Out-of-Field Doses Produced by a Proton Scanning Beam Inside Pediatric Anthropomorphic Phantoms and Their Comparison With Different Photon Modalities

Knežević, Željka; Stolarczyk, Liliana; Ambrožová, Iva; Caballero-Pacheco, Miguel Ángel; Davídková, Marie; Saint-Hubert, Marijke De; Domingo, C.; Jeleń, Kinga; Kopeć, Renata; Krzempek, Dawid; Majer, Marija; Miljanić, Saveta; Mojżeszek, Natalia; Romero-Expósito, Maite; Martínez-Rovira, I.; Harrison, R. M.; Olko, P.

doi:10.3389/fonc.2022.904563

Cited by 5 publications

(12 citation statements)

References 52 publications

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“…In all cases investigated by WG9 out-of-field organ doses were assessed inside anthropomorphic phantoms for the same target (6 cm diameter spherical PTV with the center on the left anterior side of the head). This work was recently summarized by Knezevic et al ( 2022 ). Table 1 presents example data for out-of-field dose levels estimated by EURADOS WG9 for 3D-CRT, IMRT (Majer et al 2017 ) and Intensity Modulated Proton Therapy (IMPT) with PBS technique (Knezevic et al 2018 ).…”

Section: Out-of-field Effects: Clinical Contextmentioning

confidence: 86%

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Out-of-field effects: lessons learned from partial body exposure

Pazzaglia

Eidemüller

Lumniczky³

et al. 2022

Radiat Environ Biophys

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Partial body exposure and inhomogeneous dose delivery are features of the majority of medical and occupational exposure situations. However, mounting evidence indicates that the effects of partial body exposure are not limited to the irradiated area but also have systemic effects that are propagated outside the irradiated field. It was the aim of the “Partial body exposure” session within the MELODI workshop 2020 to discuss recent developments and insights into this field by covering clinical, epidemiological, dosimetric as well as mechanistic aspects. Especially the impact of out-of-field effects on dysfunctions of immune cells, cardiovascular diseases and effects on the brain were debated. The presentations at the workshop acknowledged the relevance of out-of-field effects as components of the cellular and organismal radiation response. Furthermore, their importance for the understanding of radiation-induced pathologies, for the discovery of early disease biomarkers and for the identification of high-risk organs after inhomogeneous exposure was emphasized. With the rapid advancement of clinical treatment modalities, including new dose rates and distributions a better understanding of individual health risk is urgently needed. To achieve this, a deeper mechanistic understanding of out-of-field effects in close connection to improved modelling was suggested as priorities for future research. This will support the amelioration of risk models and the personalization of risk assessments for cancer and non-cancer effects after partial body irradiation.

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Section: Out-of-field Effects: Clinical Contextmentioning

confidence: 86%

“…For 3D-CRT, IMRT and proton active scanning radiotherapy data are adapted from Knezevic et al ( 2022 ). For passive scattering proton radiotherapy data are adapted from Sayah et al ( 2014 ) assuming 10% contribution from secondary photons to total organ equivalent dose.…”

Section: Out-of-field Effects: Clinical Contextmentioning

confidence: 99%

Out-of-field effects: lessons learned from partial body exposure

Pazzaglia

Eidemüller

Lumniczky³

et al. 2022

Radiat Environ Biophys

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“…14 The study found a decreased total organ dose equivalent for intensity modulated proton therapy (IMPT) with pencil beam scanning compared to photon therapy. 14 Compared to phantom measurements taken with bubble detectors at the Indiana University Cyclotron double scattering system, reported by Mesoloras et al, the fetal dose is reduced from the 25-871 µSv per Gy to the maximum 64.7 µSv per 2 Gy(RBE) reported here. 15 With previous literature demonstrating that passively scattered proton therapy is not associated with a significant increase in secondary malignancies when compared with photon therapy, 3,16 our work suggests that this risk is further reduced when using pencil beam scanning systems, such as the Mevion S250i system.…”

Section: Discussionmentioning

confidence: 99%

“…Additional work by Knežević et al. demonstrated the differences in dose for proton therapy compared to 3D conformal radiation therapy, IMRT, and Gamma Knife (Elekta, Stockholm, Sweden) with the proton therapy plan containing two coplanar beams treating a brain lesion in a pediatric phantom 14 . The study found a decreased total organ dose equivalent for intensity modulated proton therapy (IMPT) with pencil beam scanning compared to photon therapy 14 .…”

Section: Discussionmentioning

confidence: 99%

“…demonstrated the differences in dose for proton therapy compared to 3D conformal radiation therapy, IMRT, and Gamma Knife (Elekta, Stockholm, Sweden) with the proton therapy plan containing two coplanar beams treating a brain lesion in a pediatric phantom 14 . The study found a decreased total organ dose equivalent for intensity modulated proton therapy (IMPT) with pencil beam scanning compared to photon therapy 14 . Compared to phantom measurements taken with bubble detectors at the Indiana University Cyclotron double scattering system, reported by Mesoloras et al., the fetal dose is reduced from the 25–871 μSv per Gy to the maximum 64.7 μSv per 2 Gy(RBE) reported here 15 .…”

Section: Discussionmentioning

confidence: 99%

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Measurements of fetal dose with Mevion S250i proton therapy system with HYPERSCAN

Hopfensperger

Paxton

et al. 2023

J Applied Clin Med Phys

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To characterize potential dose to the fetus for all modes of delivery (dynamic adaptive aperture, static adaptive aperture, and no adaptive aperture) for the Mevion S250i Proton Therapy System with HYPERSCAN and compare the findings with those of other available proton systems. Materials and Methods: Fetal dose measurements were performed for all three modes of dose delivery on the Mevion S250i Proton therapy system with HYPERSCAN (static aperture, dynamic aperture and uncollimated). Standard treatment plans were created in RayStation for a left-sided brain lesion treated with a vertex field, a left lateral field, and a posterior field. Measurements were performed using WENDI and the RANDO with the detector placed at representative locations to mimic the growth and movement of the fetus at different gestational stages. Results:The fetal dose measurements varied with fetus position and the largest measured dose was 64.7 µSv per 2 Gy (RBE) fraction using the dynamic aperture. The smallest estimated fetal dose was 45.0 µSv per 2 Gy (RBE) at the base of the RANDO abdomen (47 cm from isocenter to the outer width of WENDI and 58.5 cm from the center of the WENDI detector) for the static aperture delivery. The vertex fields at all depths had larger contributions to the total dose than the other two and the dynamic aperture plans resulted in the highest dose measured for all depths. Conclusion:The reported doses are lower than reported doses using a doublescattering system. This work suggests that avoiding vertex fields and using the static aperture will help minimize dose to the fetus.

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Thermal neutron detection and track recognition method in reference and out-of-field radiotherapy FLASH electron fields using Timepix3 detectors

Oancea,

Solc,

Bourgouin

et al. 2023

Phys. Med. Biol.

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Objective. This work presents a method for enhanced detection, imaging, and measurement of the thermal neutron flux. Approach. Measurements were performed in a water tank, while the detector is positioned out-of-field of a 20 MeV ultra-high pulse dose rate electron beam. A semiconductor pixel detector Timepix3 with a silicon sensor partially covered by a 6LiF neutron converter was used to measure the flux, spatial, and time characteristics of the neutron field. To provide absolute measurements of thermal neutron flux, the detection efficiency calibration of the detectors was performed in a reference thermal neutron field. Neutron signals are recognized and discriminated against other particles such as gamma rays and x-rays. This is achieved by the resolving power of the pixel detector using machine learning algorithms and high-resolution pattern recognition analysis of the high-energy tracks created by thermal neutron interactions in the converter. Main results. The resulting thermal neutrons equivalent dose was obtained using conversion factor (2.13(10) pSv·cm2) from thermal neutron fluence to thermal neutron equivalent dose obtained by Monte Carlo simulations. The calibrated detectors were used to characterize scattered radiation created by electron beams. The results at 12.0 cm depth in the beam axis inside of the water for a delivered dose per pulse of 1.85 Gy (pulse length of 2.4 μs) at the reference depth, showed a contribution of flux of 4.07(8) × 103 particles·cm−2·s−1 and equivalent dose of 1.73(3) nSv per pulse, which is lower by ∼9 orders of magnitude than the delivered dose. Significance. The presented methodology for in-water measurements and identification of characteristic thermal neutrons tracks serves for the selective quantification of equivalent dose made by thermal neutrons in out-of-field particle therapy.

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Out-of-Field Doses Produced by a Proton Scanning Beam Inside Pediatric Anthropomorphic Phantoms and Their Comparison With Different Photon Modalities

Cited by 5 publications

References 52 publications

Out-of-field effects: lessons learned from partial body exposure

Out-of-field effects: lessons learned from partial body exposure

Measurements of fetal dose with Mevion S250i proton therapy system with HYPERSCAN

Thermal neutron detection and track recognition method in reference and out-of-field radiotherapy FLASH electron fields using Timepix3 detectors

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