Robust intensity‐modulated proton therapy to reduce high linear energy transfer in organs at risk

An, Yu; Shan, Jie; Patel, Samir H.; Wong, William W.; Schild, Steven E.; Ding, Xiaoning; Bues, Martin; Liu, Wei

doi:10.1002/mp.12610

“…In much, the same way that the EUD concept (Equivalent Uniform Dose) in biological modeling has been successful for comparing dose distributions in a biologically relevant, but non‐absolute way (EUD itself makes no prediction on the actual magnitude of biological outcome), then LET can provide a metric whereby its value provides an indication of a potential increase in biological effect, without actually predicting the magnitude of that increase. Although this may seem somewhat of a lame advantage, LET will nevertheless provide a parameter, which could be “steered” away from critical structures, or concentrated into tumor regions, by an optimization process . Such an approach makes no assumption about the relationship of LET and biological effect, other than the knowledge that a higher LET could relate to an increased biological effect, even if that increase is of unknown magnitude.…”

Section: Knowledge Is Powermentioning

confidence: 99%

“…Although this may seem somewhat of a lame advantage, LET will nevertheless provide a parameter, which could be "steered" away from critical structures, or concentrated into tumor regions, by an optimization process. [43][44][45] Such an approach makes no assumption about the relationship of LET and biological effect, other than the knowledge that a higher LET could relate to an increased biological effect, even if that increase is of unknown magnitude.…”

Section: A Biologically Relevant Dosimetry (Prediction 32)mentioning

confidence: 99%

What will the medical physics of proton therapy look like 10 yr from now? A personal view

Lomax

¹

2018

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Despite growing rapidly, proton therapy is still a relatively immature treatment modality, at least in comparison to conventional radiotherapy using photons. As such, in this article, the author gives a very personal view of some of the potential areas for development in medical physics for proton therapy in the next 10 yr by identifying six topics for detailed discussion. The first of these are all related to reducing various “parameters” of proton therapy treatments (size and cost, treatment times, penumbras, and margins), while the second group are related to providing more quantitative “knowledge” about the quality of the treatments we are delivering. In conclusion, there is much interesting and important work still to be done in many areas of medical physics related to proton therapy, of which, the topics selected here are just the tip of the iceberg.

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“…Pencil beam scanning (PBS) is a fast‐developing proton delivery technique offering improved conformal dose coverage of targets and reduced dose to organs at risk (OARs) compared to the conventional photon‐based radiotherapy. However, the relative biological effectiveness (RBE) of protons is to date poorly understood due to its complex dependence on several factors including the linear energy transfer (LET), biological endpoint, tissue type, physical dose, and the uncertainty of experimental results . As a result, it is difficult to give an accurate estimate of proton RBE for clinical dose calculations.…”

Section: Introductionmentioning

confidence: 99%

“…However, the relative biological effectiveness (RBE) of protons is to date poorly understood [3][4][5][6][7] due to its complex dependence on several factors including the linear energy transfer (LET), biological endpoint, tissue type, physical dose, 6,8 and the uncertainty of experimental results. [9][10][11][12][13][14] As a result, it is difficult to give an accurate estimate of proton RBE for clinical dose calculations. The current practice is to use a constant value of 1.1 to convert physical dose to RBE-weighted dose.…”

Section: Introductionmentioning

confidence: 99%

Hybrid 3D analytical linear energy transfer calculation algorithm based on precalculated data from Monte Carlo simulations

Deng

¹

,

Ding

²

,

Younkin

³

et al. 2019

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Purpose The dose‐averaged linear energy transfer (LETd) for intensity‐modulated proton therapy (IMPT) calculated by one‐dimensional (1D) analytical models deviates from more accurate but time‐consuming Monte Carlo (MC) simulations. We developed a fast hybrid three‐dimensional (3D) analytical LETd calculation that is more accurate than 1D analytical model. Methods We used the Geant4 MC code to generate 3D LETd distributions of monoenergetic proton beams in water for all energies and used a customized error function to fit the LETd lateral profiles at various depths to the MC simulation. The 3D LETd calculation kernel was a lookup table of these fitted coefficients, and LETd was determined directly from spot energies and voxel coordinates during analytical dose calculations. We validated our new method by comparing the calculated LETd distributions to MC results using 3D Gamma index analysis with 3%/2 mm criteria in 12 patient geometries. The significance of the improvement in Gamma index analysis passing rates over the 1D analytical model was determined using the Wilcoxon rank‐sum test. Results The passing rate of 3D Gamma analysis comparing LETd distributions from the hybrid 3D method and the 1D method to MC simulations was significantly improved from 94.0% ± 2.5% to 98.0% ± 1.0% (P = 0.0003). The typical time to calculate dose and LETd simultaneously using an Intel Xeon E5‐2680 2.50 GHz workstation was approximately 2.5 min. Conclusions Our new method significantly improved the LETd calculation accuracy compared to the 1D method while maintaining significantly shorter calculation time even comparing with the GPU‐based fast MC code.

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“…Due to the strong correlation between LET and RBE, several groups have developed LET-guided optimization techniques 4,8,13,[19][20][21][22][23][24][25] that shift high LET toward the target volume and away from the OARs to reduce toxicity. The recently published TG-256 report 15 also suggested assessing the potential clinical consequences associated with variable RBE models and recommended LET-guided optimization in treatment planning systems (TPSs).…”

Section: Introductionmentioning

confidence: 99%

New Hybrid 3D Analytical Linear Energy Transfer (LET) Calculation Algorithm Based on the Pre-Calculated Data from Monte Carlo (MC) Simulations

Deng

¹

,

Ding

²

,

Younkin

³

et al. 2019

International Journal of Radiation Oncology*Biology*Physics

0

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Purpose The dose‐averaged linear energy transfer (LETd) for intensity‐modulated proton therapy (IMPT) calculated by one‐dimensional (1D) analytical models deviates from more accurate but time‐consuming Monte Carlo (MC) simulations. We developed a fast hybrid three‐dimensional (3D) analytical LETd calculation that is more accurate than 1D analytical model. Methods We used the Geant4 MC code to generate 3D LETd distributions of monoenergetic proton beams in water for all energies and used a customized error function to fit the LETd lateral profiles at various depths to the MC simulation. The 3D LETd calculation kernel was a lookup table of these fitted coefficients, and LETd was determined directly from spot energies and voxel coordinates during analytical dose calculations. We validated our new method by comparing the calculated LETd distributions to MC results using 3D Gamma index analysis with 3%/2 mm criteria in 12 patient geometries. The significance of the improvement in Gamma index analysis passing rates over the 1D analytical model was determined using the Wilcoxon rank‐sum test. Results The passing rate of 3D Gamma analysis comparing LETd distributions from the hybrid 3D method and the 1D method to MC simulations was significantly improved from 94.0% ± 2.5% to 98.0% ± 1.0% (P = 0.0003). The typical time to calculate dose and LETd simultaneously using an Intel Xeon E5‐2680 2.50 GHz workstation was approximately 2.5 min. Conclusions Our new method significantly improved the LETd calculation accuracy compared to the 1D method while maintaining significantly shorter calculation time even comparing with the GPU‐based fast MC code.

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Robust intensity‐modulated proton therapy to reduce high linear energy transfer in organs at risk

Cited by 67 publications

References 47 publications

What will the medical physics of proton therapy look like 10 yr from now? A personal view

What will the medical physics of proton therapy look like 10 yr from now? A personal view

Hybrid 3D analytical linear energy transfer calculation algorithm based on precalculated data from Monte Carlo simulations

New Hybrid 3D Analytical Linear Energy Transfer (LET) Calculation Algorithm Based on the Pre-Calculated Data from Monte Carlo (MC) Simulations

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