The saturation loss for plane parallel ionization chambers at high dose per pulse values

Piermattei, Angelo; Canne, Stefania Delle; Azario, L.; Russo, A.; Fidanzio, A.; Miceli, R; Soriani, A.; Orvieto, A; Fantini, M.

doi:10.1088/0031-9155/45/7/312

Cited by 58 publications

(54 citation statements)

References 11 publications

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“…This calculation procedure has been considered to be appropriate once the linear dependence of

1 / M

and

1 / V

required by the Boag theory is determined to be satisfied. Some publications show that this linear dependence is not valid over a certain threshold voltage for various chambers, both plane‐parallel ( 15 , 20 – 23 ) and cylindrical. ( 24 , 25 ) …”

Section: Resultsmentioning

confidence: 99%

Study of the uncertainty in the determination of the absorbed dose to water during external beam radiotherapy calibration

Castro

Garcı́a-Vicente

Mínguez

et al. 2008

J Applied Clin Med Phys

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To achieve a good clinical outcome in radiotherapy treatment, a certain accuracy in the dose delivered to the patient is required. Therefore, it is necessary to keep the uncertainty in each of the steps of the process inside some acceptable values, which implies as low a global uncertainty as possible. The work reported here focused on the uncertainty evaluation of absorbed dose to water in the routine calibration for clinical beams in the range of energies used in external‐beam radiotherapy. With this aim, we considered various uncertainty components (corrected electrometer reading, calibration factor, beam quality correction factor, and reference conditions) associated with beam calibration. Results show a typical uncertainty in the determination of absorbed dose to water during beam calibration of approximately 1.3% for photon beams and 1.5% for electron beams (k=1 in both cases) when the ND,w formalism is used and kQ,Q0 is calculated theoretically. These values may vary depending on the uncertainty provided by the standards laboratory for calibration factor, which is shown in the work. For primary standards based on clinical linear accelerator beam energies, the uncertainty in this step of the process could be placed close to 1.0%. We also discuss the possibility of an uncertainty reduction with the adoption of the absorbed dose to water formalism as compared with the air kerma formalism.PACS numbers: 87.53.Dq, 87.53.Hv

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“…This calculation procedure has been considered to be appropriate once the linear dependence of

1 / M

and

1 / V

Section: Resultsmentioning

confidence: 99%

Study of the uncertainty in the determination of the absorbed dose to water during external beam radiotherapy calibration

Castro

Garcı́a-Vicente

Mínguez

et al. 2008

J Applied Clin Med Phys

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show abstract

“…This fact sets a limit to the employ of ionisation chambers for the beams calibration in terms of dose per MU. In particular, due to the high density of electric charge produced in the chamber's volume per radiation pulse, the correction factor for ion recombination can be largely overestimated if the correction methods recommended by the international protocols are used 15,39,40 . For this reason, for the measure of dose to water in reference conditions, ionisation chambers cannot be employed and no published dosimetry protocol can be used.…”

Section: Dedicated Acceleratorsmentioning

confidence: 99%

“…Ionisation chambers, as previously reported, are advised against: due to the high density of electric charges produced in the volume of the chamber for each radiation pulse, in fact, the correction factor for the ion recombination 11,15,39,40 can be largely overestimated when the correction methods recommended in the international dosimetry protocols are applied. The recombination factor, moreover, may vary depending on the depth in the phantom of the point of measurement.…”

Section: Dedicated Acceleratorsmentioning

confidence: 99%

“…Defining the physical characteristics of the electron beams used for IORT requires an accurate initial dosimetric study 14 , particularly with the new mobile accelerator 15 ; moreover, an accurate protocol for a regular quality control of the equipment based on international recommendations has to be prepared 16 . The definition of the procedures to be followed during the execution of IORT and its documentation is essential for the optimisation of the programme of quality assurance in this radiotherapy treatment.…”

Section: Introduction To Intra-operative Radiotherapymentioning

confidence: 99%

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Guidelines for quality assurance in intra-operative radiation therapy

Rosi¹,

Viti²

2004

Oncología (Barc.)

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“…However, the two‐voltage method has been shown to be notably inaccurate for both low electric field strength (6) and very large doses per pulse 14 , 15 . Piermattei et al, (14) for example, showed substantial error in the recombination correction estimated by the two‐voltage technique for a high dose‐per‐pulse intraoperative electron therapy accelerator. That error corresponded to a 20% difference in dose to water measured by several ion chambers, as compared to a dose‐per‐pulse independent dosimeter.…”

Section: Introductionmentioning

confidence: 99%

Ion recombination correction factors () for Varian TrueBeam high‐dose‐rate therapy beams

Kry

Popple

Molineu

et al. 2012

J Applied Clin Med Phys

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Ion recombination is approximately corrected for in the Task Group 51 protocol by Pion, which is calculated by a two‐voltage measurement. This measurement approach may be a poor estimate of the true recombination, particularly if Pion is large (greater than 1.05). Concern exists that Pion in high‐dose‐per‐pulse beams, such as flattening filter free (FFF) beams, may be unacceptably high, rendering the two‐voltage measurement technique inappropriate. Therefore, Pion was measured for flattened beams of 6, 10, 15, and 18 MV and for FFF beams of 6 and 10 MV. The values for the FFF beams were verified with 1/V versus 1/Q curves (Jaffé plots). Pion was also measured for electron beams of 6, 12, 16, 18, and 20 MeV on a traditional accelerator, as well as on the high‐dose‐rate Varian TrueBeam accelerator. The measurements were made at a range of depths and with PTW, NEL, and Exradin Farmer‐type chambers. Consistent with the increased dose per pulse, Pion was higher for FFF beams than for flattening filter beams. However, for all beams, measurement locations, and chambers examined, Pion never exceeded 1.018. Additionally, Pion was always within 0.3% of the recombination calculated from the Jaffé plots. We conclude that ion recombination can be adequately accounted for in high‐dose‐rate FFF beams using Pion determined with the standard two‐voltage technique.PACS numbers: 87.56.‐v, 87.56.Da

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The saturation loss for plane parallel ionization chambers at high dose per pulse values

Cited by 58 publications

References 11 publications

Study of the uncertainty in the determination of the absorbed dose to water during external beam radiotherapy calibration

Study of the uncertainty in the determination of the absorbed dose to water during external beam radiotherapy calibration

Guidelines for quality assurance in intra-operative radiation therapy

Ion recombination correction factors () for Varian TrueBeam high‐dose‐rate therapy beams

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