Assessing the Clinical Impact of Approximations in Analytical Dose Calculations for Proton Therapy

Schuemann, Jan; Giantsoudi, D.; Grassberger, Clemens; Moteabbed, M.; Min, Chul Hee; Paganetti, Harald

doi:10.1016/j.ijrobp.2015.04.006

Cited by 82 publications

(97 citation statements)

References 30 publications

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“…The magnitude of improvement observed with Monte Carlo algorithms for proton therapy, as indicated in our results, is larger than for photon therapy, making this issue even more important for proton therapy. This study is also largely consistent with the results of Schuemann et al who compared their analytic algorithm with Monte Carlo for several disease sites (16). They also observed discrepancies: the analytic algorithm predicted higher dose to the target volumes than did the Monte Carlo algorithm, although in the lung, their dose difference was only as large as 5%.…”

Section: Discussionsupporting

confidence: 91%

Pencil Beam Algorithms Are Unsuitable for Proton Dose Calculations in Lung

Taylor

Kry

Followill

2017

International Journal of Radiation Oncology*Biology*Physics

122

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: 91%

Pencil Beam Algorithms Are Unsuitable for Proton Dose Calculations in Lung

Taylor

Kry

Followill

2017

International Journal of Radiation Oncology*Biology*Physics

122

125

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“…It has been demonstrated that, relative to Monte Carlo (MC) simulations, proton pencil beam algorithms typically over-estimate the mean dose delivered to deep-seated targets such as the prostate by approximately 2% whilst under-estimating the scattered dose to normal tissues [10]. Consequently, in this study proton plan-specific scaling factors were applied to the MC dose distributions so that the dose received by 90% of a patient's CTV volume matched that for their IMRT plan.…”

Section: Methodsmentioning

confidence: 99%

Hydrogel rectum-prostate spacers mitigate the uncertainties in proton relative biological effectiveness associated with anterior-oblique beams

et al. 2017

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“…The doses and the three-dimensional LET d distributions were calculated using the TOPAS Monte Carlo system [30], based on the prescribed delivery parameters from the treatment planning system [31].…”

Section: Patient Cohort Dose Calculation and Model Parametersmentioning

confidence: 99%

Relating the proton relative biological effectiveness to tumor control and normal tissue complication probabilities assuming interpatient variability in α/β

Paganetti

2017

Acta Oncologica

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Background: Proton therapy uses a constant relative biological effectiveness (RBE) of 1.1. The use of variable RBE values has been suggested but is currently not feasible due to uncertainties. The impact of variable RBE has solely been studied using dosimetric indices. This work elucidates the impact of RBE variations on tumor control and normal tissue complication probabilities (TCP/NTCP). Methods: Models to estimate TCP and NTCP were used in combination with an empirical proton RBE model. Variations in outcome as a function of linear-quadratic model parameters for cellular radiosensitivity were determined for TCP in prostate and ependymoma. In addition, NTCP analysis was done for brainstem necrosis. Results: Considering a variable proton RBE as a dose-modifying factor for prescription doses and dose constraints is misleading, as TCP/NTCP do not simply scale with RBE. The dependency of RBE on a/b cannot be interpreted independent of TCP/NTCP because variations in radiosensitivity affect both photon and proton treatments. Assuming interpatient variability in radiosensitivity results in lower TCP for patients with low a/b. In proton therapy, the magnitude of TCP variations is reduced due to an RBE increase as a/b decreases. The TCP in proton therapy is less affected by interpatient variability in a/b. On the other hand, patients with a lower a/b would have a lower complication probability, which is counteracted by an increase in RBE as a/b decreases. Toxicities in proton therapy would be more affected by a/b variations compared to photon therapy. Conclusions: Assessment of variable RBE in proton therapy should be based on TCP and NTCP. Potential interpatient variability in radiosensitivity causes a smaller variance in TCP but a larger variance in NTCP for proton patients. The relative TCP as a function of a/b was found to be higher than the RBE, whereas the relative NTCP was lower than a calculated RBE.

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Assessing the Clinical Impact of Approximations in Analytical Dose Calculations for Proton Therapy

Cited by 82 publications

References 30 publications

Pencil Beam Algorithms Are Unsuitable for Proton Dose Calculations in Lung

Pencil Beam Algorithms Are Unsuitable for Proton Dose Calculations in Lung

Hydrogel rectum-prostate spacers mitigate the uncertainties in proton relative biological effectiveness associated with anterior-oblique beams

Relating the proton relative biological effectiveness to tumor control and normal tissue complication probabilities assuming interpatient variability in α/β

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