A standard graphite calorimeter for dosimetry in brachytherapy with high dose rate<sup>192</sup>Ir sources

Guerra, A.S.; Loreti, S.; Pimpinella, M.; Quini, M; D’Arienzo, Marco; Astefanoaei, Iordana; Caporali, C.; Bolzan, Chiara; Pagliari, Maria Sole

doi:10.1088/0026-1394/49/5/s179

Cited by 11 publications

(10 citation statements)

References 18 publications

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“…Once again, this was done to keep the Aerrow more in line with ionization chambers, but more importantly, measuring directly in water simplifies the dose conversion process and does away with the need for an additional transfer step. In contrast to all other graphite calorimeters, the Aerrow design incorporates aerogel‐based material as opposed to a vacuum to achieve thermal isolation from the surrounding environment . Air gaps have also been successfully used to provide thermal insulation in graphite calorimeter designs (e.g., NPL's portable photon/electron calorimeter), however this design feature necessitates the inclusion of mechanical supports such as expanded polystyrene beads .…”

Section: Introductionmentioning

confidence: 99%

“…In contrast to all other graphite calorimeters, the Aerrow design incorporates aerogel-based material as opposed to a vacuum to achieve thermal isolation from the surrounding environment. 10,11,[17][18][19][25][26][27][28][29][30] Air gaps have also been successfully used to provide thermal insulation in graphite calorimeter designs (e.g., NPL's portable photon/electron calorimeter), however this design feature necessitates the inclusion of mechanical supports such as expanded polystyrene beads. 23 In this work, aerogel was opted to simplify the assembly process, to maximize the compactness, and to improve the structural robustness of the device.…”

Section: Introductionmentioning

confidence: 99%

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Aerrow: A probe‐format graphite calorimeter for absolute dosimetry of high‐energy photon beams in the clinical environment

et al. 2017

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Purpose: In this work, the design, operation, initial experimental evaluation, and characterization of a small-scale graphite calorimeter probe -herein referred to as the Aerrow -developed for routine use in the clinical environment, are described. Similar in size and shape to a Farmer type cylindrical ionization chamber, the Aerrow represents the first translation of calorimetry intended for direct use by clinical physicists in the radiotherapy clinic. Methods: Based on a numerically optimized design obtained in previous work, a functioning Aerrow prototype capable of two independent modes of operation (quasi-adiabatic and isothermal) was constructed in-house. Reference dose measurements were performed using both Aerrow operation modes in a 6 MV photon beam and were directly compared to results obtained with a calibrated reference-class ionization chamber. The Aerrow was then used to quantify the absolute output of five clinical linac-based photon beams (6 MV, 6 MV FFF, 10 MV, 10 MV FFF, and 15 MV; 63.2% < %dd(10)9 < 76.3%). Linearity, dose rate, and orientation dependences were also investigated. Results: Compared to an ion chamber-derived dose to water of 76.3 AE 0.7 cGy, the average doses measured using the Aerrow were 75.6 AE 0.7 and 74.7 AE 0.7 cGy/MU for the quasi-adiabatic and isothermal modes, respectively. All photon beam output measurements using the Aerrow in waterequivalent phantom agreed with chamber-based clinical reference dosimetry data within combined standard uncertainties. The linearity of the Aerrow's response was characterized by an adjusted R 2 value of 0.9998 in the dose range of 80 cGy to 470 cGy. For the dose-rate dependence, no statistically significant effects were observed in the range of 0.5 Gy/min to 5.4 Gy/min. A relative photon beam quality dependence of 1.7% was calculated in the range of 60 Co to 24 MV (58.4% < %dd(10)9 < 86.8%) using Monte Carlo. Finally, the angular dependence (gantry stationary and detector rotated) of the Aerrow's response was found to be insignificant to within AE0.5%. Conclusions: This work demonstrates the feasibility of using an ion chamber-sized calorimeter as a practical means of measuring absolute dose to water in the radiotherapy clinic. The potential introduction of calorimetry as a mainstream device into the clinical setting is powerful, as this fundamental technique has formed the basis of absorbed dose standards in many countries for decades and could one day form the basis of a new local absorbed dose standard for clinics.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Aerrow: A probe‐format graphite calorimeter for absolute dosimetry of high‐energy photon beams in the clinical environment

et al. 2017

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“…21,22,24,25 Absorbed dose standards for HDR 192 Ir sources based on water and graphite calorimeters have recently been developed in the framework of the European Metrology Research Programme (EMRP) from 2008 to 2011. 26,27 However, these absorbed dose standards have not yet been fully established at primary standards laboratories, and a standard dosimetry protocol based on absorbed dose for brachytherapy has not been published yet.…”

Section: Introductionmentioning

confidence: 99%

Measurement of absorbed dose‐to‐water for an HDR ¹⁹²Ir source with ionization chambers in a sandwich setup

et al. 2013

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“…Once again, this was done to keep the Aerrow more in‐line with ICs, but more importantly, measuring directly in water simplifies the dose conversion process and does away with the need for an additional transfer step. In contrast to all other graphite calorimeters, the Aerrow design incorporates a rigid aerogel‐based material as opposed to a vacuum to achieve thermal isolation from the surrounding environment …”

Section: Introductionmentioning

confidence: 99%

“…In contrast to all other graphite calorimeters, the Aerrow design incorporates a rigid aerogel-based material as opposed to a vacuum to achieve thermal isolation from the surrounding environment. [20][21][22][37][38][39][40][41][42][43][44][45] The purpose of this study is to build a prototype Aerrow and to evaluate its use as an absolute clinical dosimeter of high-energy photon beams while in the presence of a B = 1.5 T magnetic field. In this paper, the design and operating principles of the Aerrow system are presented, and a direct comparison of the detector against two reference-class IC types in a high-energy MRgRT photon beam is described.…”

Section: Introductionmentioning

confidence: 99%

Absolute dosimetry of a 1.5 T MR‐guided accelerator‐based high‐energy photon beam in water and solid phantoms using Aerrow

et al. 2020

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Purpose In this work, the fabrication, operation, and evaluation of a probe‐format graphite calorimeter — herein referred to as Aerrow — as an absolute clinical dosimeter of high‐energy photon beams while in the presence of a B = 1.5 T magnetic field is described. Comparable to a cylindrical ionization chamber (IC) in terms of utility and usability, Aerrow has been developed for the purpose of accurately measuring absorbed dose to water in the clinic with a minimum disruption to the existing clinical workflow. To our knowledge, this is the first reported application of graphite calorimetry to magnetic resonance imaging (MRI)‐guided radiotherapy. Methods Based on a previously numerically optimized and experimentally validated design, an Aerrow prototype capable of isothermal operation was constructed in‐house. Graphite‐to‐water dose conversions as well as magnetic field perturbation factors were calculated using Monte Carlo, while heat transfer and mass impurity corrections and uncertainties were assessed analytically. Reference dose measurements were performed in the absence and presence of a B = 1.5 T magnetic field using Aerrow in the 7 MV FFF photon beam of an Elekta MRI‐linac and were directly compared to the results obtained using two calibrated reference‐class IC types. The feasibility of performing solid phantom‐based dosimetry with Aerrow and the possible influence of clearance gaps is also investigated by performing reference‐type dosimetry measurements for multiple rotational positions of the detector and comparing the results to those obtained in water. Results In the absence of the B‐field, as well as in the parallel orientation while in the presence of the B‐field, the absorbed dose to water measured using Aerrow was found to agree within combined uncertainties with those derived from TG‐51 using calibrated reference‐class ICs. Statistically significant differences on the order of (2–4)%, however, were observed when measuring absorbed dose to water using the ICs in the perpendicular orientation in the presence of the B‐field. Aerrow had a peak‐to‐peak response of about 0.5% when rotated within the solid phantom regardless of whether the B‐field was present or not. Conclusions This work describes the successful use of Aerrow as a straightforward means of measuring absolute dose to water for large high‐energy photon fields in the presence of a 1.5 T B‐field to a greater accuracy than currently achievable with ICs. The detector‐phantom air gap does not appear to significantly influence the response of Aerrow in absolute terms, nor does it contribute to its rotational dependence. This work suggests that the accurate use of solid phantoms for absolute point dose measurement is possible with Aerrow.

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A standard graphite calorimeter for dosimetry in brachytherapy with high dose rate¹⁹²Ir sources

Cited by 11 publications

References 18 publications

Aerrow: A probe‐format graphite calorimeter for absolute dosimetry of high‐energy photon beams in the clinical environment

Aerrow: A probe‐format graphite calorimeter for absolute dosimetry of high‐energy photon beams in the clinical environment

Measurement of absorbed dose‐to‐water for an HDR ¹⁹²Ir source with ionization chambers in a sandwich setup

Absolute dosimetry of a 1.5 T MR‐guided accelerator‐based high‐energy photon beam in water and solid phantoms using Aerrow

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A standard graphite calorimeter for dosimetry in brachytherapy with high dose rate192Ir sources

Cited by 11 publications

References 18 publications

Aerrow: A probe‐format graphite calorimeter for absolute dosimetry of high‐energy photon beams in the clinical environment

Aerrow: A probe‐format graphite calorimeter for absolute dosimetry of high‐energy photon beams in the clinical environment

Measurement of absorbed dose‐to‐water for an HDR 192Ir source with ionization chambers in a sandwich setup

Absolute dosimetry of a 1.5 T MR‐guided accelerator‐based high‐energy photon beam in water and solid phantoms using Aerrow

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A standard graphite calorimeter for dosimetry in brachytherapy with high dose rate¹⁹²Ir sources

Measurement of absorbed dose‐to‐water for an HDR ¹⁹²Ir source with ionization chambers in a sandwich setup