PURPOSE: To quantify the dosimetric benefit of using a dynamic collimation system (DCS) for penumbra reduction during the treatment of brain tumors by pencil beam scanning proton therapy (PBS PT). METHODS AND MATERIALS: Collimated and uncollimated brain treatment plans were created for 5 patients previously treated with PBS PT and retrospectively enrolled in an institutional review board-approved study. The in-house treatment planning system, RDX, was used to generate the plans because it is capable of modeling both collimated and uncollimated beamlets. The clinically delivered plans were reproduced with uncollimated plans in terms of target coverage and organ at risk (OAR) sparing to ensure a clinically relevant starting point, and collimated plans were generated to improve the OAR sparing while maintaining target coverage. Physical and biological comparison metrics, such as dose distribution conformity, mean and maximum doses, normal tissue complication probability, and risk of secondary brain cancer, were used to evaluate the plans. RESULTS: The DCS systematically improved the dose distribution conformity while preserving the target coverage. The average reduction of the mean dose to the 10-mm ring surrounding the target and the healthy brain were 13.7% (95% confidence interval [CI] 11.6%-15.7%; P<.0001) and 25.1% (95% CI 16.8%-33.4%; P<.001), respectively. This yielded an average reduction of 24.8% (95% CI 0.8%-48.8%; P<.05) for the brain necrosis normal tissue complication probability using the Flickinger model, and 25.1% (95% CI 16.8%-33.4%; P<.001) for the risk of secondary brain cancer. A general improvement of the OAR sparing was also observed. CONCLUSION: The lateral penumbra reduction afforded by the DCS increases the normal tissue sparing capabilities of PBS PT for brain cancer treatment while preserving target coverage.
PURPOSE: To quantify the dosimetric benefit of using a dynamic collimation system (DCS) for penumbra reduction during the treatment of brain tumors by pencil beam scanning proton therapy (PBS PT). METHODS AND MATERIALS: Collimated and uncollimated brain treatment plans were created for 5 patients previously treated with PBS PT and retrospectively enrolled in an institutional review board-approved study. The in-house treatment planning system, RDX, was used to generate the plans because it is capable of modeling both collimated and uncollimated beamlets. The clinically delivered plans were reproduced with uncollimated plans in terms of target coverage and organ at risk (OAR) sparing to ensure a clinically relevant starting point, and collimated plans were generated to improve the OAR sparing while maintaining target coverage. Physical and biological comparison metrics, such as dose distribution conformity, mean and maximum doses, normal tissue complication probability, and risk of secondary brain cancer, were used to evaluate the plans. RESULTS: The DCS systematically improved the dose distribution conformity while preserving the target coverage. The average reduction of the mean dose to the 10-mm ring surrounding the target and the healthy brain were 13.7% (95% confidence interval [CI] 11.6%-15.7%; P<.0001) and 25.1% (95% CI 16.8%-33.4%; P<.001), respectively. This yielded an average reduction of 24.8% (95% CI 0.8%-48.8%; P<.05) for the brain necrosis normal tissue complication probability using the Flickinger model, and 25.1% (95% CI 16.8%-33.4%; P<.001) for the risk of secondary brain cancer. A general improvement of the OAR sparing was also observed. CONCLUSION: The lateral penumbra reduction afforded by the DCS increases the normal tissue sparing capabilities of PBS PT for brain cancer treatment while preserving target coverage.
Authors: Blake Smith; Edgar Gelover; Alexandra Moignier; Dongxu Wang; Ryan T Flynn; Liyong Lin; Maura Kirk; Tim Solberg; Daniel E Hyer Journal: Med Phys Date: 2016-08 Impact factor: 4.071
Authors: Alexandra Moignier; Edgar Gelover; Blake R Smith; Dongxu Wang; Ryan T Flynn; Maura L Kirk; Liyong Lin; Timothy D Solberg; Alexander Lin; Daniel E Hyer Journal: Med Phys Date: 2016-03 Impact factor: 4.071
Authors: Blake R Smith; Nicholas P Nelson; Theodore J Geoghegan; Kaustubh A Patwardhan; Patrick M Hill; Jen Yu; Alonso N Gutiérrez; Bryan G Allen; Daniel E Hyer Journal: Med Phys Date: 2022-02-21 Impact factor: 4.071
Authors: Alexandra Moignier; Edgar Gelover; Dongxu Wang; Blake Smith; Ryan Flynn; Maura Kirk; Liyong Lin; Timothy Solberg; Alexander Lin; Daniel Hyer Journal: Int J Part Ther Date: 2016-03-24
Authors: Christian Bäumer; Sandija Plaude; Dalia Ahmad Khalil; Dirk Geismar; Paul-Heinz Kramer; Kevin Kröninger; Christian Nitsch; Jörg Wulff; Beate Timmermann Journal: Front Oncol Date: 2021-05-12 Impact factor: 6.244