The median values of mean plus two standard deviations (SDs) for [Formula: see text] were 0.06, 0.35, and 0.06 mm in the left–right (LR), SI, and AP directions, respectively. The mean values of maximum deviation for [Formula: see text] were 0.38, 0.49, and 0.53 mm and the coefficients of variance (CV) were 0.16, 0.10, and 0.05 in lateral, longitudinal, and 2D directions, respectively. Consequently, the IR Tracking accuracy was consistent over a period of two years. Our proposed method assessed the overall tracking accuracy readily using real‐time EPID images, and proved to be a useful QA tool for dynamic tumor tracking with the Vero4DRT system. PACS number: 87.59.‐e, 88.10.gc, 87.55.Qr
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spelling pubmed-56901482018-04-02 Long‐term stability assessment of a 4D tumor tracking system integrated into a gimbaled linear accelerator Akimoto, Mami Nakamura, Mitsuhiro Miyabe, Yuki Mukumoto, Nobutaka Yokota, Kenji Mizowaki, Takashi Hiraoka, Masahiro J Appl Clin Med Phys Radiation Oncology Physics We assessed long‐term stability of tracking accuracy using the Vero4DRT system. This metric was observed between September 2012 and March 2015. A programmable respiratory motion phantom, designed to move phantoms synchronously with respiratory surrogates, was used. The infrared (IR) markers moved in the anterior–posterior (AP) direction as respiratory surrogates, while a cube phantom with a steel ball at the center, representing the tumor, and with radiopaque markers around it moved in the superior–inferior (SI) direction with one‐dimensional (1D) sinusoidal patterns. A correlation model between the tumor and IR marker motion (4D model) was created from the training data obtained for 20 s just before beam delivery. The irradiation field was set to [Formula: see text] and 300 monitor units (MUs) of desired MV X‐ray beam were delivered. The gantry and ring angles were set to 0° and 45°, respectively. During beam delivery, the system recorded approximately 60 electronic portal imaging device (EPID) images. We analyzed: 1) the predictive accuracy of the 4D model ([Formula: see text]), defined as the difference between the detected and predicted target positions during 4D model creation, and 2) the tracking accuracy ([Formula: see text]), defined as the difference between the center of the steel ball and the MV X‐ray field on the EPID image. The median values of mean plus two standard deviations (SDs) for [Formula: see text] were 0.06, 0.35, and 0.06 mm in the left–right (LR), SI, and AP directions, respectively. The mean values of maximum deviation for [Formula: see text] were 0.38, 0.49, and 0.53 mm and the coefficients of variance (CV) were 0.16, 0.10, and 0.05 in lateral, longitudinal, and 2D directions, respectively. Consequently, the IR Tracking accuracy was consistent over a period of two years. Our proposed method assessed the overall tracking accuracy readily using real‐time EPID images, and proved to be a useful QA tool for dynamic tumor tracking with the Vero4DRT system. PACS number: 87.59.‐e, 88.10.gc, 87.55.Qr John Wiley and Sons Inc. 2015-09-08 /pmc/articles/PMC5690148/ /pubmed/26699328 http://dx.doi.org/10.1120/jacmp.v16i5.5679 Text en © 2015 The Authors. This is an open access article under the terms of the Creative Commons Attribution (http://creativecommons.org/licenses/by/3.0/) License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.
spellingShingle Radiation Oncology Physics
Akimoto, Mami
Nakamura, Mitsuhiro
Miyabe, Yuki
Mukumoto, Nobutaka
Yokota, Kenji
Mizowaki, Takashi
Hiraoka, Masahiro
Long‐term stability assessment of a 4D tumor tracking system integrated into a gimbaled linear accelerator
title Long‐term stability assessment of a 4D tumor tracking system integrated into a gimbaled linear accelerator
title_full Long‐term stability assessment of a 4D tumor tracking system integrated into a gimbaled linear accelerator
title_fullStr Long‐term stability assessment of a 4D tumor tracking system integrated into a gimbaled linear accelerator
title_full_unstemmed Long‐term stability assessment of a 4D tumor tracking system integrated into a gimbaled linear accelerator
title_short Long‐term stability assessment of a 4D tumor tracking system integrated into a gimbaled linear accelerator
title_sort long‐term stability assessment of a 4d tumor tracking system integrated into a gimbaled linear accelerator
topic Radiation Oncology Physics
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5690148/
https://www.ncbi.nlm.nih.gov/pubmed/26699328
http://dx.doi.org/10.1120/jacmp.v16i5.5679
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