A single-field integrated boost treatment planning technique for spot scanning proton therapy

PURPOSE: Intensity modulated proton therapy (IMPT) plans are normally generated utilizing multiple field optimization (MFO) techniques. Similar to photon based IMRT, MFO allows for the utilization of a simultaneous integrated boost in which multiple target volumes are treated to discrete doses simul...

Descripción completa

Detalles Bibliográficos
Autores principales: Zhu, Xiaorong Ronald, Poenisch, Falk, Li, Heng, Zhang, Xiaodong, Sahoo, Narayan, Wu, Richard Y, Li, Xiaoqiang, Lee, Andrew K, Chang, Eric L, Choi, Seungtaek, Pugh, Thomas, Frank, Steven J, Gillin, Michael T, Mahajan, Anita, Grosshans, David R
Formato: Online Artículo Texto
Lenguaje:English
Publicado: BioMed Central 2014
Materias:
Methodology
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4262206/
https://www.ncbi.nlm.nih.gov/pubmed/25212571
http://dx.doi.org/10.1186/1748-717X-9-202
_version_ 1782348396123652096
author Zhu, Xiaorong Ronald
Poenisch, Falk
Li, Heng
Zhang, Xiaodong
Sahoo, Narayan
Wu, Richard Y
Li, Xiaoqiang
Lee, Andrew K
Chang, Eric L
Choi, Seungtaek
Pugh, Thomas
Frank, Steven J
Gillin, Michael T
Mahajan, Anita
Grosshans, David R
author_facet Zhu, Xiaorong Ronald
Poenisch, Falk
Li, Heng
Zhang, Xiaodong
Sahoo, Narayan
Wu, Richard Y
Li, Xiaoqiang
Lee, Andrew K
Chang, Eric L
Choi, Seungtaek
Pugh, Thomas
Frank, Steven J
Gillin, Michael T
Mahajan, Anita
Grosshans, David R
author_sort Zhu, Xiaorong Ronald
collection PubMed
description PURPOSE: Intensity modulated proton therapy (IMPT) plans are normally generated utilizing multiple field optimization (MFO) techniques. Similar to photon based IMRT, MFO allows for the utilization of a simultaneous integrated boost in which multiple target volumes are treated to discrete doses simultaneously, potentially improving plan quality and streamlining quality assurance and treatment delivery. However, MFO may render plans more sensitive to the physical uncertainties inherent to particle therapy. Here we present clinical examples of a single-field integrated boost (SFIB) technique for spot scanning proton therapy based on single field optimization (SFO) treatment-planning techniques. METHODS AND MATERIALS: We designed plans of each type for illustrative patients with central nervous system (brain and spine), prostate and head and neck malignancies. SFIB and IMPT plans were constructed to deliver multiple prescription dose levels to multiple targets using SFO or MFO, respectively. Dose and fractionation schemes were based on the current clinical practice using X-ray IMRT in our clinic. For inverse planning, dose constraints were employed to achieve the desired target coverage and normal tissue sparing. Conformality and inhomogeneity indices were calculated to quantify plan quality. We also compared the worst-case robustness of the SFIB, sequential boost SFUD, and IMPT plans. RESULTS: The SFIB technique produced more conformal dose distributions than plans generated by sequential boost using a SFUD technique (conformality index for prescription isodose levels; 0.585 ± 0.30 vs. 0.435 ± 0.24, SFIB vs. SFUD respectively, Wilcoxon matched-pair signed rank test, p < 0.01). There was no difference in the conformality index between SFIB and IMPT plans (0.638 ± 0.27 vs. 0.633 ± 0.26, SFIB vs. IMPT, respectively). Heterogeneity between techniques was not significantly different. With respect to clinical metrics, SFIB plans proved more robust than the corresponding IMPT plans. CONCLUSIONS: SFIB technique for scanning beam proton therapy (SSPT) is now routinely employed in our clinic. The SFIB technique is a natural application of SFO and offers several advantages over SFUD, including more conformal plans, seamless treatment delivery and more efficient planning and QA. SFIB may be more robust than IMPT and has been the treatment planning technique of choice for some patients.
format Online
Article
Text
id pubmed-4262206
institution National Center for Biotechnology Information
language English
publishDate 2014
publisher BioMed Central
record_format MEDLINE/PubMed
spelling pubmed-42622062014-12-11 A single-field integrated boost treatment planning technique for spot scanning proton therapy Zhu, Xiaorong Ronald Poenisch, Falk Li, Heng Zhang, Xiaodong Sahoo, Narayan Wu, Richard Y Li, Xiaoqiang Lee, Andrew K Chang, Eric L Choi, Seungtaek Pugh, Thomas Frank, Steven J Gillin, Michael T Mahajan, Anita Grosshans, David R Radiat Oncol Methodology PURPOSE: Intensity modulated proton therapy (IMPT) plans are normally generated utilizing multiple field optimization (MFO) techniques. Similar to photon based IMRT, MFO allows for the utilization of a simultaneous integrated boost in which multiple target volumes are treated to discrete doses simultaneously, potentially improving plan quality and streamlining quality assurance and treatment delivery. However, MFO may render plans more sensitive to the physical uncertainties inherent to particle therapy. Here we present clinical examples of a single-field integrated boost (SFIB) technique for spot scanning proton therapy based on single field optimization (SFO) treatment-planning techniques. METHODS AND MATERIALS: We designed plans of each type for illustrative patients with central nervous system (brain and spine), prostate and head and neck malignancies. SFIB and IMPT plans were constructed to deliver multiple prescription dose levels to multiple targets using SFO or MFO, respectively. Dose and fractionation schemes were based on the current clinical practice using X-ray IMRT in our clinic. For inverse planning, dose constraints were employed to achieve the desired target coverage and normal tissue sparing. Conformality and inhomogeneity indices were calculated to quantify plan quality. We also compared the worst-case robustness of the SFIB, sequential boost SFUD, and IMPT plans. RESULTS: The SFIB technique produced more conformal dose distributions than plans generated by sequential boost using a SFUD technique (conformality index for prescription isodose levels; 0.585 ± 0.30 vs. 0.435 ± 0.24, SFIB vs. SFUD respectively, Wilcoxon matched-pair signed rank test, p < 0.01). There was no difference in the conformality index between SFIB and IMPT plans (0.638 ± 0.27 vs. 0.633 ± 0.26, SFIB vs. IMPT, respectively). Heterogeneity between techniques was not significantly different. With respect to clinical metrics, SFIB plans proved more robust than the corresponding IMPT plans. CONCLUSIONS: SFIB technique for scanning beam proton therapy (SSPT) is now routinely employed in our clinic. The SFIB technique is a natural application of SFO and offers several advantages over SFUD, including more conformal plans, seamless treatment delivery and more efficient planning and QA. SFIB may be more robust than IMPT and has been the treatment planning technique of choice for some patients. BioMed Central 2014-09-11 /pmc/articles/PMC4262206/ /pubmed/25212571 http://dx.doi.org/10.1186/1748-717X-9-202 Text en © Zhu et al.; licensee BioMed Central Ltd. 2014 This article is published under license to BioMed Central Ltd. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly credited. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.
spellingShingle Methodology
Zhu, Xiaorong Ronald
Poenisch, Falk
Li, Heng
Zhang, Xiaodong
Sahoo, Narayan
Wu, Richard Y
Li, Xiaoqiang
Lee, Andrew K
Chang, Eric L
Choi, Seungtaek
Pugh, Thomas
Frank, Steven J
Gillin, Michael T
Mahajan, Anita
Grosshans, David R
A single-field integrated boost treatment planning technique for spot scanning proton therapy
title A single-field integrated boost treatment planning technique for spot scanning proton therapy
title_full A single-field integrated boost treatment planning technique for spot scanning proton therapy
title_fullStr A single-field integrated boost treatment planning technique for spot scanning proton therapy
title_full_unstemmed A single-field integrated boost treatment planning technique for spot scanning proton therapy
title_short A single-field integrated boost treatment planning technique for spot scanning proton therapy
title_sort single-field integrated boost treatment planning technique for spot scanning proton therapy
topic Methodology
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4262206/
https://www.ncbi.nlm.nih.gov/pubmed/25212571
http://dx.doi.org/10.1186/1748-717X-9-202
work_keys_str_mv AT zhuxiaorongronald asinglefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT poenischfalk asinglefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT liheng asinglefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT zhangxiaodong asinglefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT sahoonarayan asinglefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT wurichardy asinglefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT lixiaoqiang asinglefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT leeandrewk asinglefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT changericl asinglefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT choiseungtaek asinglefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT pughthomas asinglefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT frankstevenj asinglefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT gillinmichaelt asinglefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT mahajananita asinglefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT grosshansdavidr asinglefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT zhuxiaorongronald singlefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT poenischfalk singlefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT liheng singlefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT zhangxiaodong singlefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT sahoonarayan singlefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT wurichardy singlefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT lixiaoqiang singlefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT leeandrewk singlefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT changericl singlefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT choiseungtaek singlefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT pughthomas singlefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT frankstevenj singlefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT gillinmichaelt singlefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT mahajananita singlefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy
AT grosshansdavidr singlefieldintegratedboosttreatmentplanningtechniqueforspotscanningprotontherapy

Ejemplares similares