Abstract
Abstract
Living tissues could suffer different types of DNA damage as a result of being exposed to ionizing radiations. Monte Carlo simulations of the underlying interactions have been instrumental in predicting the damage types and the processes involved. In this work, we employed Geant4-DNA and MCDS for extracting the initial DNA damage and investigating the dependence of damage efficiency on the cell’s oxygen content. The frequency-mean lineal (
y
¯
F
) and specific (
z
¯
F
) energies were derived for a spherical volume of water of various diameters between 2 and 11.1 μm. This sphere would serve as the nucleus of a cell of 100 μm diameter, engulfed by a homogeneous beam of protons. These microdosimetric quantities were calculated assuming spherical samples of 1 μm diameter in MCDS. The simulation results showed that for 230 MeV protons, an increase in the oxygen content from 0 by 10% raised the frequency of single- and double-strand breaks and lowered the base damage frequency. The resulting damage frequencies appeared to be independent of nucleus diameter. For proton energies between 2 and 230 MeV,
y
¯
F
showed no dependence on the cell diameter and an increase of the cell size resulted in a decrease in
z
¯
F
.
An increase in the proton energy slowed down the decreasing rate of
z
¯
F
as a function of nucleus diameter. However, the ratio of
y
¯
F
values corresponding to two proton energies of choice showed no dependence on the nucleus size and were equal to the ratio of the corresponding
z
¯
F
values. Furthermore, the oxygen content of the cell did not affect these microdosimetric quantities. Contrary to damage frequencies, these quantities appeared to depend only on direct interactions due to deposited energies. Our calculations showed the near independence of DNA damages on the nucleus size of the human cells. The probabilities of different types of single and double-strand breaks increase with the oxygen content.