Microdosimetric investigation of the radiation quality of low-medium energy electrons using Geant4-DNA

Ioanna Kyriakou; Ioanna Tremi; Alexandros G Georgakilas; Dimitris Emfietzoglou

doi:10.1016/j.apradiso.2021.109654

Microdosimetric investigation of the radiation quality of low-medium energy electrons using Geant4-DNA

Appl Radiat Isot. 2021 Jun:172:109654. doi: 10.1016/j.apradiso.2021.109654. Epub 2021 Feb 25.

Authors

Ioanna Kyriakou¹, Ioanna Tremi², Alexandros G Georgakilas², Dimitris Emfietzoglou³

Affiliations

¹ Medical Physics Laboratory, University of Ioannina Medical School, 45110, Ioannina, Greece. Electronic address: ikyriak@uoi.gr.
² DNA Damage Laboratory, Physics Department, School of Applied Mathematical and Physical Sciences, National Technical University of Athens (NTUA), Zografou, Athens, Greece.
³ Medical Physics Laboratory, University of Ioannina Medical School, 45110, Ioannina, Greece.

PMID: 33676082
DOI: 10.1016/j.apradiso.2021.109654

Abstract

The increasing clinical use of low-energy photon and electron sources (below few tens of keV) has raised concerns on the adequacy of the existing approximation of an energy-independent radiobiological effectiveness. In this work, the variation of the quality factor (Q) and relative biological effectiveness (RBE) of electrons over the low-medium energy range (0.1 keV-1 MeV) is examined using several microdosimetry-based Monte Carlo methodologies with input data obtained from Geant4-DNA track-structure simulations. The sensitivity of the results to the different methodologies, Geant4-DNA physics models, and target sizes is examined. Calculations of Q and RBE are based on the ICRU Report 40 recommendations, the Kellerer-Hahn approximation, the site version of the theory of dual radiation action (TDRA), the microdosimetric kinetic model (MKM) of cell survival, and the calculated yield of DNA double strand breaks (DSB). The stochastic energy deposition spectra needed as input in the above approaches have been calculated for nanometer spherical volumes using the different electron physics models of Geant4-DNA. Results are normalized at 100 keV electrons which is here considered the reference radiation. It is shown that in the energy range ~50 keV-1 MeV, the calculated Q and RBE are approximately unity (to within 1-2%) irrespective of the methodology, Geant4-DNA physics model, and target size. At lower energies, Q and RBE become energy-dependent reaching a maximum value of ~1.5-2.5 between ~200 and 700 eV. The detailed variation of Q and RBE at low energies depends mostly upon the adopted methodology and target size, and less so upon the Geant4-DNA physics model. Overall, the DSB yield predicts the highest RBE values (with RBE_max≈2.5) whereas the MKM the lowest RBE values (with RBE_max≈1.5). The ICRU Report 40, Kellerer-Hahn, and TDRA methods are in excellent agreement (to within 1-2%) over the whole energy range predicting a Q_max≈2. In conclusion, the approximation Q=RBE=1 was found to be valid only above ~50 keV whereas at lower energies both Q and RBE become strongly energy-dependent. It is envisioned that the present work will contribute towards establishing robust methodologies to determine theoretically the energy-dependence of radiation quality of individual electrons which may then be used in subsequent calculations involving practical electron and photon radiation sources.

Keywords: Biological effects of radiation; Geant4-DNA; LET; Microdosimetry; Quality factor; RBE.

MeSH terms

DNA / chemistry*
Electrons*
Nucleic Acid Conformation
Radiometry / methods*
Relative Biological Effectiveness
Reproducibility of Results

Substances

DNA