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Implementation of a double scattering nozzle for Monte Carlo recalculation of proton plans with variable relative biological effectiveness

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Development of a Monte Carlo beam model for raster scanning proton beams and dosimetric comparison

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https://doi.org/10.1080/09553002.2020.1812758

Monte Carlo study of out‐of‐field exposure in carbon‐ion radiotherapy: Organ doses in pediatric brain tumor treatment

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Medical Physics 46 (12) 5824 (2019)
https://doi.org/10.1002/mp.13864

Nanoscale Insights into Ion-Beam Cancer Therapy

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Nanoscale Insights into Ion-Beam Cancer Therapy 467 (2017)
https://doi.org/10.1007/978-3-319-43030-0_14

Benchmarking Monte Carlo simulations against experimental data in clinically relevant passive scattering proton therapy beamline configurations

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Radioprotection 51 (2) 113 (2016)
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Influence of beam incidence and irradiation parameters on stray neutron doses to healthy organs of pediatric patients treated for an intracranial tumor with passive scattering proton therapy

A. Bonfrate, J. Farah, L. De Marzi, et al.
Physica Medica 32 (4) 590 (2016)
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Monte Carlo modeling of proton therapy installations: a global experimental method to validate secondary neutron dose calculations

J Farah, F Martinetti, R Sayah, et al.
Physics in Medicine and Biology 59 (11) 2747 (2014)
https://doi.org/10.1088/0031-9155/59/11/2747

Secondary neutron doses received by paediatric patients during intracranial proton therapy treatments

R Sayah, J Farah, L Donadille, et al.
Journal of Radiological Protection 34 (2) 279 (2014)
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