Algorithms Used in Heterogeneous Dose Calculations Show Systematic Differences as Measured With the Radiological Physics Center's Anthropomorphic Thorax Phantom Used for RTOG Credentialing

Kry, Stephen F.; Alvarez, P.; Molineu, A.; Amador, C.; Galvin, James M.; Followill, David S

doi:10.1016/j.ijrobp.2012.08.039

Cited by 72 publications

(70 citation statements)

References 20 publications

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“…The findings of this study is similar to what was previously discovered with the photon lung phantom (12): the dose calculated by Monte Carlo algorithms agrees better with measurements than the dose calculated by analytic algorithms. Overestimation of dose in the lung by up to 14% (13–15) has been observed with simple analytic algorithms (e.g.…”

Section: Discussionsupporting

confidence: 89%

Pencil Beam Algorithms Are Unsuitable for Proton Dose Calculations in Lung

Taylor

Kry

Followill

2017

International Journal of Radiation Oncology*Biology*Physics

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125

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Purpose To compare analytic and Monte Carlo-based algorithms for proton dose calculations in the lung, benchmarked against anthropomorphic lung phantom measurements. Methods A heterogeneous anthropomorphic moving lung phantom has been irradiated at numerous proton therapy centers. At five centers, the treatment plan could be calculated with both an analytic and Monte Carlo algorithm. The doses calculated in the treatment plans were compared with the doses delivered to the phantoms, which were measured using thermoluminescent dosimeters and film. Point doses were compared, as were planar doses using a gamma analysis. Results The analytic algorithms overestimated the dose to the center of the target by an average of 7.2%, whereas the Monte Carlo algorithms were within 1.6% of the physical measurements on average. In some regions of the target volume, the analytic algorithm calculations differed from the measurement by up to 31% in the iGTV (46% in the PTV), over-predicting the dose. All comparisons showed a region of at least 15% dose discrepancy within the iGTV between the analytic calculation and the measured dose. The Monte Carlo algorithm recalculations showed dramatically improved agreement with the measured doses, showing mean agreement within 4% for all cases, and a maximum difference of 12% within the iGTV. Conclusions Analytic algorithms often do a poor job predicting proton dose in lung tumors, overpredicting the dose to the target by up to 46%, and should not be used unless extensive validation counters the consistent results of the current study. Monte Carlo algorithms showed dramatically improved agreement with physical measurements and should be implemented to better reflect actual delivered dose distributions.

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Section: Discussionsupporting

confidence: 89%

Pencil Beam Algorithms Are Unsuitable for Proton Dose Calculations in Lung

Taylor

Kry

Followill

2017

International Journal of Radiation Oncology*Biology*Physics

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123

125

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“…The shortcoming of PB algorithms to accurately predict dose in low density media has been described previously 27 , 32 , 45 , 46 , 47 , 48 , 49 . In a recent study of 304 irradiations performed at 221 different institutions, Kry et al (49) observed an overestimate of 4.9% in PB algorithms compared to measurement in the Radiological Physics Center (RPC) thorax phantom used for RTOG credentialing; these results agree favorably with those reported here.…”

Section: Discussionsupporting

confidence: 88%

Commissioning and initial stereotactic ablative radiotherapy experience with Vero

Solberg

Medin

Ramirez

et al. 2014

J Applied Clin Med Phys

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The purpose of this study is to describe the comprehensive commissioning process and initial clinical performance of the Vero linear accelerator, a new radiotherapy device recently installed at UT Southwestern Medical Center specifically developed for delivery of image‐guided stereotactic ablative radiotherapy (SABR). The Vero system utilizes a ring gantry to integrate a beam delivery platform with image guidance systems. The ring is capable of rotating ± 60° about the vertical axis to facilitate noncoplanar beam arrangements ideal for SABR delivery. The beam delivery platform consists of a 6 MV C‐band linac with a 60 leaf MLC projecting a maximum field size of 15×15 cm2 at isocenter. The Vero planning and delivery systems support a range of treatment techniques, including fixed beam conformal, dynamic conformal arcs, fixed gantry IMRT in either SMLC (step‐and‐shoot) or DMLC (dynamic) delivery, and hybrid arcs, which combines dynamic conformal arcs and fixed beam IMRT delivery. The accelerator and treatment head are mounted on a gimbal mechanism that allows the linac and MLC to pivot in two dimensions for tumor tracking. Two orthogonal kV imaging subsystems built into the ring facilitate both stereoscopic and volumetric (CBCT) image guidance. The system is also equipped with an always‐active electronic portal imaging device (EPID). We present our commissioning process and initial clinical experience focusing on SABR applications with the Vero, including: (1) beam data acquisition; (2) dosimetric commissioning of the treatment planning system, including evaluation of a Monte Carlo algorithm in a specially‐designed anthropomorphic thorax phantom; (3) validation using the Radiological Physics Center thorax, head and neck (IMRT), and spine credentialing phantoms; (4) end‐to‐end evaluation of IGRT localization accuracy; (5) ongoing system performance, including isocenter stability; and (6) clinical SABR applications.PACS number: 87.53.Ly

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“…The study found that in-house IMRT QA failed to detect unacceptable plan delivery as measured independently in an IROC head and neck phantom and concluded that IMRT QA was not a reasonable replacement for a credentialing (audit) phantom irradiation. In a similar study to the work presented here, Kry et al [24] used a thorax phantom for a large (n ¼ 221 different institutions, 304 irradiations) credentialing study that looked at the impact of dose calculation algorithm and their accuracy when accounting for heterogeneities. Measured doses were compared to calculated doses for a lung target and analysed as a function of calculation algorithm.…”

Section: Discussionmentioning

confidence: 97%

“…In end-to-end tests, which are generally also performed as part of the commissioning, any algorithm rooted deviations might be diminished by other small deviations or might be within the larger allowed tolerances for such tests [24].…”

Section: Discussionmentioning

confidence: 99%

National dosimetric audit network finds discrepancies in AAA lung inhomogeneity corrections

Dunn¹,

Lehmann

Lye³

et al. 2015

Physica Medica

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This work presents the Australian Clinical Dosimetry Service's (ACDS) findings of an investigation of systematic discrepancies between treatment planning system (TPS) calculated and measured audit doses. Specifically, a comparison between the Anisotropic Analytic Algorithm (AAA) and other common dose-calculation algorithms in regions downstream (≥2cm) from low-density material in anthropomorphic and slab phantom geometries is presented. Two measurement setups involving rectilinear slab-phantoms (ACDS Level II audit) and anthropomorphic geometries (ACDS Level III audit) were used in conjunction with ion chamber (planar 2D array and Farmer-type) measurements. Measured doses were compared to calculated doses for a variety of cases, with and without the presence of inhomogeneities and beam-modifiers in 71 audits. Results demonstrate a systematic AAA underdose with an average discrepancy of 2.9 ± 1.2% when the AAA algorithm is implemented in regions distal from lung-tissue interfaces, when lateral beams are used with anthropomorphic phantoms. This systemic discrepancy was found for all Level III audits of facilities using the AAA algorithm. This discrepancy is not seen when identical measurements are compared for other common dose-calculation algorithms (average discrepancy -0.4 ± 1.7%), including the Acuros XB algorithm also available with the Eclipse TPS. For slab phantom geometries (Level II audits), with similar measurement points downstream from inhomogeneities this discrepancy is also not seen.

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Algorithms Used in Heterogeneous Dose Calculations Show Systematic Differences as Measured With the Radiological Physics Center's Anthropomorphic Thorax Phantom Used for RTOG Credentialing

Cited by 72 publications

References 20 publications

Pencil Beam Algorithms Are Unsuitable for Proton Dose Calculations in Lung

Pencil Beam Algorithms Are Unsuitable for Proton Dose Calculations in Lung

Commissioning and initial stereotactic ablative radiotherapy experience with Vero

National dosimetric audit network finds discrepancies in AAA lung inhomogeneity corrections

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