Consistency in reference radiotherapy dosimetry: resolution of an apparent conundrum when<sup>60</sup>Co is the reference quality for charged-particle and photon beams

Andreo, Pedro; Wulff, J; Burns, D T; Palmans, Hugo

doi:10.1088/0031-9155/58/19/6593

Cited by 50 publications

(87 citation statements)

References 76 publications

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“…The results of f ‐sum rule and ps ‐sum rule are 10.51 and 1.037, respectively, with relative errors being 5.1% and 3.7%. The calculated mean excitation energy I which is defined by,

\ln I = \frac{\int_{0}^{\infty} ω \ln ω Im (}{- 1 / ε ()(, ω)) d ω}{\int_{0}^{\infty} ω Im (}{- 1 / ε ()(, ω)) d ω},

is 76.20 eV, which compares well with the reported ones: 71.8 eV, 75 ± 3 eV, 77.8 eV, 78 ± 2 eV . The upper limit of integration in Eq.…”

Section: Methodssupporting

confidence: 80%

A comparative study on Monte Carlo simulations of electron emission from liquid water

et al. 2019

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Purpose Liquid water being the major constituent of the human body, is of fundamental importance in radiobiological research. Hence, the knowledge of electron‐water interaction physics and particularly the secondary electron yield is essential. However, to date, only very little is known experimentally on the low energy electron interaction with liquid water because of certain practical limitations. The purpose of this study was to gain some useful information about electron emission from water using a Monte Carlo (MC) simulation technique that can numerically model electron transport trajectories in water. Methods In this study, we have performed MC simulations of electron emission from liquid water in the primary energy range of 50 eV–30 keV by using two different codes, i.e., a classical trajectory MC (CMC) code developed in our laboratory and the Geant4‐DNA (G4DNA) code. The calculated secondary electron yield and electron backscattering coefficient are compared with experimental results wherever applicable to verify the validity of physical models for the electron‐water interaction. Results The secondary electron yield vs. primary energy curves calculated using the two codes present the same generic curve shape as that of metals but in rather different absolute values. G4DNA underestimates the secondary electron yield due to the application of one step thermalization model by setting a cutoff energy at 10 eV so that the low energy losses due to phonon excitations are omitted. Our CMC code, using a full energy loss spectrum to model electron inelastic scattering, allows the simulation of individual phonon scattering events for very low energy losses down to 10 meV, which then enables the calculated secondary electron yields much closer to the experimental data and also gives quite reasonable energy distribution curve of secondary electrons. Conclusions It is concluded that full dielectric function data at low energy loss values below 10 eV are recommended for modeling of low energy electrons in liquid water.

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“…The results of f ‐sum rule and ps ‐sum rule are 10.51 and 1.037, respectively, with relative errors being 5.1% and 3.7%. The calculated mean excitation energy I which is defined by,

\ln I = \frac{\int_{0}^{\infty} ω \ln ω Im (}{- 1 / ε ()(, ω)) d ω}{\int_{0}^{\infty} ω Im (}{- 1 / ε ()(, ω)) d ω},

is 76.20 eV, which compares well with the reported ones: 71.8 eV, 75 ± 3 eV, 77.8 eV, 78 ± 2 eV . The upper limit of integration in Eq.…”

Section: Methodssupporting

confidence: 80%

A comparative study on Monte Carlo simulations of electron emission from liquid water

et al. 2019

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“…These are known to differ from recent measurements and calculations by a small amount (within their stated uncertainty) [19], mainly because the chamber stem was not included in the calculation of k Q . When Monte Carlo calculations are used to derive k Q factors and the stem is included, the results are in better agreement with AR-PANSA’s and other laboratories’ measured values.…”

Section: Discussionmentioning

confidence: 82%

“…A recent article by Andreo is an exception [19]. Nevertheless, improvements in the consistency and accuracy of ionisation chamber calibrations are considered to be important in the clinic.…”

Section: Discussionmentioning

confidence: 99%

Direct megavoltage photon calibration service in Australia

Butler¹,

Ramanathan²,

Oliver³

et al. 2014

Australas Phys Eng Sci Med

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The Australian Radiation Protection and Nuclear Safety Agency (ARPANSA) maintains the Australian primary standard of absorbed dose. Until recently, the standard was used to calibrate ionisation chambers only in 60Co gamma rays. These chambers are then used by radiotherapy clinics to determine linac output, using a correction factor (kQ) to take into account the different spectra of 60Co and the linac. Over the period 2010–2013, ARPANSA adapted the primary standard to work in megavoltage linac beams, and has developed a calibration service at three photon beams (6, 10 and 18 MV) from an Elekta Synergy linac. We describe the details of the new calibration service, the method validation and the use of the new calibration factors with the International Atomic Energy Agency’s TRS-398 dosimetry Code of Practice. The expected changes in absorbed dose measurements in the clinic when shifting from 60Co to the direct calibration are determined. For a Farmer chamber (model 2571), the measured chamber calibration coefficient is expected to be reduced by 0.4, 1.0 and 1.1 % respectively for these three beams when compared to the factor derived from 60Co. These results are in overall agreement with international absorbed dose standards and calculations by Muir and Rogers in 2010 of kQ factors using Monte Carlo techniques. The reasons for and against moving to the new service are discussed in the light of the requirements of clinical dosimetry.

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“…The factors for the Addendum to TG‐51 were determined using full MC calculations incorporating detailed information about the chamber to better reflect the true chamber geometry 14, 19. In contrast, the result for IAEA TRS‐398 was based on a semi‐analytic approach that did not consider all details of the chamber geometry 5, 36. Perturbation correction factors used in the expression for k Q for JSMP 12 were obtained from MC calculations, with the exception of a wall correction factor derived by semi‐analytical expressions 20.…”

Section: Discussionmentioning

confidence: 99%

“…Therefore, the difference in the k Q factors for the three protocols appears due to the difference between the perturbation factors obtained by a semi‐analytic approach and MC calculations. Several studies14, 15, 16, 36 have compared individual perturbation correction factors obtained using MC calculations for cylindrical chambers with those obtained using a semi‐analytic approach, such as that used in IAEA TRS‐398 and AAPM TG‐51. For a 60 Co beam, the value of the replacement factor derived from MC calculations by Wang and Rogers17 was 0.5% higher than the AAPM TG‐51 value and approximately 1% higher than the IAEA TRS‐398 value.…”

Section: Discussionmentioning

confidence: 99%

Comparison of AAPM Addendum to TG‐51, IAEA TRS‐398, and JSMP 12: Calibration of photon beams in water

Kinoshita

Oguchi

Nishimoto

et al. 2017

J Applied Clin Med Phys

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The American Association of Physicists in Medicine (AAPM) Working Group on TG‐51 published an Addendum to the AAPM's TG‐51 protocol (Addendum to TG‐51) in 2014, and the Japan Society of Medical Physics (JSMP) published a new dosimetry protocol JSMP 12 in 2012. In this study, we compared the absorbed dose to water determined at the reference depth for high‐energy photon beams following the recommendations given in AAPM TG‐51 and the Addendum to TG‐51, IAEA TRS‐398, and JSMP 12. This study was performed using measurements with flattened photon beams with nominal energies of 6 and 10 MV. Three widely used ionization chambers with different compositions, Exradin A12, PTW 30013, and IBA FC65‐P, were employed. Fully corrected charge readings obtained for the three chambers according to AAPM TG‐51 and the Addendum to TG‐51, which included the correction for the radiation beam profile (P rp), showed variations of 0.2% and 0.3% at 6 and 10 MV, respectively, from the readings corresponding to IAEA TRS‐398 and JSMP 12. The values for the beam quality conversion factor k Q obtained according to the three protocols agreed within 0.5%; the only exception was a 0.6% difference between the results obtained at 10 MV for Exradin A12 according to IAEA TRS‐398 and AAPM TG‐51 and the Addendum to TG‐51. Consequently, the values for the absorbed dose to water obtained for the three protocols agreed within 0.4%; the only exception was a 0.6% difference between the values obtained at 10 MV for PTW 30013 according to AAPM TG‐51 and the Addendum to TG‐51, and JSMP 12. While the difference in the absorbed dose to water determined by the three protocols depends on the kQ and P rp values, the absorbed dose to water obtained according to the three protocols agrees within the relative uncertainties for the three protocols.

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Consistency in reference radiotherapy dosimetry: resolution of an apparent conundrum when⁶⁰Co is the reference quality for charged-particle and photon beams

Cited by 50 publications

References 76 publications

A comparative study on Monte Carlo simulations of electron emission from liquid water

A comparative study on Monte Carlo simulations of electron emission from liquid water

Direct megavoltage photon calibration service in Australia

Comparison of AAPM Addendum to TG‐51, IAEA TRS‐398, and JSMP 12: Calibration of photon beams in water

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Consistency in reference radiotherapy dosimetry: resolution of an apparent conundrum when60Co is the reference quality for charged-particle and photon beams

Cited by 50 publications

References 76 publications

A comparative study on Monte Carlo simulations of electron emission from liquid water

A comparative study on Monte Carlo simulations of electron emission from liquid water

Direct megavoltage photon calibration service in Australia

Comparison of AAPM Addendum to TG‐51, IAEA TRS‐398, and JSMP 12: Calibration of photon beams in water

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Consistency in reference radiotherapy dosimetry: resolution of an apparent conundrum when⁶⁰Co is the reference quality for charged-particle and photon beams