An analytical dose‐averaged LET calculation algorithm considering the off‐axis LET enhancement by secondary protons for spot‐scanning proton therapy

Purpose To evaluate the biological effects of proton beams as part of daily clinical routine, fast and accurate calculation of dose‐averaged linear energy transfer (LETd) is required. In this study, we have developed the analytical LETd calculation method based on the pencil‐beam algorithm (PBA) con...

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Published in:Medical physics (Lancaster) 2018-07, Vol.45 (7), p.3404-3416
Main Authors: Hirayama, Shusuke, Matsuura, Taeko, Ueda, Hideaki, Fujii, Yusuke, Fujii, Takaaki, Takao, Seishin, Miyamoto, Naoki, Shimizu, Shinichi, Fujimoto, Rintaro, Umegaki, Kikuo, Shirato, Hiroki
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Language:English
Subjects:
Algorithms
Computer Simulation
Humans
Linear Energy Transfer
Liver - radiation effects
Lung - radiation effects
Male
Monte Carlo Method
Organs at Risk
pencil beam algorithm
Prostate - radiation effects
proton
Proton Therapy - instrumentation
Proton Therapy - methods
Protons - therapeutic use
Radiotherapy Dosage
Radiotherapy Planning, Computer-Assisted - instrumentation
Radiotherapy Planning, Computer-Assisted - methods
spot scanning
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container_end_page 3416
container_issue 7
container_start_page 3404
container_title Medical physics (Lancaster)
container_volume 45
creator Hirayama, Shusuke
Matsuura, Taeko
Ueda, Hideaki
Fujii, Yusuke
Fujii, Takaaki
Takao, Seishin
Miyamoto, Naoki
Shimizu, Shinichi
Fujimoto, Rintaro
Umegaki, Kikuo
Shirato, Hiroki
description Purpose To evaluate the biological effects of proton beams as part of daily clinical routine, fast and accurate calculation of dose‐averaged linear energy transfer (LETd) is required. In this study, we have developed the analytical LETd calculation method based on the pencil‐beam algorithm (PBA) considering the off‐axis enhancement by secondary protons. This algorithm (PBA‐dLET) was then validated using Monte Carlo simulation (MCS) results. Methods In PBA‐dLET, LET values were assigned separately for each individual dose kernel based on the PBA. For the dose kernel, we employed a triple Gaussian model which consists of the primary component (protons that undergo the multiple Coulomb scattering) and the halo component (protons that undergo inelastic, nonelastic and elastic nuclear reaction); the primary and halo components were represented by a single Gaussian and the sum of two Gaussian distributions, respectively. Although the previous analytical approaches assumed a constant LETd value for the lateral distribution of a pencil beam, the actual LETd increases away from the beam axis, because there are more scattered and therefore lower energy protons with higher stopping powers. To reflect this LETd behavior, we have assumed that the LETs of primary and halo components can take different values (LETp and LEThalo), which vary only along the depth direction. The values of dual‐LET kernels were determined such that the PBA‐dLET reproduced the MCS‐generated LETd distribution in both small and large fields. These values were generated at intervals of 1 mm in depth for 96 energies from 70.2 to 220 MeV and collected in the look‐up table. Finally, we compared the LETd distributions and mean LETd (LETd,mean) values of targets and organs at risk between PBA‐dLET and MCS. Both homogeneous phantom and patient geometries (prostate, liver, and lung cases) were used to validate the present method. Results In the homogeneous phantom, the LETd profiles obtained by the dual‐LET kernels agree well with the MCS results except for the low‐dose region in the lateral penumbra, where the actual dose was below 10% of the maximum dose. In the patient geometry, the LETd profiles calculated with the developed method reproduces MCS with the similar accuracy as in the homogeneous phantom. The maximum differences in LETd,mean for each structure between the PBA‐dLET and the MCS were 0.06 keV/μm in homogeneous phantoms and 0.08 keV/μm in patient geometries under all tested conditions, res
doi_str_mv 10.1002/mp.12991
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In this study, we have developed the analytical LETd calculation method based on the pencil‐beam algorithm (PBA) considering the off‐axis enhancement by secondary protons. This algorithm (PBA‐dLET) was then validated using Monte Carlo simulation (MCS) results. Methods In PBA‐dLET, LET values were assigned separately for each individual dose kernel based on the PBA. For the dose kernel, we employed a triple Gaussian model which consists of the primary component (protons that undergo the multiple Coulomb scattering) and the halo component (protons that undergo inelastic, nonelastic and elastic nuclear reaction); the primary and halo components were represented by a single Gaussian and the sum of two Gaussian distributions, respectively. Although the previous analytical approaches assumed a constant LETd value for the lateral distribution of a pencil beam, the actual LETd increases away from the beam axis, because there are more scattered and therefore lower energy protons with higher stopping powers. To reflect this LETd behavior, we have assumed that the LETs of primary and halo components can take different values (LETp and LEThalo), which vary only along the depth direction. The values of dual‐LET kernels were determined such that the PBA‐dLET reproduced the MCS‐generated LETd distribution in both small and large fields. These values were generated at intervals of 1 mm in depth for 96 energies from 70.2 to 220 MeV and collected in the look‐up table. Finally, we compared the LETd distributions and mean LETd (LETd,mean) values of targets and organs at risk between PBA‐dLET and MCS. Both homogeneous phantom and patient geometries (prostate, liver, and lung cases) were used to validate the present method. Results In the homogeneous phantom, the LETd profiles obtained by the dual‐LET kernels agree well with the MCS results except for the low‐dose region in the lateral penumbra, where the actual dose was below 10% of the maximum dose. In the patient geometry, the LETd profiles calculated with the developed method reproduces MCS with the similar accuracy as in the homogeneous phantom. The maximum differences in LETd,mean for each structure between the PBA‐dLET and the MCS were 0.06 keV/μm in homogeneous phantoms and 0.08 keV/μm in patient geometries under all tested conditions, respectively. Conclusions We confirmed that the dual‐LET‐kernel model well reproduced the MCS, not only in the homogeneous phantom but also in complex patient geometries. The accuracy of the LETd was largely improved from the single‐LET‐kernel model, especially at the lateral penumbra. The model is expected to be useful, especially for proper recognition of the risk of side effects when the target is next to critical organs.</description><identifier>ISSN: 0094-2405</identifier><identifier>EISSN: 2473-4209</identifier><identifier>DOI: 10.1002/mp.12991</identifier><identifier>PMID: 29788552</identifier><language>eng</language><publisher>United States</publisher><subject>Algorithms ; Computer Simulation ; Humans ; Linear Energy Transfer ; Liver - radiation effects ; Lung - radiation effects ; Male ; Monte Carlo Method ; Organs at Risk ; pencil beam algorithm ; Prostate - radiation effects ; proton ; Proton Therapy - instrumentation ; Proton Therapy - methods ; Protons - therapeutic use ; Radiotherapy Dosage ; Radiotherapy Planning, Computer-Assisted - instrumentation ; Radiotherapy Planning, Computer-Assisted - methods ; spot scanning</subject><ispartof>Medical physics (Lancaster), 2018-07, Vol.45 (7), p.3404-3416</ispartof><rights>2018 American Association of Physicists in Medicine</rights><rights>2018 American Association of Physicists in Medicine.</rights><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-c3871-9d9187818ee8e142eccf52b7d124a57d6097af26c4f30b6ed5a1457d153da6a53</citedby><cites>FETCH-LOGICAL-c3871-9d9187818ee8e142eccf52b7d124a57d6097af26c4f30b6ed5a1457d153da6a53</cites></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>314,780,784,27924,27925</link.rule.ids><backlink>$$Uhttps://www.ncbi.nlm.nih.gov/pubmed/29788552$$D View this record in MEDLINE/PubMed$$Hfree_for_read</backlink></links><search><creatorcontrib>Hirayama, Shusuke</creatorcontrib><creatorcontrib>Matsuura, Taeko</creatorcontrib><creatorcontrib>Ueda, Hideaki</creatorcontrib><creatorcontrib>Fujii, Yusuke</creatorcontrib><creatorcontrib>Fujii, Takaaki</creatorcontrib><creatorcontrib>Takao, Seishin</creatorcontrib><creatorcontrib>Miyamoto, Naoki</creatorcontrib><creatorcontrib>Shimizu, Shinichi</creatorcontrib><creatorcontrib>Fujimoto, Rintaro</creatorcontrib><creatorcontrib>Umegaki, Kikuo</creatorcontrib><creatorcontrib>Shirato, Hiroki</creatorcontrib><title>An analytical dose‐averaged LET calculation algorithm considering the off‐axis LET enhancement by secondary protons for spot‐scanning proton therapy</title><title>Medical physics (Lancaster)</title><addtitle>Med Phys</addtitle><description>Purpose To evaluate the biological effects of proton beams as part of daily clinical routine, fast and accurate calculation of dose‐averaged linear energy transfer (LETd) is required. In this study, we have developed the analytical LETd calculation method based on the pencil‐beam algorithm (PBA) considering the off‐axis enhancement by secondary protons. This algorithm (PBA‐dLET) was then validated using Monte Carlo simulation (MCS) results. Methods In PBA‐dLET, LET values were assigned separately for each individual dose kernel based on the PBA. For the dose kernel, we employed a triple Gaussian model which consists of the primary component (protons that undergo the multiple Coulomb scattering) and the halo component (protons that undergo inelastic, nonelastic and elastic nuclear reaction); the primary and halo components were represented by a single Gaussian and the sum of two Gaussian distributions, respectively. Although the previous analytical approaches assumed a constant LETd value for the lateral distribution of a pencil beam, the actual LETd increases away from the beam axis, because there are more scattered and therefore lower energy protons with higher stopping powers. To reflect this LETd behavior, we have assumed that the LETs of primary and halo components can take different values (LETp and LEThalo), which vary only along the depth direction. The values of dual‐LET kernels were determined such that the PBA‐dLET reproduced the MCS‐generated LETd distribution in both small and large fields. These values were generated at intervals of 1 mm in depth for 96 energies from 70.2 to 220 MeV and collected in the look‐up table. Finally, we compared the LETd distributions and mean LETd (LETd,mean) values of targets and organs at risk between PBA‐dLET and MCS. Both homogeneous phantom and patient geometries (prostate, liver, and lung cases) were used to validate the present method. Results In the homogeneous phantom, the LETd profiles obtained by the dual‐LET kernels agree well with the MCS results except for the low‐dose region in the lateral penumbra, where the actual dose was below 10% of the maximum dose. In the patient geometry, the LETd profiles calculated with the developed method reproduces MCS with the similar accuracy as in the homogeneous phantom. The maximum differences in LETd,mean for each structure between the PBA‐dLET and the MCS were 0.06 keV/μm in homogeneous phantoms and 0.08 keV/μm in patient geometries under all tested conditions, respectively. Conclusions We confirmed that the dual‐LET‐kernel model well reproduced the MCS, not only in the homogeneous phantom but also in complex patient geometries. The accuracy of the LETd was largely improved from the single‐LET‐kernel model, especially at the lateral penumbra. The model is expected to be useful, especially for proper recognition of the risk of side effects when the target is next to critical organs.</description><subject>Algorithms</subject><subject>Computer Simulation</subject><subject>Humans</subject><subject>Linear Energy Transfer</subject><subject>Liver - radiation effects</subject><subject>Lung - radiation effects</subject><subject>Male</subject><subject>Monte Carlo Method</subject><subject>Organs at Risk</subject><subject>pencil beam algorithm</subject><subject>Prostate - radiation effects</subject><subject>proton</subject><subject>Proton Therapy - instrumentation</subject><subject>Proton Therapy - methods</subject><subject>Protons - therapeutic use</subject><subject>Radiotherapy Dosage</subject><subject>Radiotherapy Planning, Computer-Assisted - instrumentation</subject><subject>Radiotherapy Planning, Computer-Assisted - methods</subject><subject>spot scanning</subject><issn>0094-2405</issn><issn>2473-4209</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2018</creationdate><recordtype>article</recordtype><recordid>eNp1kcFO3DAQhq2qqGwBiSeofOwlYDt24hwRohRpKzjQczRrT3ZdJXZqZ0tz4xF67uP1SfCy0J56sjT-_m80M4SccnbGGRPnw3jGRdPwN2QhZF0WUrDmLVkw1shCSKYOyfuUvjHGqlKxd-RQNLXWSokF-X3hKXjo58kZ6KkNCf88_oIfGGGNli6v7mmum20PkwsZ7dchumkzUBN8chaj82s6bZCGrtsFf7r0HEK_AW9wQD_R1UwTZt5CnOkYw5SjtAuRpjFMOZQMeL_z7P92ugjjfEwOOugTnry8R-Trp6v7y8_F8vb65vJiWZhS17xobMN1rblG1MilQGM6JVa15UKCqm3Fmho6URnZlWxVoVXAZa5zVVqoQJVH5OPem9t_32Ka2sElg30PHsM2tYLJkmud9_sPNTGkFLFrx-iGPFbLWbu7RDuM7fMlMvrhxbpdDWj_gq-rz0CxBx5cj_N_Re2Xu73wCXIql7c</recordid><startdate>201807</startdate><enddate>201807</enddate><creator>Hirayama, Shusuke</creator><creator>Matsuura, Taeko</creator><creator>Ueda, Hideaki</creator><creator>Fujii, Yusuke</creator><creator>Fujii, Takaaki</creator><creator>Takao, Seishin</creator><creator>Miyamoto, Naoki</creator><creator>Shimizu, Shinichi</creator><creator>Fujimoto, Rintaro</creator><creator>Umegaki, Kikuo</creator><creator>Shirato, Hiroki</creator><scope>CGR</scope><scope>CUY</scope><scope>CVF</scope><scope>ECM</scope><scope>EIF</scope><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7X8</scope></search><sort><creationdate>201807</creationdate><title>An analytical dose‐averaged LET calculation algorithm considering the off‐axis LET enhancement by secondary protons for spot‐scanning proton therapy</title><author>Hirayama, Shusuke ; Matsuura, Taeko ; Ueda, Hideaki ; Fujii, Yusuke ; Fujii, Takaaki ; Takao, Seishin ; Miyamoto, Naoki ; Shimizu, Shinichi ; Fujimoto, Rintaro ; Umegaki, Kikuo ; Shirato, Hiroki</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c3871-9d9187818ee8e142eccf52b7d124a57d6097af26c4f30b6ed5a1457d153da6a53</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2018</creationdate><topic>Algorithms</topic><topic>Computer Simulation</topic><topic>Humans</topic><topic>Linear Energy Transfer</topic><topic>Liver - radiation effects</topic><topic>Lung - radiation effects</topic><topic>Male</topic><topic>Monte Carlo Method</topic><topic>Organs at Risk</topic><topic>pencil beam algorithm</topic><topic>Prostate - radiation effects</topic><topic>proton</topic><topic>Proton Therapy - instrumentation</topic><topic>Proton Therapy - methods</topic><topic>Protons - therapeutic use</topic><topic>Radiotherapy Dosage</topic><topic>Radiotherapy Planning, Computer-Assisted - instrumentation</topic><topic>Radiotherapy Planning, Computer-Assisted - methods</topic><topic>spot scanning</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Hirayama, Shusuke</creatorcontrib><creatorcontrib>Matsuura, Taeko</creatorcontrib><creatorcontrib>Ueda, Hideaki</creatorcontrib><creatorcontrib>Fujii, Yusuke</creatorcontrib><creatorcontrib>Fujii, Takaaki</creatorcontrib><creatorcontrib>Takao, Seishin</creatorcontrib><creatorcontrib>Miyamoto, Naoki</creatorcontrib><creatorcontrib>Shimizu, Shinichi</creatorcontrib><creatorcontrib>Fujimoto, Rintaro</creatorcontrib><creatorcontrib>Umegaki, Kikuo</creatorcontrib><creatorcontrib>Shirato, Hiroki</creatorcontrib><collection>Medline</collection><collection>MEDLINE</collection><collection>MEDLINE (Ovid)</collection><collection>MEDLINE</collection><collection>MEDLINE</collection><collection>PubMed</collection><collection>CrossRef</collection><collection>MEDLINE - Academic</collection><jtitle>Medical physics (Lancaster)</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Hirayama, Shusuke</au><au>Matsuura, Taeko</au><au>Ueda, Hideaki</au><au>Fujii, Yusuke</au><au>Fujii, Takaaki</au><au>Takao, Seishin</au><au>Miyamoto, Naoki</au><au>Shimizu, Shinichi</au><au>Fujimoto, Rintaro</au><au>Umegaki, Kikuo</au><au>Shirato, Hiroki</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>An analytical dose‐averaged LET calculation algorithm considering the off‐axis LET enhancement by secondary protons for spot‐scanning proton therapy</atitle><jtitle>Medical physics (Lancaster)</jtitle><addtitle>Med Phys</addtitle><date>2018-07</date><risdate>2018</risdate><volume>45</volume><issue>7</issue><spage>3404</spage><epage>3416</epage><pages>3404-3416</pages><issn>0094-2405</issn><eissn>2473-4209</eissn><abstract>Purpose To evaluate the biological effects of proton beams as part of daily clinical routine, fast and accurate calculation of dose‐averaged linear energy transfer (LETd) is required. In this study, we have developed the analytical LETd calculation method based on the pencil‐beam algorithm (PBA) considering the off‐axis enhancement by secondary protons. This algorithm (PBA‐dLET) was then validated using Monte Carlo simulation (MCS) results. Methods In PBA‐dLET, LET values were assigned separately for each individual dose kernel based on the PBA. For the dose kernel, we employed a triple Gaussian model which consists of the primary component (protons that undergo the multiple Coulomb scattering) and the halo component (protons that undergo inelastic, nonelastic and elastic nuclear reaction); the primary and halo components were represented by a single Gaussian and the sum of two Gaussian distributions, respectively. Although the previous analytical approaches assumed a constant LETd value for the lateral distribution of a pencil beam, the actual LETd increases away from the beam axis, because there are more scattered and therefore lower energy protons with higher stopping powers. To reflect this LETd behavior, we have assumed that the LETs of primary and halo components can take different values (LETp and LEThalo), which vary only along the depth direction. The values of dual‐LET kernels were determined such that the PBA‐dLET reproduced the MCS‐generated LETd distribution in both small and large fields. These values were generated at intervals of 1 mm in depth for 96 energies from 70.2 to 220 MeV and collected in the look‐up table. Finally, we compared the LETd distributions and mean LETd (LETd,mean) values of targets and organs at risk between PBA‐dLET and MCS. Both homogeneous phantom and patient geometries (prostate, liver, and lung cases) were used to validate the present method. Results In the homogeneous phantom, the LETd profiles obtained by the dual‐LET kernels agree well with the MCS results except for the low‐dose region in the lateral penumbra, where the actual dose was below 10% of the maximum dose. In the patient geometry, the LETd profiles calculated with the developed method reproduces MCS with the similar accuracy as in the homogeneous phantom. The maximum differences in LETd,mean for each structure between the PBA‐dLET and the MCS were 0.06 keV/μm in homogeneous phantoms and 0.08 keV/μm in patient geometries under all tested conditions, respectively. Conclusions We confirmed that the dual‐LET‐kernel model well reproduced the MCS, not only in the homogeneous phantom but also in complex patient geometries. The accuracy of the LETd was largely improved from the single‐LET‐kernel model, especially at the lateral penumbra. The model is expected to be useful, especially for proper recognition of the risk of side effects when the target is next to critical organs.</abstract><cop>United States</cop><pmid>29788552</pmid><doi>10.1002/mp.12991</doi><tpages>13</tpages></addata></record>
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subjects Algorithms
Computer Simulation
Humans
Linear Energy Transfer
Liver - radiation effects
Lung - radiation effects
Male
Monte Carlo Method
Organs at Risk
pencil beam algorithm
Prostate - radiation effects
proton
Proton Therapy - instrumentation
Proton Therapy - methods
Protons - therapeutic use
Radiotherapy Dosage
Radiotherapy Planning, Computer-Assisted - instrumentation
Radiotherapy Planning, Computer-Assisted - methods
spot scanning
title An analytical dose‐averaged LET calculation algorithm considering the off‐axis LET enhancement by secondary protons for spot‐scanning proton therapy
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