High-resolution entry and exit surface dosimetry in a 1.5 T MR-linac

Patterson, Elizabeth; Stokes, Peter W.; Cutajar, Dean L; Rosenfeld, Anatoly B.; Baines, John; Metcalfe, Peter E; Powers, Marcus

doi:10.1007/s13246-023-01251-6

Cited by 2 publications

(1 citation statement)

References 54 publications

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“…28 In this work, the term "skin dose" is a clinical term referring to the dose at the recommended ICRP depth. Previous measurements with the MOSkin™ on the Elekta Unity 33 and an inline 1.0 T MR-linac [34][35][36] indicate that the dose-response of the detector is unaffected by the presence of the B 0 . 37…”

Section: Moskin™ Detectormentioning

confidence: 98%

Electron streaming dose measurements and calculations on a 1.5 T MR‐Linac

Patterson,

Powers,

Metcalfe

et al. 2024

J Applied Clin Med Phys

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PurposeTo evaluate the accuracy of different dosimeters and the treatment planning system (TPS) for assessing the skin dose due to the electron streaming effect (ESE) on a 1.5 T magnetic resonance (MR)‐linac.MethodSkin dose due to the ESE on an MR‐linac (Unity, Elekta) was investigated using a solid water phantom rotated 45° in the x‐y plane (IEC61217) and centered at the isocenter. The phantom was irradiated with 1 × 1, 3 × 3, 5 × 5, 10 × 10, and 22 × 22 cm2 fields, gantry at 90°. Out‐of‐field doses (OFDs) deposited by electron streams generated at the entry and exit surface of the angled phantom were measured on the surface of solid water slabs placed ±20.0 cm from the isocenter along the x‐direction. A high‐resolution MOSkin™ detector served as a benchmark due to its shallower depth of measurement that matches the International Commission on Radiological Protection (ICRP) recommended depth for skin dose assessment (0.07 mm). MOSkin™ doses were compared to EBT3 film, OSLDs, a diamond detector, and the TPS where the experimental setup was modeled using two separate calculation parameters settings: a 0.1 cm dose grid with 0.2% statistical uncertainty (0.1 cm, 0.2%) and a 0.2 cm dose grid with 3.0% statistical uncertainty (0.2 cm, 3.0%).ResultsOSLD, film, the 0.1 cm, 0.2%, and 0.2 cm, 3.0% TPS ESE doses, underestimated skin doses measured by the MOSkin™ by as much as –75.3%, –7.0%, –24.7%, and –41.9%, respectively. Film results were most similar to MOSkin™ skin dose measurements.ConclusionsThese results show that electron streams can deposit significant doses outside the primary field and that dosimeter choice and TPS calculation settings greatly influence the reported readings. Due to the steep dose gradient of the ESE, EBT3 film remains the choice for accurate skin dose assessment in this challenging environment.

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Section: Moskin™ Detectormentioning

confidence: 98%

Electron streaming dose measurements and calculations on a 1.5 T MR‐Linac

Patterson,

Powers,

Metcalfe

et al. 2024

J Applied Clin Med Phys

View full text Add to dashboard Cite

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MOSkin dosimetry for an ultra-high dose-rate, very high-energy electron irradiation environment at PEER

Cayley,

Tan,

Petasecca

et al. 2024

Front. Phys.

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FLASH radiotherapy, which refers to the delivery of radiation at ultra-high dose-rates (UHDRs), has been demonstrated with various forms of radiation and is the subject of intense research and development recently, including the use of very high-energy electrons (VHEEs) to treat deep-seated tumors. Delivering FLASH radiotherapy in a clinical setting is expected to place high demands on real-time quality assurance and dosimetry systems. Furthermore, very high-energy electron research currently requires the transformation of existing non-medical accelerators into radiotherapy research environments. Accurate dosimetry is crucial for any such transformation. In this article, we assess the response of the MOSkin, developed by the Center for Medical Radiation Physics, which is designed for on-patient, real-time skin dose measurements during radiotherapy, and whether it exhibits dose-rate independence when exposed to 100 MeV electron beams at the Pulsed Energetic Electrons for Research (PEER) end-station. PEER utilizes the electron beam from a 100 MeV linear accelerator when it is not used as the injector for the ANSTO Australian Synchrotron. With the estimated pulse dose-rates ranging from (7.84±0.21)×105 Gy/s to (1.28±0.03)×107 Gy/s and an estimated peak bunch dose-rate of (2.55±0.06)×108 Gy/s, MOSkin measurements were verified against a scintillating screen to confirm that the MOSkin responds proportionally to the charge delivered and, therefore, exhibits dose-rate independence in this irradiation environment.

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High-resolution entry and exit surface dosimetry in a 1.5 T MR-linac

Cited by 2 publications

References 54 publications

Electron streaming dose measurements and calculations on a 1.5 T MR‐Linac

Electron streaming dose measurements and calculations on a 1.5 T MR‐Linac

MOSkin dosimetry for an ultra-high dose-rate, very high-energy electron irradiation environment at PEER

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