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2. Optimization of FLASH Proton Beams Using a Track-Repeating Algorithm

Author

Wang, Qianxia, Titt, Uwe, Mohan, Radhe, Guan, Fada, Zhao, Yao, Yang, Ming, and Yepes, Pablo

Subjects
Physics - Medical Physics
Abstract

Methods: A phase space file in a plane at 202 mm downstream of the beam exit window is generated through tuning parameters to match FDC results with measured or MCNPX Monte Carlo-simulated integrated depth-dose distribution (IDD) and lateral dose profiles. To spread out the Bragg peak, widen the beam and reduce the penumbra, a ridge filter (RF), a high-Z material scatterer and a collimator with compensator are inserted in the beam path and their shapes and sizes have been optimized. The FDC calculations are validated by comparing Geant4 Monte Carlo simulations. In addition, a set of algorithms to automatically choose the optimum dimensions of the beam shaping elements is developed and tested using the same beams. At the last part, dose rates for optimized beams were estimated by scaling their dose distributions to that of their original beams. Results: The optimized 86.4 MeV beam had an 8.5 mm wide spread-out Bragg peak (SOBP) (proximal 90% to distal 90% of the maximum dose), 14.5 mm, 12.0 mm and 11.0 lateral widths with dose above 50%, 80% and 90% respectively and a 2.5 mm penumbra from 80% to 20% in the lateral profile for the energy. The 159.5 MeV beam had a SOBP of 39.0 mm and the lateral widths with dose above 50%, 80% and 90% of 20.5 mm, 15.0 and 12.5 mm when the source to surface distance (SSD) was 550 mm. Wider lateral widths was obtained with increased SSD. The FDC calculations had passing rates higher than 96% using 3mm/3% as the gamma-index criterion comparing with Geant4 simulations for both energies. The set of automatic algorithms can choose the proper dimensions for the high-density scatterer, RF, collimator and compensator efficiently. And the optimized 159.5 MeV beam with different SDDs had entrance dose rate higher than 40 Gy/s if the entrance dose rate of the original beam was 150 Gy/s., Comment: 15 pages, 7 figures, two tables

Published
2021
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12. The first PET glimpse of a proton FLASH beam

Author

Abouzahr, Firas, primary, Cesar, John Paul, additional, Crespo, Paulo, additional, Gajda, Michael Julius, additional, Hu, Zongsheng, additional, Kaye, Willie, additional, Klein, Kyle, additional, Kuo, Alex, additional, Majewski, Stanislaw, additional, Mawlawi, Osama R, additional, Morozov, Andrey, additional, Ojha, Aryan, additional, Poenisch, Falk, additional, Polf, Jerimy C, additional, Proga, Marek, additional, Sahoo, Narayan, additional, Seco, Joao, additional, Takaoka, Takeshi, additional, Tavernier, Stefaan, additional, Titt, Uwe, additional, Wang, Xiaochun, additional, Zhu, Xiaorong Ronald, additional, and Lang, Karol, additional

Published
2023
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19. Adaptation and dosimetric commissioning of a synchrotron-based proton beamline for FLASH experiments

Author

Yang, Ming, primary, Wang, Xiaochun, additional, Guan, Fada, additional, Titt, Uwe, additional, Iga, Kiminori, additional, Jiang, Dadi, additional, Takaoka, Takeshi, additional, Tootake, Satoshi, additional, Katayose, Tadashi, additional, Umezawa, Masumi, additional, Schüler, Emil, additional, Frank, Steven, additional, Lin, Steven H, additional, Sahoo, Narayan, additional, Koong, Albert C, additional, Mohan, Radhe, additional, and Zhu, X Ronald, additional

Published
2022
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20. Roadmap: helium ion therapy

Author

Mairani, Andrea, primary, Mein, Stewart, additional, Blakely, Eleanor, additional, Debus, Jürgen, additional, Durante, Marco, additional, Ferrari, Alfredo, additional, Fuchs, Hermann, additional, Georg, Dietmar, additional, Grosshans, David R, additional, Guan, Fada, additional, Haberer, Thomas, additional, Harrabi, Semi, additional, Horst, Felix, additional, Inaniwa, Taku, additional, Karger, Christian P, additional, Mohan, Radhe, additional, Paganetti, Harald, additional, Parodi, Katia, additional, Sala, Paola, additional, Schuy, Christoph, additional, Tessonnier, Thomas, additional, Titt, Uwe, additional, and Weber, Ulrich, additional

Published
2022
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21. Effect of boron compounds on the biological effectiveness of proton therapy

Author

Manandhar, Mandira, primary, Bright, Scott J., additional, Flint, David B., additional, Martinus, David K. J., additional, Kolachina, Rishab V., additional, Kacem, Mariam B., additional, Titt, Uwe, additional, Martin, Tioga J., additional, Lee, Chad L., additional, Morrison, Kendall, additional, Shaitelman, Simona F., additional, and Sawakuchi, Gabriel O., additional

Published
2022
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25. Mapping the Relative Biological Effectiveness of Proton, Helium and Carbon Ions with High-Throughput Techniques

Author

Bronk, Lawrence, primary, Guan, Fada, additional, Patel, Darshana, additional, Ma, Duo, additional, Kroger, Benjamin, additional, Wang, Xiaochun, additional, Tran, Kevin, additional, Yiu, Joycelyn, additional, Stephan, Clifford, additional, Debus, Jürgen, additional, Abdollahi, Amir, additional, Jäkel, Oliver, additional, Mohan, Radhe, additional, Titt, Uwe, additional, and Grosshans, David R., additional

Published
2020
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27. Technical note: Monte Carlo study of the mechanism of proton–boron fusion therapy.

Author

Meyer, Henry J., Titt, Uwe, and Mohan, Radhe

Subjects
*PROTON beams, *ALPHA rays, *NUCLEAR fusion, *PARTICLE physics, *BORON isotopes, *PARTICLE beams
Abstract

Purpose: Proton beam therapy has been found to have enhanced biological effectiveness in targets that contain the boron isotope 11B, with the alpha particles resulting from the p + 11B → 3α reaction being hypothesized as the mechanism; in this study, we aimed to elucidate the causes of the enhanced biological effectiveness of proton–boron fusion therapy by performing a detailed Monte Carlo study of the p + 11B → 3α reaction in a phantom geometry. Methods: We utilized the Geant4 toolkit to create Monte Carlo particle physics simulations. These simulations consisted of a proton beam with a range 30 mm, creating a Spread‐Out Bragg Peak with a modulation width of 10 mm, directed into a water phantom containing a region of boron material. Energy deposition, particle energy, and particle fluence were scored along the path of the beam and grouped by particle species. The scoring was performed using a series of cylindrical volumes with a radius of 2.5 mm and depth of 0.1 mm, constructed such that the depth was parallel to the proton beam. Root was then used to perform the data analysis. Results: Our simulations showed that the dose delivered by alpha particles produced by p + 11B → 3α was several orders of magnitude lower than the dose delivered directly by protons, even when the boron uptake region was comprised entirely of natural boron or pure 11B. Conclusions: Our findings do not support the theory that an alpha particle‐based mechanism is responsible for the enhanced biological effectiveness of proton–boron fusion therapy. We conclude that any enhanced biological effect seen in experimental studies was not caused by fusion reactions between protons and 11B nuclei. However, it is necessary to reproduce the past experiments that indicated significant dose enhancement. [ABSTRACT FROM AUTHOR]

Published
2022
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28. Design and validation of a synchrotron proton beam line for FLASH radiotherapy preclinical research experiments.

Author

Titt, Uwe, Yang, Ming, Wang, Xiaochun, Iga, Kiminori, Fredette, Nathaniel, Schueler, Emil, Lin, Steven H, Zhu, X Ron, Sahoo, Narayan, Koong, Albert C, Zhang, Xiaodong, and Mohan, Radhe

Subjects
*PROTON beams, *LINEAR energy transfer, *MONTE Carlo method, *SYNCHROTRONS, *RADIOBIOLOGY, *RADIOTHERAPY
Abstract

Purpose: The main purpose of this work was to generate and validate the dosimetric accuracy of proton beams of dimensions that are appropriate for in vivo small animal and in vitro ultrahigh dose rate (FLASH) radiotherapy experiments using a synchrotron‐based treatment delivery system. This study was performed to enable future investigations of the relevance of a spread‐out Bragg peak (SOBP) under FLASH conditions. Methods: The spill characteristics of the small field fixed horizontal beam line were modified to deliver accelerated protons in times as short as 2 ms and to control the dose delivered. A Gaussian‐like transverse beam profile was transformed into a square uniform one at FLASH dose rates, while avoiding low‐dose regions, a crucial requirement to protect normal tissue during FLASH irradiation. Novel beam‐shaping devices were designed using Monte Carlo techniques to produce up to about 6 cm3 of uniform dose in SOBPs while maximizing the dose rate. These included a scattering foil, a conical flattening filter to maximize the flux of protons into the region of interest, energy filters, range compensators, and collimators. The shapes, sizes, and positions of the components were varied to provide the required field sizes and SOBPs. Results: The designed and fabricated devices were used to produce 10‐, 15‐, and 20‐mm diameter, circular field sizes and 10‐, 15‐, and 20‐mm SOBP modulation widths at uniform physical dose rates of up to 375 Gy/s at the center of the SOBP and a minimum dose rate of about 255 Gy/s at the entrance, respectively, in cylindrical volumes. The flatness of lateral dose profiles at the center could be adjusted to within ±1.5% at the center of the SOBP. Assessment of systematic uncertainties, such as impact of misalignments and positioning uncertainties, was performed using simulations, and the results were used to provide appropriate adjustments to ensure high‐accuracy FLASH beam delivery for both in vitro and in vivo preclinical experiments. Conclusions: It is feasible to use synchrotron‐generated proton beams of sufficient dimensions for FLASH radiobiology experiments. We expect to use the system we developed to acquire in vitro and in vivo small animal FLASH radiobiology data as a function of dose, dose rate, oxygen content, and linear energy transfer to help us understand the underlying mechanisms of the FLASH phenomenon. [ABSTRACT FROM AUTHOR]

Published
2022
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29. Nonhomologous End Joining Is More Important Than Proton Linear Energy Transfer in Dictating Cell Death

Author

Bright, Scott J., primary, Flint, David B., additional, Chakraborty, Sharmistha, additional, McFadden, Conor H., additional, Yoon, David S., additional, Bronk, Lawrence, additional, Titt, Uwe, additional, Mohan, Radhe, additional, Grosshans, David R., additional, Sumazin, Pavel, additional, Shaitelman, Simona F., additional, Asaithamby, Aroumougame, additional, and Sawakuchi, Gabriel O., additional

Published
2019
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33. Differences in Normal Tissue Response in the Esophagus Between Proton and Photon Radiation Therapy for Non-Small Cell Lung Cancer Using In Vivo Imaging Biomarkers

Author

Niedzielski, Joshua S., primary, Yang, Jinzhong, additional, Mohan, Radhe, additional, Titt, Uwe, additional, Mirkovic, Dragan, additional, Stingo, Francesco, additional, Liao, Zhongxing, additional, Gomez, Daniel R., additional, Martel, Mary K., additional, Briere, Tina M., additional, and Court, Laurence E., additional

Published
2017
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40. An MCNPX Monte Carlo model of a discrete spot scanning proton beam therapy nozzle

Author

Sawakuchi, Gabriel O., Mirkovic, Dragan, Perles, Luis A., Sahoo, Narayan, Zhu, X. Ron, Ciangaru, George, Suzuki, Kazumichi, Gillin, Michael T., Mohan, Radhe, and Titt, Uwe

Subjects
Radiation Therapy Physics, Radiotherapy, Phantoms, Imaging, Physics::Medical Physics, Proton Therapy, Physics::Accelerator Physics, Reproducibility of Results, Radiotherapy Dosage, Radiometry, Monte Carlo Method
Abstract

The purposes of this study were to validate a discrete spot scanning proton beam nozzle using the Monte Carlo (MC) code MCNPX and use the MC validated model to investigate the effects of a low-dose envelope, which surrounds the beam's central axis, on measurements of integral depth dose (IDD) profiles.An accurate model of the discrete spot scanning beam nozzle from The University of Texas M. D. Anderson Cancer Center (Houston, Texas) was developed on the basis of blueprints provided by the manufacturer of the nozzle. The authors performed simulations of single proton pencil beams of various energies using the standard multiple Coulomb scattering (MCS) algorithm within the MCNPX source code and a new MCS algorithm, which was implemented in the MCNPX source code. The MC models were validated by comparing calculated in-air and in-water lateral profiles and percentage depth dose profiles for single pencil beams with their corresponding measured values. The models were then further tested by comparing the calculated and measured three-dimensional (3-D) dose distributions. Finally, an IDD profile was calculated with different scoring radii to determine the limitations on the use of commercially available plane-parallel ionization chambers to measure IDD.The distance to agreement, defined as the distance between the nearest positions of two equivalent distributions with the same value of dose, between measured and simulated ranges was within 0.13 cm for both MCS algorithms. For low and intermediate pencil beam energies, the MC simulations using the standard MCS algorithm were in better agreement with measurements. Conversely, the new MCS algorithm produced better results for high-energy single pencil beams. The IDD profile calculated with cylindrical tallies with an area equivalent to the area of the largest commercially available ionization chamber showed up to 7.8% underestimation of the integral dose in certain depths of the IDD profile.The authors conclude that a combination of MCS algorithms is required to accurately reproduce experimental data of single pencil beams and 3-D dose distributions for the scanning beam nozzle. In addition, the MC simulations showed that because of the low-dose envelope, ionization chambers with radii as large as 4.08 cm are insufficient to accurately measure IDD profiles for a 221.8 MeV pencil beam in the scanning beam nozzle.

Published
2010

42. Spatial mapping of the biologic effectiveness of scanned particle beams: towards biologically optimized particle therapy

Author

Guan, Fada, primary, Bronk, Lawrence, additional, Titt, Uwe, additional, Lin, Steven H., additional, Mirkovic, Dragan, additional, Kerr, Matthew D., additional, Zhu, X. Ronald, additional, Dinh, Jeffrey, additional, Sobieski, Mary, additional, Stephan, Clifford, additional, Peeler, Christopher R., additional, Taleei, Reza, additional, Mohan, Radhe, additional, and Grosshans, David R., additional

Published
2015
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