Neutron Radiation Dose Measurements in a Scanning Proton Therapy Room: Can Parents Remain Near Their Children During Treatment?

Mares, V.; Farah, Jad; Saint-Hubert, Marijke De; Domański, Szymon; Domingo, C.; Dommert, Martin; Kłodowska, Magdalena; Krzempek, Katarzyna; Kuć, Michał; Martínez-Rovira, I.; Michaś, Edyta; Mojżeszek, Natalia; Murawski, Łukasz; Ploc, Ondřej; Romero-Expósito, Maite; Tisi, Marco; Trompier, F.; Hoey, Olivier Van; Ryckeghem, Laurent Van; Wieluński, M.; Harrison, R. M.; Stolarczyk, Liliana; Olko, P.

doi:10.3389/fonc.2022.903706

Cited by 9 publications

(9 citation statements)

References 38 publications

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“…Overall trends obtained for the secondary neutrons generated by primary oxygen beams, both for the pristine Bragg peaks and the SOBPs, are in agreement with the previous study using primary protons, helium and carbon ions (Vedelago et al 2022). The secondary neutrons spectra follow the typical shape of energy distributions of secondary neutrons encountered in ion beam therapy, with one peak in the TE region and another peak in the FR region, with a flat thermalization region in between (Mares et al 2022, Shrestha et al 2022. In the obtained spectra, the evaporation peak is usually eclipsed by the cascade peak, as no additional room elements or room walls were considered (Englbrecht et al 2021).…”

Section: Energy Distribution Of the Secondary Neutronssupporting

confidence: 88%

A Monte Carlo study on the secondary neutron generation by oxygen ion beams for radiotherapy and its comparison to lighter ions

Geser,

Stabilini,

Christensen

et al. 2024

Phys. Med. Biol.

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Objective: To study the secondary neutrons generated by primary oxygen beams for cancer treatment and compare the results to those from primary protons, helium, and carbon ions. This information can provide useful insight into the positioning of neutron detectors in phantom for future experimental dose assessments.Approach: Mono-energetic oxygen beams and spread-out Bragg peaks were simulated using the Monte Carlo particle transport codes FLUKA, TOPAS, and MCNP, with energies within the therapeutic range. The energy and angular distribution of the secondary neutrons were quantified. Main results: The secondary neutron spectra generated by primary oxygen beams present the same qualitative trend as for other primary ions. The energy distributions resemble continuous spectra with one peak in the thermal/epithermal region, and one other peak in the fast/relativistic region, with the most probable energy ranging from 94 MeV up to 277 MeV and maximum energies exceeding 500~MeV. The angular distribution of the secondary neutrons is mainly downstream-directed for the fast/relativistic energies, whereas the thermal/epithermal neutrons present a more isotropic propagation. When comparing the four different primary ions, there is a significant increase in the most probable energy as well as the number of secondary neutrons per primary particle when increasing the mass of the primaries.Significance: Most previous studies have only presented results of secondary neutrons generated by primary proton beams. In this work, secondary neutrons generated by primary oxygen beams are presented, and the obtained energy and angular spectra are added as supplementary material. Furthermore, a comparison of the secondary neutron generation by the different primary ions is given, which can be used as the starting point for future studies on treatment plan comparison and secondary neutron dose optimization. The distal penumbra after the maximum dose deposition appears to be a suitable location for in-phantom dose assessments. 

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Section: Energy Distribution Of the Secondary Neutronssupporting

confidence: 88%

A Monte Carlo study on the secondary neutron generation by oxygen ion beams for radiotherapy and its comparison to lighter ions

Geser,

Stabilini,

Christensen

et al. 2024

Phys. Med. Biol.

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“…Neutrons created during proton‐RT have a wide range of energies, ranging from thermal energies (<0.4 eV) up to the maximum proton energy (up to 250 MeV) 9,10 . As neutrons are indirectly ionizing, they will deposit energy by creating ionizing secondary particles.…”

Section: Out‐of‐field Dosimetry During Proton‐rtmentioning

confidence: 99%

“…Neutrons created during proton‐RT have a wide range of energies, ranging from thermal energies (<0.4 eV) up to the maximum proton energy (up to 250 MeV). 9 , 10 As neutrons are indirectly ionizing, they will deposit energy by creating ionizing secondary particles. These nuclear reaction cross‐sections strongly depend on the neutron energy, causing the relative biological effectiveness (RBE) of neutrons to vary greatly for different neutron energies.…”

Section: Out‐of‐field Dosimetry During Proton‐rtmentioning

confidence: 99%

Challenges and opportunities for proton therapy during pregnancy

Blommaert

Saint-Hubert

Depuydt

et al. 2023

Acta Obstet Gynecol Scand

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During pregnancy, the use of radiation therapy for cancer treatment is often considered impossible due to the assumed associated fetal risks. However, suboptimal treatment of pregnant cancer patients and unjustifiable delay in radiation therapy until after delivery can be harmful for both patient and child. In non‐pregnant patients, proton‐radiation therapy is increasingly administered because of its favorable dosimetric properties compared with photon‐radiation therapy. Although data on the use of pencil beam scanning proton‐radiation therapy during pregnancy are scarce, different case reports and dosimetric studies have indicated a more than 10‐fold reduction in fetal radiation exposure compared with photon‐radiation therapy. Nonetheless, the implementation of proton‐radiation therapy during pregnancy requires complex fetal dosimetry for the neutron‐dominated out‐of‐field radiation dose and faces a lack of clinical guidelines. Further exploration and standardization of proton‐radiation therapy during pregnancy will be necessary to improve radiotherapeutic management of pregnant women with cancer and further reduce risks for their offspring.

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“…In the absence of robust shielding, these radiation fields could potentially present significant risks, not only to the healthcare professionals but also to the general public. It is worth noting that the effect of the secondary neutron field has been studied in the following studies: Agosteo et al (1998), Hälg and Schneider (2020), and Mares et al 2022. Agosteo et al reported that the estimated secondary gamma-ray dose was approximately one-tenth of the combined total dose from neutrons and gamma rays.…”

Section: Introductionmentioning

confidence: 99%

Dose Measurements at Provision Proton Therapy Center

Burahmah,

Heilbronn

2024

Health Physics

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Proton therapy is an advanced method for treating cancerous tumors, and its adoption has expanded significantly in recent years. The production of high-energy protons, however, may result in the creation of secondary neutrons and gamma rays. Hence, ensuring radiation safety at proton therapy centers is crucial, with shielding playing a vital role. This study aimed to evaluate the efficacy of the shielding implemented at the Provision Proton Therapy center in Knoxville, TN, USA. For this purpose, we measured and compared gamma ray radiation levels within the treatment room and the facility’s roof. These measurements were conducted using a NaI(Tl) scintillator detector. The PHITS Monte Carlo code was used to deconvolute the incident spectrum using detector response functions. Findings reveal that the facility’s shielding effectively protects the general public from gamma ray radiation, with the effective dose within the treatment room being minimal and dose on the roof was comparable to background radiation levels. However, it is important to note that this study did not address the issue of secondary neutron radiation field, which is an important aspect of dose and radiation safety in proton therapy centers.

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Neutron Radiation Dose Measurements in a Scanning Proton Therapy Room: Can Parents Remain Near Their Children During Treatment?

Cited by 9 publications

References 38 publications

A Monte Carlo study on the secondary neutron generation by oxygen ion beams for radiotherapy and its comparison to lighter ions

A Monte Carlo study on the secondary neutron generation by oxygen ion beams for radiotherapy and its comparison to lighter ions

Challenges and opportunities for proton therapy during pregnancy

Dose Measurements at Provision Proton Therapy Center

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