A phenomenological biological dose model for proton therapy based on linear energy transfer spectra

Eivind Rørvik; Sara Thörnqvist; Camilla H Stokkevåg; Tordis J Dahle; Lars Fredrik Fjaera; Kristian S Ytre-Hauge

doi:10.1002/mp.12216

A phenomenological biological dose model for proton therapy based on linear energy transfer spectra

Med Phys. 2017 Jun;44(6):2586-2594. doi: 10.1002/mp.12216. Epub 2017 May 22.

Authors

Eivind Rørvik¹, Sara Thörnqvist^{1

2}, Camilla H Stokkevåg², Tordis J Dahle¹, Lars Fredrik Fjaera^{1

2}, Kristian S Ytre-Hauge¹

Affiliations

¹ Department of Physics and Technology, University of Bergen, Bergen, Norway.
² Department of Oncology and Medical Physics, Haukeland University Hospital, Bergen, Norway.

PMID: 28295379
DOI: 10.1002/mp.12216

Abstract

Purpose: The relative biological effectiveness (RBE) of protons varies with the radiation quality, quantified by the linear energy transfer (LET). Most phenomenological models employ a linear dependency of the dose-averaged LET (LET_d ) to calculate the biological dose. However, several experiments have indicated a possible non-linear trend. Our aim was to investigate if biological dose models including non-linear LET dependencies should be considered, by introducing a LET spectrum based dose model.

Method: The RBE-LET relationship was investigated by fitting of polynomials from 1st to 5th degree to a database of 85 data points from aerobic in vitro experiments. We included both unweighted and weighted regression, the latter taking into account experimental uncertainties. Statistical testing was performed to decide whether higher degree polynomials provided better fits to the data as compared to lower degrees. The newly developed models were compared to three published LET_d based models for a simulated spread out Bragg peak (SOBP) scenario.

Results: The statistical analysis of the weighted regression analysis favored a non-linear RBE-LET relationship, with the quartic polynomial found to best represent the experimental data (P = 0.010). The results of the unweighted regression analysis were on the borderline of statistical significance for non-linear functions (P = 0.053), and with the current database a linear dependency could not be rejected. For the SOBP scenario, the weighted non-linear model estimated a similar mean RBE value (1.14) compared to the three established models (1.13-1.17). The unweighted model calculated a considerably higher RBE value (1.22).

Conclusion: The analysis indicated that non-linear models could give a better representation of the RBE-LET relationship. However, this is not decisive, as inclusion of the experimental uncertainties in the regression analysis had a significant impact on the determination and ranking of the models. As differences between the models were observed for the SOBP scenario, both non-linear LET spectrum- and linear LET_d based models should be further evaluated in clinically realistic scenarios.

Keywords: LET spectrum; biological dose modelling; linear energy transfer; mixed field radiation; proton therapy; relative biological effectiveness.

MeSH terms

Linear Energy Transfer*
Nonlinear Dynamics
Proton Therapy*
Protons
Relative Biological Effectiveness*

Substances

Protons