Clinical commissioning of intensity‐modulated proton therapy systems: Report of AAPM Task Group 185

Farr, J; Moyers, Michael F.; Allgower, C.; Bues, Martin; Hsi, W; Jin, H; Mihailidis, Dimitris; Lu, Hsiao‐Ming; Newhauser, Wayne D.; Slopsema, R; Yeung, Daniel; Zhu, Xiaorong Ronald

doi:10.1002/mp.14546

Cited by 34 publications

(43 citation statements)

References 187 publications

(355 reference statements)

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“…The PBS delivery system was implemented in the second gantry room at our institute beginning in May 2017. We describe the characteristics of PBS beam delivery and the commissioning of TPS 8 in a separate section. Based on the database of recorded PBS‐QA measurements, the numbers of patients and of PBS‐QA measurements are sorted and listed in Table 1 .…”

Section: Methodsmentioning

confidence: 99%

The root cause analysis on failed patient‐specific measurements of pencil beam scanning protons using a 2D detection array with finite size ionization chambers

Ricci

Hsi

et al. 2021

J Applied Clin Med Phys

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Section: Methodsmentioning

confidence: 99%

The root cause analysis on failed patient‐specific measurements of pencil beam scanning protons using a 2D detection array with finite size ionization chambers

Ricci

Hsi

et al. 2021

J Applied Clin Med Phys

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“…The solid water equivalent materials (SW 1471 and SW 1472, St. Bartholomew's Hospital, London, UK) used in the phantom are epoxy resin based and were previously optimised to match the proton nuclear interaction cross sections of water [13]. Both were shown to provide better water-equivalence in terms of proton fluence compared to commercial solid water equivalent materials [14]. While it was concluded that SW 1472 was the most water equivalent, it is inhomogeneous in nature due to the practicalities of mixing compounds into the epoxy resin mixture, which results in batch variability that impact the measured range and TPS calculations.…”

Section: Phantom Designmentioning

confidence: 99%

“…As proton range estimation is a main source of uncertainty, it is important to validate range measurements in more realistic and complex phantom geometries to enable the evaluation of the full patient workflow as a means of an end-to-end audit [11]. Range measurements are typically performed with an ionisation chamber in a water phantom or with the use of array based detectors placed behind slabs of either water, tissue-substitute materials or real biological tissues [12][13][14]. But radiochromic film has also been previously shown to have potential as a detector for measuring proton range [15,16] and the response of different types of radiochromic film (MD 55, MD 55 2, HD 810, EBT, EBT2, EBT3, EBT XD films) in proton beams has been well documented [15][16][17][18][19].…”

Section: Introductionmentioning

confidence: 99%

Development of a heterogeneous phantom to measure range in clinical proton therapy beams

Cook

Lambert²,

Thomas

et al. 2022

Physica Medica

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“…In particular, recommended periodic QA procedures include proton spot placement verification to ±1–2 mm accuracy and spot size verification to ±10% accuracy of baseline commissioning values 11 . Accurate single spot profile data are also important for the commissioning of IMPT systems including treatment planning systems (TPS) that will be used for proton dose calculations 12 . For these purposes, accurate profile data have to be obtained especially proton halo profile measurements around a single spot 13 .…”

Section: Introductionmentioning

confidence: 99%

“…11 Accurate single spot profile data are also important for the commissioning of IMPT systems including treatment planning systems (TPS) that will be used for proton dose calculations. 12 For these purposes, accurate profile data have to be obtained especially proton halo profile measurements around a single spot. 13 Proton halos arise from inelastic nuclear interactions 14,15 and are typically on the order of 0.1% of the peak proton dose.…”

Section: Introductionmentioning

confidence: 99%

Development of a storage phosphor imaging system for proton pencil beam spot profile determination

et al. 2021

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Purpose Accurate two‐dimensional (2D) profile measurements at submillimeter precision are necessary for proton beam commissioning and periodic quality assurance (QA) purposes and are currently performed at our institution with a commercial scintillation detector (Lynx PT) with limited means for independent checks. The purpose of this work was to create an independent dosimetry system consisting of an in‐house optical scanner and a BaFBrI:Eu2+ storage phosphor dosimeter by: (a) determining the optimal settings for the optical scanner, (b) measuring 2D proton spot profiles with the storage phosphors, and (c) comparing them to similar measurements using a commercial scintillation detector. Methods An in‐house 2D laboratory optical scanner was constructed and spatially calibrated for accurate 2D photostimulated luminescence (PSL) dosimetry. Square 5 × 5 cm2 BaFBrI:Eu2+ dosimeter samples were uniformly irradiated with line scans performed to determine the physical and electronic scanner settings resulting in the highest signal‐to‐noise ratios (SNR) at a sub‐millimeter spatial resolution. The resultant spatial resolution of the scanner was then quantitatively assessed by measuring (a) line pairs on a standard X‐ray lead bar phantom and (b) modulation transfer functions. Following this, 2D proton spot profiles from a Mevion S250i Hyperscan proton unit were obtained at 1, 10, 20, 30, 40, and 50 monitor unit (MU) settings at maximum energy (E0 = 227.1 MeV) and compared to baseline profiles from a commercial scintillation detector, where 1 MU is calibrated to deliver 1 Gy absolute proton dose‐to‐water under reference conditions, that is, 41 × 41 proton spots uniformly spaced by 0.25 cm within a 10 × 10 cm2 square field size at maximum energy (227.1 MeV) in water at depth of 5 cm at isocenter. The dosimetric system's sensitivities to (a) ±1 mm positional shifts and (b) ±0.3 mm beam lateral spread changes were quantitatively evaluated through a Gaussian fitting of the crossline and inline plots of the respective artificially shifted beam profiles. Results The physical scanner settings of (a) Δτ = 27 ms time interval between data samples, (b) vx = 1.235 cm/s scanning speed, (c) 1% laser transmission (0.02 mW power) and (d) (Δx, Δy) = (0.33, 0.50 mm) pixel sizes with electronic settings of (a) 300 microseconds time constant, (b) normal dynamic reserve, (c) 24 dB/oct low pass filter slope, and (d) 160 Hz chopping frequency resulted in the highest SNR while maintaining sub‐millimeter spatial resolution. The BaFBr0.85I0.15:Eu2+ storage phosphor dosimeters were linear from 1 to 50 MU and their profiles did not saturate up to 150 MU. The scanner was able to detect lateral displacements of ±1 mm in both the crossline and inline directions and ±0.3 mm beam spread changes that were artificially introduced by varying the incident proton energy. Specific to our proton unit, proton energy changes of ±1 MeV can also be detected indirectly via beam spread measurements. Conclusion Our combined dosimetric system including an in‐hous...

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Clinical commissioning of intensity‐modulated proton therapy systems: Report of AAPM Task Group 185

Cited by 34 publications

References 187 publications

The root cause analysis on failed patient‐specific measurements of pencil beam scanning protons using a 2D detection array with finite size ionization chambers

The root cause analysis on failed patient‐specific measurements of pencil beam scanning protons using a 2D detection array with finite size ionization chambers

Development of a heterogeneous phantom to measure range in clinical proton therapy beams

Development of a storage phosphor imaging system for proton pencil beam spot profile determination

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