Cargando…
Generation and verification of QFix kVue Calypso‐compatible couch top model for a dedicated stereotactic linear accelerator with FFF beams
This study details the generation, verification, and implementation of a treatment planning system (TPS) couch top model for patient support system used in conjunction with a dedicated stereotactic linear accelerator. Couch top model was created within the TPS using CT simulation images of the kVue...
| Autores principales: | , , , , , , , , , , , |
|---|---|
| Formato: | Online Artículo Texto |
| Lenguaje: | English |
| Publicado: |
John Wiley and Sons Inc.
2015
|
| Materias: | |
| Acceso en línea: | https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5690015/ https://www.ncbi.nlm.nih.gov/pubmed/26219010 http://dx.doi.org/10.1120/jacmp.v16i4.5441 |
| _version_ | 1783279509742551040 |
|---|---|
| author | Gardner, Stephen J. Gulam, Misbah Song, Kwang Li, Haisen Huang, Yimei Zhao, Bo Qin, Yujiao Snyder, Karen Kim, Jinkoo Gordon, James Chetty, Indrin J. Wen, Ning |
| author_facet | Gardner, Stephen J. Gulam, Misbah Song, Kwang Li, Haisen Huang, Yimei Zhao, Bo Qin, Yujiao Snyder, Karen Kim, Jinkoo Gordon, James Chetty, Indrin J. Wen, Ning |
| author_sort | Gardner, Stephen J. |
| collection | PubMed |
| description | This study details the generation, verification, and implementation of a treatment planning system (TPS) couch top model for patient support system used in conjunction with a dedicated stereotactic linear accelerator. Couch top model was created within the TPS using CT simulation images of the kVue Calpyso‐compatible couchtop (with rails). Verification measurements were compared to TPS dose prediction for different energies (6 MV FFF and 10 MV FFF) and rail configurations (rails in and rails out) using: 1) central axis point‐dose measurements with pinpoint chamber in water‐equivalent phantom at 42 gantry angles for various field sizes ([Formula: see text]); and 2) Gafchromic EBT3 film parallel to beam in acrylic slab to assess changes in surface and percent depth doses in PA geometry. To assess sensitivity of delivered dose to variations in patient lateral position, measurements at central axis using the pinpoint chamber geometry were taken at lateral couch displacements of 2, 5, and 10 mm for 6 MV FFF. The maximum percent difference for point‐dose measurements was 3.24% (6 MV FFF) and 2.30% (10 MV FFF). The average percent difference for point‐dose measurements was less than 1.10% for all beam energies and rail geometries. The maximum percent difference between calculated and measured dose can be as large as 13.0% if no couch model is used for dose calculation. The presence of the couch structures also impacts surface dose and PDD, which was evaluated with Gafchromic film measurements. The upstream shift in the depth of dose maximum (dmax) was found to be 10.5 mm for 6 MV FFF and 5.5 mm for 10 MV FFF for ‘Rails In’ configuration. Transmission of the treatment beam through the couch results in an increase in surface dose (absolute percentage) of approximately 50% for both photon energies (6 MV FFF and 10 MV FFF). The largest sensitivity to lateral shifts occurred at the lateral boundary of the rail structures. The mean magnitude (standard deviation) of the deviation between shifted and centered measurements over all field sizes tested was 0.61% (0.61%) for 2 mm shifts, 0.46% (0.67%) for 5 mm shifts, and 0.86% (1.46%) for 10 mm shifts. PACS numbers: 87.56.‐v, 87.56.Da, 87.56.Fc |
| format | Online Article Text |
| id | pubmed-5690015 |
| institution | National Center for Biotechnology Information |
| language | English |
| publishDate | 2015 |
| publisher | John Wiley and Sons Inc. |
| record_format | MEDLINE/PubMed |
| spelling | pubmed-56900152018-04-02 Generation and verification of QFix kVue Calypso‐compatible couch top model for a dedicated stereotactic linear accelerator with FFF beams Gardner, Stephen J. Gulam, Misbah Song, Kwang Li, Haisen Huang, Yimei Zhao, Bo Qin, Yujiao Snyder, Karen Kim, Jinkoo Gordon, James Chetty, Indrin J. Wen, Ning J Appl Clin Med Phys Radiation Oncology Physics This study details the generation, verification, and implementation of a treatment planning system (TPS) couch top model for patient support system used in conjunction with a dedicated stereotactic linear accelerator. Couch top model was created within the TPS using CT simulation images of the kVue Calpyso‐compatible couchtop (with rails). Verification measurements were compared to TPS dose prediction for different energies (6 MV FFF and 10 MV FFF) and rail configurations (rails in and rails out) using: 1) central axis point‐dose measurements with pinpoint chamber in water‐equivalent phantom at 42 gantry angles for various field sizes ([Formula: see text]); and 2) Gafchromic EBT3 film parallel to beam in acrylic slab to assess changes in surface and percent depth doses in PA geometry. To assess sensitivity of delivered dose to variations in patient lateral position, measurements at central axis using the pinpoint chamber geometry were taken at lateral couch displacements of 2, 5, and 10 mm for 6 MV FFF. The maximum percent difference for point‐dose measurements was 3.24% (6 MV FFF) and 2.30% (10 MV FFF). The average percent difference for point‐dose measurements was less than 1.10% for all beam energies and rail geometries. The maximum percent difference between calculated and measured dose can be as large as 13.0% if no couch model is used for dose calculation. The presence of the couch structures also impacts surface dose and PDD, which was evaluated with Gafchromic film measurements. The upstream shift in the depth of dose maximum (dmax) was found to be 10.5 mm for 6 MV FFF and 5.5 mm for 10 MV FFF for ‘Rails In’ configuration. Transmission of the treatment beam through the couch results in an increase in surface dose (absolute percentage) of approximately 50% for both photon energies (6 MV FFF and 10 MV FFF). The largest sensitivity to lateral shifts occurred at the lateral boundary of the rail structures. The mean magnitude (standard deviation) of the deviation between shifted and centered measurements over all field sizes tested was 0.61% (0.61%) for 2 mm shifts, 0.46% (0.67%) for 5 mm shifts, and 0.86% (1.46%) for 10 mm shifts. PACS numbers: 87.56.‐v, 87.56.Da, 87.56.Fc John Wiley and Sons Inc. 2015-07-08 /pmc/articles/PMC5690015/ /pubmed/26219010 http://dx.doi.org/10.1120/jacmp.v16i4.5441 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 Gardner, Stephen J. Gulam, Misbah Song, Kwang Li, Haisen Huang, Yimei Zhao, Bo Qin, Yujiao Snyder, Karen Kim, Jinkoo Gordon, James Chetty, Indrin J. Wen, Ning Generation and verification of QFix kVue Calypso‐compatible couch top model for a dedicated stereotactic linear accelerator with FFF beams |
| title | Generation and verification of QFix kVue Calypso‐compatible couch top model for a dedicated stereotactic linear accelerator with FFF beams |
| title_full | Generation and verification of QFix kVue Calypso‐compatible couch top model for a dedicated stereotactic linear accelerator with FFF beams |
| title_fullStr | Generation and verification of QFix kVue Calypso‐compatible couch top model for a dedicated stereotactic linear accelerator with FFF beams |
| title_full_unstemmed | Generation and verification of QFix kVue Calypso‐compatible couch top model for a dedicated stereotactic linear accelerator with FFF beams |
| title_short | Generation and verification of QFix kVue Calypso‐compatible couch top model for a dedicated stereotactic linear accelerator with FFF beams |
| title_sort | generation and verification of qfix kvue calypso‐compatible couch top model for a dedicated stereotactic linear accelerator with fff beams |
| topic | Radiation Oncology Physics |
| url | https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5690015/ https://www.ncbi.nlm.nih.gov/pubmed/26219010 http://dx.doi.org/10.1120/jacmp.v16i4.5441 |
| work_keys_str_mv | AT gardnerstephenj generationandverificationofqfixkvuecalypsocompatiblecouchtopmodelforadedicatedstereotacticlinearacceleratorwithfffbeams AT gulammisbah generationandverificationofqfixkvuecalypsocompatiblecouchtopmodelforadedicatedstereotacticlinearacceleratorwithfffbeams AT songkwang generationandverificationofqfixkvuecalypsocompatiblecouchtopmodelforadedicatedstereotacticlinearacceleratorwithfffbeams AT lihaisen generationandverificationofqfixkvuecalypsocompatiblecouchtopmodelforadedicatedstereotacticlinearacceleratorwithfffbeams AT huangyimei generationandverificationofqfixkvuecalypsocompatiblecouchtopmodelforadedicatedstereotacticlinearacceleratorwithfffbeams AT zhaobo generationandverificationofqfixkvuecalypsocompatiblecouchtopmodelforadedicatedstereotacticlinearacceleratorwithfffbeams AT qinyujiao generationandverificationofqfixkvuecalypsocompatiblecouchtopmodelforadedicatedstereotacticlinearacceleratorwithfffbeams AT snyderkaren generationandverificationofqfixkvuecalypsocompatiblecouchtopmodelforadedicatedstereotacticlinearacceleratorwithfffbeams AT kimjinkoo generationandverificationofqfixkvuecalypsocompatiblecouchtopmodelforadedicatedstereotacticlinearacceleratorwithfffbeams AT gordonjames generationandverificationofqfixkvuecalypsocompatiblecouchtopmodelforadedicatedstereotacticlinearacceleratorwithfffbeams AT chettyindrinj generationandverificationofqfixkvuecalypsocompatiblecouchtopmodelforadedicatedstereotacticlinearacceleratorwithfffbeams AT wenning generationandverificationofqfixkvuecalypsocompatiblecouchtopmodelforadedicatedstereotacticlinearacceleratorwithfffbeams |