Your search keyword '"Bernal, Mario A."' showing total 3 results

1. Track structure modeling in liquid water: A review of the Geant4-DNA very low energy extension of the Geant4 Monte Carlo simulation toolkit

Author

Bernal, Mario A., Bordage, Marie Claude, Brown, Jeremy Michael Cooney, Davídková, Marie, Delage, E., El Bitar, Ziad Ei, Enger, Shirin A., Francis, Ziad, Guatelli, Susanna, Ivanchenko, Vladimir N., Karamitros, Mathieu, Kyriakou, Ioanna, Maigne, Lydia, Meylan, Sylvain, Murakami, Kouichi, Okada, Shogo, Payno, H., Perrot, Yann, Petrović, Ivan M., Pham, Q. T., Ristić-Fira, Aleksandra, Sasaki, Takashi, Stepan, Vaclav, Tran, Ngoc Hoang, Villagrasa, Carmen, and Incerti, Sebastien

Subjects

Ionizing radiation, Geant4-DNA, Radiolysis, Radiobiology, Monte Carlo

Abstract

Understanding the fundamental mechanisms involved in the induction of biological damage by ionizing radiation remains a major challenge of todays radiobiology research. The Monte Carlo simulation of physical, physicochemical and chemical processes involved may provide a powerful tool for the simulation of early damage induction. The Geant4-DNA extension of the general purpose Monte Carlo Geant4 simulation toolkit aims to provide the scientific community with an open source access platform for the mechanistic simulation of such early damage. This paper presents the most recent review of the Geant4-DNA extension, as available to Geant4 users since June 2015 (release 10.2 Beta). In particular, the review includes the description of new physical models for the description of electron elastic and inelastic interactions in liquid water, as well as new examples dedicated to the simulation of physicochemical and chemical stages of water radiolysis. Several implementations of geometrical models of biological targets are presented as well, and the list of Geant4-DNA examples is described.

Published

2015

2. A Feasibility Study of Fricke Dosimetry as an Absorbed Dose to Water Standard for 192Ir HDR Sources.

Author

deAlmeida, Carlos Eduardo, Ochoa, Ricardo, Lima, Marilene Coelho de, David, Mariano Gazineu, Pires, Evandro Jesus, Peixoto, José Guilherme, Salata, Camila, and Bernal, Mario Antônio

Subjects

FRICKE dosimeters, RADIOISOTOPE brachytherapy, RADIATION doses, RADIATION absorption, COMPARATIVE studies

Abstract

High dose rate brachytherapy (HDR) using 192Ir sources is well accepted as an important treatment option and thus requires an accurate dosimetry standard. However, a dosimetry standard for the direct measurement of the absolute dose to water for this particular source type is currently not available. An improved standard for the absorbed dose to water based on Fricke dosimetry of HDR 192Ir brachytherapy sources is presented in this study. The main goal of this paper is to demonstrate the potential usefulness of the Fricke dosimetry technique for the standardization of the quantity absorbed dose to water for 192Ir sources. A molded, double-walled, spherical vessel for water containing the Fricke solution was constructed based on the Fricke system. The authors measured the absorbed dose to water and compared it with the doses calculated using the AAPM TG-43 report. The overall combined uncertainty associated with the measurements using Fricke dosimetry was 1.4% for k = 1, which is better than the uncertainties reported in previous studies. These results are promising; hence, the use of Fricke dosimetry to measure the absorbed dose to water as a standard for HDR 192Ir may be possible in the future. [ABSTRACT FROM AUTHOR]

Published

2014

3. On the consistency of Monte Carlo track structure DNA damage simulations.

Author

Pater, Piotr, Seuntjens, Jan, El Naqa, Issam, and Bernal, Mario A.

Subjects

DNA damage, RADIOBIOLOGY, RADIATION doses, ENERGY transfer, CHROMATIN, CLUSTER analysis (Statistics), MONTE Carlo method

Abstract

Purpose: Monte Carlo track structures (MCTS) simulations have been recognized as useful tools for radiobiological modeling. However, the authors noticed several issues regarding the consistency of reported data. Therefore, in this work, they analyze the impact of various user defined parameters on simulated direct DNA damage yields. In addition, they draw attention to discrepancies in published literature in DNA strand break (SB) yields and selected methodologies. Methods: The MCTS code Geant4-DNA was used to compare radial dose profiles in a nanometer-scale region of interest (ROI) for photon sources of varying sizes and energies. Then, electron tracks of 0.28 keV-220 keV were superimposed on a geometric DNA model composed of 2.7 x 106 nucleosomes, and SBs were simulated according to four definitions based on energy deposits or energy transfers in DNA strand targets compared to a threshold energy ETH. The SB frequencies and complexities in nucleosomes as a function of incident electron energies were obtained. SBs were classified into higher order clusters such as single and double strand breaks (SSBs and DSBs) based on inter-SB distances and on the number of affected strands. Results: Comparisons of different nonuniform dose distributions lacking charged particle equilibrium may lead to erroneous conclusions regarding the effect of energy on relative biological effectiveness. The energy transfer-based SB definitions give similar SB yields as the one based on energy deposit when ETH≈10.79 eV, but deviate significantly for higher ETH values. Between 30 and 40 nucle-osomes/Gy show at least one SB in the ROI. The number of nucleosomes that present a complex damage pattern of more than 2 SBs and the degree of complexity of the damage in these nucleosomes diminish as the incident electron energy increases. DNA damage classification into SSB and DSB is highly dependent on the definitions of these higher order structures and their implementations. The authors' show that, for the four studied models, different yields are expected by up to 54% for SSBs and by up to 32% for DSBs, as a function of the incident electrons energy and of the models being compared. Conclusions: MCTS simulations allow to compare direct DNA damage types and complexities induced by ionizing radiation. However, simulation results depend to a large degree on user-defined parameters, definitions, and algorithms such as: DNA model, dose distribution, SB definition, and the DNA damage clustering algorithm. These interdependencies should be well controlled during the simulations and explicitly reported when comparing results to experiments or calculations [ABSTRACT FROM AUTHOR]

Published

2014