A comprehensive spectrometry study of a stray neutron radiation field in scanning proton therapy

Mares, V.; Romero-Expósito, Maite; Farah, Jad; Trinkl, Sebastian; Domingo, C.; Dommert, Martin; Stolarczyk, Liliana; Ryckeghem, Laurent Van; Wieluński, M.; Olko, P.; Harrison, R. M.

doi:10.1088/0031-9155/61/11/4127

Cited by 37 publications

(32 citation statements)

References 20 publications

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“…As in Ref. [13], an evaporation peak was resolved in beam direction despite the existence of a strong high-energy peak. In previous studies, 12 it was not possible to resolve the evaporation peak completely.…”

Section: Discussionsupporting

confidence: 64%

Systematic out‐of‐field secondary neutron spectrometry and dosimetry in pencil beam scanning proton therapy

et al. 2017

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This study showed a pronounced increase of secondary neutron H*(10) values inside the proton treatment room with increasing proton energy without beam modifiers. For example, in beam direction this increase was about a factor of 50 when protons of 75 MeV and 200 MeV were compared. The existence of a peak of secondary neutrons in the MeV region was demonstrated in beam direction (0°). This peak is due to evaporation neutrons produced in the existing surrounding materials such as those used for the gantry. Therefore, any simulation of the secondary neutrons within a proton treatment room must take these materials into account. In addition, the results obtained here show that the use of a range-shifter increases the production of secondary neutrons inside the treatment room. Using a range-shifter, the higher neutron doses observed mainly result from the higher incident proton energy (118 MeV instead of 75 MeV when no range-shifter was used), due to higher neutron production cross-sections.

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Section: Discussionsupporting

confidence: 64%

Systematic out‐of‐field secondary neutron spectrometry and dosimetry in pencil beam scanning proton therapy

et al. 2017

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“…Like the photon–neutron spectra, the proton neutrons have a peak at a few hundred keV that is produced from evaporation processes and is isotropically generated as well as a low‐energy tail that extends down to thermal energies from room‐scattered neutrons. Uniquely, however, the proton–neutron spectra have a second peak that starts at around 20 MeV and extends up to the maximum proton beam energy . The high‐energy peak contains forward‐directed neutrons from direct (nucleon–nucleon) reactions .…”

Section: Dose Estimatesmentioning

confidence: 99%

“…High‐Z shells are typically employed to increase the sensitivity of Bonner spheres to high‐energy neutrons (> 20 MeV), such as those encountered around proton or carbon ion beams that extend up to hundreds of MeV . Use of these shells creates an extended‐range Bonner sphere spectrometer, which can be used in conjunction with any of the thermal neutron detectors described above to measure secondary neutrons from proton therapy . Similar to standard Bonner sphere spectrometers, response functions for each detector–sphere combination must be determined, accounting for the high‐Z shell.…”

Section: Measurement Approachesmentioning

confidence: 99%

“…[222][223][224][225][226][227] Use of these shells creates an extended-range Bonner sphere spectrometer, which can be used in conjunction with any of the thermal neutron detectors described above to measure secondary neutrons from proton therapy. 94,108,110,[227][228][229][230] Similar to standard Bonner sphere spectrometers, response functions for each detector-sphere combination must be determined, accounting for the high-Z shell. During a neutron measurement, the irradiation must be repeated with each detector-sphere combination, and data must be unfolded to determine a neutron spectrum.…”

Section: B1 Thermal Neutron-based Detectorsmentioning

confidence: 99%

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AAPM TG158: Measurement and calculation of doses outside the treated volume from external‐beam radiation therapy

et al. 2017

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The introduction of advanced techniques and technology in radiotherapy has greatly improved our ability to deliver highly conformal tumor doses while minimizing the dose to adjacent organs at risk. Despite these tremendous improvements, there remains a general concern about doses to normal tissues that are not the target of the radiation treatment; any "nontarget" radiation should be minimized as it offers no therapeutic benefit. As patients live longer after treatment, there is increased opportunity for late effects including second cancers and cardiac toxicity to manifest. Complicating the management of these issues, there are unique challenges with measuring, calculating, reducing, and reporting nontarget doses that many medical physicists may have limited experience with. Treatment planning systems become dramatically inaccurate outside the treatment field, necessitating a measurement or some other means of assessing the dose. However, measurements are challenging because outside the treatment field, the radiation energy spectrum, dose rate, and general shape of the dose distribution (particularly the percent depth dose) are very different and often require special consideration. Neutron dosimetry is also particularly challenging, and common errors in methodology can easily manifest as errors of several orders of magnitude. Task Group 158 was, therefore, formed to provide guidance for physicists in terms of assessing and managing nontarget doses. In particular, the report: (a) highlights major concerns with nontarget radiation; (b) provides a rough estimate of doses associated with different treatment approaches in clinical practice; (c) discusses the uses of dosimeters for measuring photon, electron, and neutron doses; (d) discusses the use of calculation techniques for dosimetric evaluations; (e) highlights techniques that may be considered for reducing nontarget doses; (f) discusses dose reporting; and (g) makes recommendations for both clinical and research practice.

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“…In the diagnostic and therapeutic setting, guidelines and national standards 7,13,14 suffice as a best practice compliance document which provides recommendations on methodologies to quantify leakage radiation and its permissible limit. Although there are many publication in the literature which assess out-of-field radiation doses for therapeutic high energy photons, [15][16][17][18] electrons, 19-21 protons [22][23][24][25] or neutrons 26,27 very few publications assess the issue within objective: The objective of this work is to characterise out-of-field leakage radiation emanating from clinical applicators of the WOmed T-200 kilovoltage therapy machine. methods: To identify points of leakage, radiosensitive film was affixed to the walls and base plate of each applicator.…”

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confidence: 99%

Excessive applicator radiation leakage for a common therapeutic kilovoltage system

Beeksma

Lehmann

2019

BJR

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IntroductIon Kilovoltage X-ray systems are often used in radiotherapy departments for the therapeutic treatment of skin cancers, 1,2 benign diseases and other conditions. 3-5 Typically, these units operate with peak accelerating voltages ranging from 10 to 400 kVp. 6 For a kilovoltage therapy machine, leakage radiation can emanate from radiation penetrating through the head shielding or through any part of the applicator other than the dedicated aperture. Thus leakage radiation can be defined as ionising radiation transmitted through the protective shielding of a radiation source other than the primary beam. 7 Flaws in head/applicator shielding, lack of head/applicator shielding, or an incorrectly positioned X-ray tube insert can lead to increased leakage radiation and consequently increased out-of-field patient dose. Following the installation of a new kilovoltage X-ray system, it is common for the medical physicist to quantify unwanted out-of-field, or leakage radiation emitted from the X-ray tube. 8 As quality control guidance documents 9-12

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A comprehensive spectrometry study of a stray neutron radiation field in scanning proton therapy

Cited by 37 publications

References 20 publications

Systematic out‐of‐field secondary neutron spectrometry and dosimetry in pencil beam scanning proton therapy

Systematic out‐of‐field secondary neutron spectrometry and dosimetry in pencil beam scanning proton therapy

AAPM TG158: Measurement and calculation of doses outside the treated volume from external‐beam radiation therapy

Excessive applicator radiation leakage for a common therapeutic kilovoltage system

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