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[1]
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Lukas Cornelius Wolter, Fabian Hennings, Jozef Bokor, Christian Richter, and
Kristin Stuetzer.
Validity of one-time phantomless patient-specific quality assurance
in proton therapy with regard to the reproducibility of beam delivery.
Medical Physics, 52:3173–3182, 2025.
[ DOI ]
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[2]
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Xiaoning Ding, James E. Younkin, Jiajian Shen, Martin Bues, and Wei Liu.
A critical review of the practices of proton daily quality assurance
programs.
Therapeutic Radiology and Oncology, 5, 2021.
[ DOI ]
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[3]
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Sebastian Tattenberg, Thomas M. Madden, Bram L. Gorissen, Thomas Bortfeld,
Katia Parodi, and Joost Verburg.
Proton range uncertainty reduction benefits for skull base tumors in
terms of normal tissue complication probability (ntcp) and healthy tissue
doses.
Medical Physics, 48, 2021.
[ DOI ]
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[4]
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Arturs Meijers, Gabriel Guterres Marmitt, Kelvin Ng Wei Siang, Arjen van der
Schaaf, Antje C. Knopf, Johannes A. Langendijk, and Stefan Both.
Feasibility of patient specific quality assurance for proton therapy
based on independent dose calculation and predicted outcomes.
Radiotherapy and Oncology, 150, 2020.
[ DOI ]
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[5]
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M. Matter, L. Nenoff, L. Marc, D. C. Weber, A. J. Lomax, and F. Albertini.
Update on yesterday's dose-use of delivery log-files for daily
adaptive proton therapy (dapt).
Physics in Medicine and Biology, 65, 2020.
[ DOI ]
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[6]
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Antony John Lomax.
Myths and realities of range uncertainty.
The British Journal of Radiology, 93, 2020.
[ DOI ]
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[7]
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Carla Winterhalter, Gabriel Meier, David Oxley, Damien C. Weber, Antony J.
Lomax, and Sairos Safai.
Log file based monte carlo calculations for proton pencil beam
scanning therapy.
Physics in Medicine and Biology, 64, 2019.
[ DOI ]
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[8]
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Suresh Rana, Jaafar Bennouna, E. James Jebaseelan Samuel, and Alonso N.
Gutierrez.
Development and long-term stability of a comprehensive daily qa
program for a modern pencil beam scanning (pbs) proton therapy delivery
system.
Journal of Applied Clinical Medical Physics, 20, 2019.
[ DOI ]
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[9]
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Bijan Arjomandy, Paige Taylor, Christopher Ainsley, Sairos Safai, Narayan
Sahoo, Mark Pankuch, Jonathan B. Farr, Sung Yong Park, Eric Klein, Jacob
Flanz, Ellen D. Yorke, David Followill, and Yuki Kase.
Aapm task group 224: Comprehensive proton therapy machine quality
assurance.
Medical Physics, 46, 2019.
[ DOI ]
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[10]
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Xuemin Bai, Gino Lim, David Grosshans, Radhe Mohan, and Wenhua Cao.
Robust optimization to reduce the impact of biological effect
variation from physical uncertainties in intensity-modulated proton therapy.
Physics in Medicine and Biology, 64, 2019.
[ DOI ]
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[11]
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M. Matter, L. Nenoff, G. Meier, D. C. Weber, A. J. Lomax, and F. Albertini.
Alternatives to patient specific verification measurements in proton
therapy: A comparative experimental study with intentional errors.
Physics in Medicine and Biology, 63, 2018.
[ DOI ]
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[12]
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Moyed Miften, Arthur Olch, Dimitris Mihailidis, Jean Moran, Todd Pawlicki,
Andrea Molineu, Harold Li, Krishni Wijesooriya, Jie Shi, Ping Xia, Nikos
Papanikolaou, and Daniel A. Low.
Tolerance limits and methodologies for imrt measurement-based
verification qa: Recommendations of aapm task group no. 218.
Medical Physics, 45, 2018.
[ DOI ]
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[13]
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O. Actis, D. Meer, S. König, D. C. Weber, and A. Mayor.
A comprehensive and efficient daily quality assurance for pbs proton
therapy.
Physics in Medicine and Biology, 62, 2017.
[ DOI ]
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[14]
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Maria Francesca Belosi, Robert van der Meer, Paz Garcia de Acilu Laa,
Alessandra Bolsi, Damien C. Weber, and Antony J. Lomax.
Treatment log files as a tool to identify treatment plan sensitivity
to inaccuracies in scanned proton beam delivery.
Radiotherapy and Oncology, 125, 2017.
[ DOI ]
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[15]
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Maria F. Chan, Chin-Cheng Chen, Chengyu Shi, Jingdong Li, Xiaoli Tang, Xiang
Li, and Dennis Mah.
Patient-specific qa of spot-scanning proton beams using radiochromic
film.
International Journal of Medical Physics, Clinical Engineering
and Radiation Oncology, 06, 2017.
[ DOI ]
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[16]
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Nicola Bizzocchi, Francesco Fracchiolla, Marco Schwarz, and Carlo Algranati.
A fast and reliable method for daily quality assurance in spot
scanning proton therapy with a compact and inexpensive phantom.
Medical Dosimetry, 42, 2017.
[ DOI ]
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[17]
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P. Trnková, A. Bolsi, F. Albertini, D. C. Weber, and A. J. Lomax.
Factors influencing the performance of patient specific quality
assurance for pencil beam scanning impt fields.
Medical Physics, 43, 2016.
[ DOI ]
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[18]
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Harald Paganetti.
Proton Therapy Physics.
CRC Press, 2016.
[ DOI ]
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[19]
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X. Ronald Zhu, Yupeng Li, Dennis Mackin, Heng Li, Falk Poenisch, Andrew K. Lee,
Anita Mahajan, Steven J. Frank, Michael T. Gillin, Narayan Sahoo, and
Xiaodong Zhang.
Towards effective and efficient patient-specific quality assurance
for spot scanning proton therapy.
Cancers, 7, 2015.
[ DOI ]
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[20]
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Wayne D. Newhauser and Rui Zhang.
The physics of proton therapy.
Physics in Medicine and Biology, 60, 2015.
[ DOI ]
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[21]
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Dennis Mackin, X. Ronald Zhu, Falk Poenisch, Heng Li, Narayan Sahoo, Matthew
Kerr, Charles Holmes, Yupeng Li, MingFwu Lii, Richard Wu, Kazumichi Suzuki,
Michael T. Gillin, Steven J. Frank, David Grosshans, and Xiaodong Zhang.
Spot-scanning proton therapy patient-specific quality assurance:
Results from 309 treatment plans.
International Journal of Particle Therapy, 1, 2014.
[ DOI ]
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[22]
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Albin Fredriksson and Rasmus Bokrantz.
A critical evaluation of worst case optimization methods for robust
intensity-modulated proton therapy planning.
Medical Physics, 41, 2014.
[ DOI ]
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[23]
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Heng Li, Narayan Sahoo, Falk Poenisch, Kazumichi Suzuki, Yupeng Li, Xiaoqiang
Li, Xiaodong Zhang, Andrew K. Lee, Michael T. Gillin, and X. Ronald Zhu.
Use of treatment log files in spot scanning proton therapy as part of
patient-specific quality assurance.
Medical Physics, 40, 2013.
[ DOI ]
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[24]
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Harald Paganetti.
Range uncertainties in proton therapy and the role of monte carlo
simulations.
Physics in Medicine and Biology, 57, 2012.
[ DOI ]
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[25]
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J. Perl, J. Shin, J. Schümann, B. Faddegon, and H. Paganetti.
Topas: An innovative proton monte carlo platform for research and
clinical applications.
Medical Physics, 39, 2012.
[ DOI ]
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[26]
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Christian P. Karger, Oliver Jäkel, Hugo Palmans, and Tatsuaki Kanai.
Dosimetry for ion beam radiotherapy.
Physics in Medicine and Biology, 55, 2010.
[ DOI ]
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[27]
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D. Pflugfelder, J. J. Wilkens, and U. Oelfke.
Worst case optimization: A method to account for uncertainties in the
optimization of intensity modulated proton therapy.
Physics in Medicine and Biology, 53, 2008.
[ DOI ]
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[28]
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A. J. Lomax.
Intensity modulated proton therapy and its sensitivity to treatment
uncertainties 2: The potential effects of inter-fraction and inter-field
motions.
Physics in Medicine and Biology, 53, 2008.
[ DOI ]
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[29]
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A. J. Lomax.
Intensity modulated proton therapy and its sensitivity to treatment
uncertainties 1: The potential effects of calculational uncertainties.
Physics in Medicine and Biology, 53, 2008.
[ DOI ]
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