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| Main Authors: | , , , , |
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| Format: | Preprint |
| Published: |
2025
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| Subjects: | |
| Online Access: | https://arxiv.org/abs/2503.12904 |
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Table of Contents:
- Background: Upright proton therapy with compact delivery systems has the potential to reduce costs for treatments but could also lead to broadening of the beam penumbra due to energy selection close to the patient. Purpose: This study aims at combining upright static proton arcs with additional layers of shoot-through (ST) protons to sharpen the beam penumbra and improve plan quality for such systems. Methods: We examined various treatment plans for a virtual phantom: 3-beam IMPT, static arc (Arc) with/without ST (Arc+ST), and with/without collimation (+Coll). In the virtual phantom three different targets were utilized to study the effect on conformity index (CI), homogeneity index (HI), robustness and mean dose to the phantom volume. The phantom study was complemented with a head-and-neck (H&N) patient case with a similar set of plans. The delivery time for all plans was estimated. A range verification concept that determines residual ranges of the ST protons was studied in simulated scenarios for the H&N case. Results: In the phantom study, the Arc+ST plans show superior CI, HI and target robustness compared to the Arc+Coll plans. For the Arc plans without ST, the collimated plans perform better than the uncollimated plans. On the other hand, for Arc+ST, collimation has little impact on CI, HI and robustness. For the H&N case, similar improvements for Arc+ST can be seen. These results imply that no aperture is needed when combining arcs with ST, which in turn substantially reduces treatment times. The range verification simulation shows that the method is sensitive to detect SPR errors, setup errors and changes in the patient anatomy. Conclusions: Combining proton arcs and ST layers can enhance compact upright proton solutions by improving plan quality. It is also tailored for the inclusion of a fast and straightforward residual range verification method.