A fast Monte Carlo cell-by-cell simulation for radiobiological effects in targeted radionuclide therapy using pre-calculated single-particle-track standard DNA damage data

Abstract

IntroductionWe develop a new method that drastically speeds up radiobiological Monte Carlo radiation-track-structure (MC-RTS) calculations on a cell-by-cell basis.MethodsThe method is based on random sampling and superposition of single-particletrack (SPT) standard DNA damage (SDD) files from a “pre-calculated” data library, constructed using the RTS code TOPAS-nBio, with “time stamps” manually added to incorporate dose-rate effects. This time-stamped SDD file can then be input into MEDRAS, a mechanistic kinetic model that calculates various radiation-induced biological endpoints, including DNA double strand breaks (DSBs), misrepairs and chromosomal aberrations, and cell death. As a benchmark validation of the approach, we calculate the predicted energy-dependent DSB yield and the ratio of direct-to-total DNA damage, both of which agree with published in-vitro experimental data. We subsequently apply the method to perform superfast cell-by-cell simulation of an experimental in-vitro system consisting of neuroendocrine tumor cells uniformly incubated with 177Lu.Results and discussionThe results for residual DSBs, both at 24 and 48 h post-irradiation, agree well with the published literature values. Our work serves as a proof-of-concept demonstration of the feasibility of cost-effective “in silico clonogenic cell survival assay” for the computational design and development of radiopharmaceuticals, and novel radiotherapy treatments more generally.