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Prostate rotation detected from implanted markers can affect dose coverage and cannot be simply dismissed

With implanted markers, daily prostate displacements can be automatically detected with six degrees of freedom. The reported magnitudes of the rotations, however, are often greater than the typical range of a six‐degree treatment couch. The purpose of this study is to quantify geometric and dosimetr...

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Autores principales: Shang, Qingyang, Olsen, Lawrence J Sheplan, Stephans, Kevin, Tendulkar, Rahul, Xia, Ping
Formato: Online Artículo Texto
Lenguaje:English
Publicado: John Wiley and Sons Inc. 2013
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5714427/
https://www.ncbi.nlm.nih.gov/pubmed/23652257
http://dx.doi.org/10.1120/jacmp.v14i3.4262
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author Shang, Qingyang
Olsen, Lawrence J Sheplan
Stephans, Kevin
Tendulkar, Rahul
Xia, Ping
author_facet Shang, Qingyang
Olsen, Lawrence J Sheplan
Stephans, Kevin
Tendulkar, Rahul
Xia, Ping
author_sort Shang, Qingyang
collection PubMed
description With implanted markers, daily prostate displacements can be automatically detected with six degrees of freedom. The reported magnitudes of the rotations, however, are often greater than the typical range of a six‐degree treatment couch. The purpose of this study is to quantify geometric and dosimetric effects if the prostate rotations are not corrected (ROT_NC) and if they can be compensated with translational shifts (ROT_C). Forty‐three kilovoltage cone‐beam CTs (KV‐CBCT) with implanted markers from five patients were available for this retrospective study. On each KV‐CBCT, the prostate, bladder, and rectum were manually contoured by a physician. The prostate contours from the planning CT and CBCT were aligned manually to achieve the best overlaps. This contour registration served as the benchmark method for comparison with two marker registration methods: (a) using six degrees of freedom, but rotations were not corrected (ROT_NC); and (b) using three degrees of freedom while compensating rotations into the translational shifts (ROT_C). The center of mass distance (CMD) and overlap index (OI) were used to evaluate these two methods. The dosimetric effects were also analyzed by comparing the dose coverage of the prostate clinical target volume (CTV) in relation to the planning margins. According to our analysis, the detected rotations dominated in the left–right axis with systematic and random components of 4.6° and 4.1°, respectively. When the rotation angles were greater than 10°, the differences in CMD between the two registrations were greater than 5 mm in 85.7% of these fractions; when the rotation angles were greater than 6°, the differences of CMD were greater than 4 mm in 61.1% of these fractions. With 6 mm/4 mm posterior planning margins, the average difference between the dose to 99% (D99) of the prostate in CBCTs and the planning D99 of the prostate was [Formula: see text] for the ROT_NC registration, and [Formula: see text] for the ROT_C registration [Formula: see text]. When the planning margin decreased to 4 mm/2 mm posterior, the average difference in D99 of the prostate was [Formula: see text] and [Formula: see text] for the ROT_NC and ROT_C methods, respectively [Formula: see text]. In conclusion, prostate rotation cannot be simply dismissed, and the impact of the rotational errors depends on the distance between the isocenter and the centroid of implanted markers and the rotation angle. PACS number: 87.55
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spelling pubmed-57144272018-04-02 Prostate rotation detected from implanted markers can affect dose coverage and cannot be simply dismissed Shang, Qingyang Olsen, Lawrence J Sheplan Stephans, Kevin Tendulkar, Rahul Xia, Ping J Appl Clin Med Phys Radiation Oncology Physics With implanted markers, daily prostate displacements can be automatically detected with six degrees of freedom. The reported magnitudes of the rotations, however, are often greater than the typical range of a six‐degree treatment couch. The purpose of this study is to quantify geometric and dosimetric effects if the prostate rotations are not corrected (ROT_NC) and if they can be compensated with translational shifts (ROT_C). Forty‐three kilovoltage cone‐beam CTs (KV‐CBCT) with implanted markers from five patients were available for this retrospective study. On each KV‐CBCT, the prostate, bladder, and rectum were manually contoured by a physician. The prostate contours from the planning CT and CBCT were aligned manually to achieve the best overlaps. This contour registration served as the benchmark method for comparison with two marker registration methods: (a) using six degrees of freedom, but rotations were not corrected (ROT_NC); and (b) using three degrees of freedom while compensating rotations into the translational shifts (ROT_C). The center of mass distance (CMD) and overlap index (OI) were used to evaluate these two methods. The dosimetric effects were also analyzed by comparing the dose coverage of the prostate clinical target volume (CTV) in relation to the planning margins. According to our analysis, the detected rotations dominated in the left–right axis with systematic and random components of 4.6° and 4.1°, respectively. When the rotation angles were greater than 10°, the differences in CMD between the two registrations were greater than 5 mm in 85.7% of these fractions; when the rotation angles were greater than 6°, the differences of CMD were greater than 4 mm in 61.1% of these fractions. With 6 mm/4 mm posterior planning margins, the average difference between the dose to 99% (D99) of the prostate in CBCTs and the planning D99 of the prostate was [Formula: see text] for the ROT_NC registration, and [Formula: see text] for the ROT_C registration [Formula: see text]. When the planning margin decreased to 4 mm/2 mm posterior, the average difference in D99 of the prostate was [Formula: see text] and [Formula: see text] for the ROT_NC and ROT_C methods, respectively [Formula: see text]. In conclusion, prostate rotation cannot be simply dismissed, and the impact of the rotational errors depends on the distance between the isocenter and the centroid of implanted markers and the rotation angle. PACS number: 87.55 John Wiley and Sons Inc. 2013-05-06 /pmc/articles/PMC5714427/ /pubmed/23652257 http://dx.doi.org/10.1120/jacmp.v14i3.4262 Text en © 2013 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
Shang, Qingyang
Olsen, Lawrence J Sheplan
Stephans, Kevin
Tendulkar, Rahul
Xia, Ping
Prostate rotation detected from implanted markers can affect dose coverage and cannot be simply dismissed
title Prostate rotation detected from implanted markers can affect dose coverage and cannot be simply dismissed
title_full Prostate rotation detected from implanted markers can affect dose coverage and cannot be simply dismissed
title_fullStr Prostate rotation detected from implanted markers can affect dose coverage and cannot be simply dismissed
title_full_unstemmed Prostate rotation detected from implanted markers can affect dose coverage and cannot be simply dismissed
title_short Prostate rotation detected from implanted markers can affect dose coverage and cannot be simply dismissed
title_sort prostate rotation detected from implanted markers can affect dose coverage and cannot be simply dismissed
topic Radiation Oncology Physics
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5714427/
https://www.ncbi.nlm.nih.gov/pubmed/23652257
http://dx.doi.org/10.1120/jacmp.v14i3.4262
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