RESUMO
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¯Fshowed no dependence on the cell diameter and an increase of the cell size resulted in a decrease inz¯F.An increase in the proton energy slowed down the decreasing rate ofz¯Fas a function of nucleus diameter. However, the ratio ofy¯Fvalues corresponding to two proton energies of choice showed no dependence on the nucleus size and were equal to the ratio of the correspondingz¯Fvalues. 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.
Assuntos
Núcleo Celular , Simulação por Computador , Dano ao DNA , Método de Monte Carlo , Oxigênio , Prótons , Oxigênio/metabolismo , Núcleo Celular/metabolismo , Núcleo Celular/efeitos da radiação , Humanos , Quebras de DNA de Cadeia Dupla/efeitos da radiação , DNA , Tamanho do Núcleo Celular , ÁguaRESUMO
Cobalt substituted manganese ferrite nanoparticles, Mn1-xCoxFe2O4 (x = 0.0, 0.1, 0.25 and 0.5) were prepared by co-precipitation procedure. The structural and magnetic properties of ferrite nanoparticles were measured by X-ray diffraction (XRD), field emission scanning electron microscopy (FESEM) and vibrating sample magnetometry (VSM). The lattice constant and cation distribution of ferrite samples were extracted from XRD patterns using the software package MAUD. The crystallite size of the samples was determined by the Scherrer equation and indicated that all of the ferrite samples were nanocrystalline. The defects in the samples were studied by employing positron annihilation lifetime spectroscopy (PALS). From the analysis of the positron lifetime spectrum, three components τ1, τ2, and τ3 with corresponding intensities I1, I2, and I3 were obtained. The mean lifetime of the annihilated positrons is maximum in the case of x = 0.25. This means that the defect concentration for this sample is greater than that for other samples. Magnetic measurements show a significant increase in the saturation magnetization from 20.62 to 36.03 emu/g, as the cobalt content (x) increased. The coercivity (Hc) of ferrite nanoparticles increased with the increasing cobalt ion substitution up to x = 0.25, and decreased for x = 0.5. This behavior of the Hc variation in samples is similar to the variation of average concentration of defects, as indicated by the mean positron lifetime τm, Therefore, it is concluded that the variation in the defect concentration affects the coercivity of the samples.
RESUMO
PURPOSE: DNA double-strand breaks (DSBs) created by ionizing radiations are considered as the most detrimental lesion, which could result in the cell death or sterilization. As the empirical evidence gathered from the cellular and molecular radiation biology has demonstrated significant correlations between the initial and lasting levels of DSBs, gaining knowledge into the DSB repair mechanisms proves vital. Much effort has been invested into understanding the mechanisms triggering the repair and processes engaged after irradiation of cells. Given a mechanistic model, we performed - to our knowledge - the first Monte Carlo study of the expected repair kinetics of carbon ions and electrons using on the one hand Geant4-DNA simulations of electrons for benchmarking purposes and on the other hand quantifying the influence of direct and indirect damage. Our objective was to calculate the DSB repair rates using a repair mechanism for G1 and early S phases of the cell cycle in conjunction with simulations of the DNA damage. MATERIALS AND METHODS: Based on Geant4-DNA simulations of DSB damage caused by electrons and carbon ions - using a B-DNA model and a water sphere of 3 µm radius resembling the mean size of human cells - we derived the kinetics of various biochemical repair processes. RESULTS: The overall repair times of carbon ions increased with the DSB complexity. Comparison of the DSB complexity (DSBc) and repair times as a function of carbon-ion energy suggested that the repair time of no specific fraction of DSBs could solely be explained as a function of DSB complexity. CONCLUSION: Analysis of the carbon-ion repair kinetics indicated that, given a fraction of DSBs, decreasing the energy would result in an increase of the repair time. The disagreements of the calculated and experimental repair kinetics for electrons could, among others, be due to larger damage complexity predicted by simulations or created actually by electrons of comparable energies to x-rays. They are also due to the employed repair mechanisms, which introduce no inherent dependence on the radiation type but make direct use of the simulated DSBs.
Assuntos
Dano ao DNA , Elétrons , Humanos , Reparo do DNA , DNA/efeitos da radiação , Íons , Simulação por Computador , Carbono , Método de Monte CarloRESUMO
PURPOSE: Dose distribution in carbon-ion irradiations is generally envisaged to have therapeutic advantages over protons, primarily due to the carbon ion's comparatively higher relative biological effectiveness in the tumor than in the encompassing healthy tissues. The objective of this work was to simulate the overall physical and chemical reactions of primary carbon ions impinging on liquid water and, as such, to investigate the DNA-damage yields in the form of strand breaks (SBs) and in connection with the expected microdosimetric quantities. MATERIALS AND METHODS: Using a B-DNA model and Geant4-DNA, we simulated the primary and secondary interactions in a spherical medium of water. Subsequently, we categorized DNA damages based on their complexity utilizing the concept of µ-randomness. We assumed a threshold of 17.5 eV for a direct SB and a probability of 0.13 for an indirect SB triggered by chemical reactions of hydroxyl radicals. Microdosimetric quantities were extracted for three cylindrical volumes representing typical subcellular organisms. RESULTS: For fully ionized carbons of 8-256 MeV/u, the yield results appeared to be considerably influenced by the chemical reactions-indicating the important role of secondary electrons in inflicting damage. However, it was mostly the direct-damage spectrum that determined the overall shape of the damage spectrum. At all primary energies, it was more probable to break each DNA strand at one point-the two points being less than 10 bp apart-than to break only one strand at two random points. Unlike proton's mean-specific-energy results, which showed more sensitivity to the volume increase of the smallest cylinder than of the larger ones, carbon-ion results showed no such sensitivity. CONCLUSION: The growth of the yield ratio of the single- and double-strand breaks (DSB) with the particle energy was estimated for protons to be about 2 times that of alphas and 92 times that of carbon ions. Unlike the proton results, which suggested significant correlations between the DSB yields and mean-specific (and lineal) energies, carbon ions exhibited no such correlations.
Assuntos
Carbono , Prótons , DNA/química , Dano ao DNA , Íons , Método de Monte Carlo , ÁguaRESUMO
PURPOSE: Through introducing stochastic quantities that can be connected to the dimensions of the microscopic structures exposed to radiations, microdosimetry is concerned with the substantive specifications of radiation quality that could help gain insight into radiation effects. Utilizing the µ-randomness method and Geant4-DNA code, we calculated microdosimetry quantities for nanometric structures in a spherical body of water irradiated with protons. To gain more insight into the effects of radiation on microscopic structures and validate the code parameters, we made a comparison between our results obtained within Geant4-DNA and results from other simulations. MATERIALS AND METHODS: We calculated microdosimetric quantities through irradiating a spherical body of water of 6 µm diameter with 0.5-100 MeV protons. Microdosimetric quantities were derived for cylinders with diameter × height values of 23 × 23, 50 × 100, and 300 × 300 Å × Å, which would resemble the typical sizes of sub-cellular organisms such as the DNA, nucleosome, and chromatin fiber. We exploited the concept of µ-randomness to introduce convex bodies of random positions and directions for calculating microdosimetric quantities. We used the Geant4-DNA Monte Carlo simulation toolkit for transporting protons and secondary particles and calculating the frequency- and dose-mean lineal and specific energies in cylindrical volumes. Specifically, for same-sized cylindrical volumes, microdosimetric parameters obtained by Nikjoo et al. using the KURBUC code were used for evaluation. RESULTS: For the energy range investigated, the frequency-mean lineal energy, dose-mean lineal energy, frequency-mean specific energy, and dose-mean specific energy vary within [2.34,47.06] (keV/µm), [10.40,68.55] (keV/µm), [0.04,39.38] × 106 cGy, and [0.16,90.29] × 106 cGy, respectively. Regardless of the proton energy, our specific-energy results showed higher sensitivity to volume change, for smaller cylinder volumes rather than larger ones. Regardless of both proton energy and volume of the cylinder under study, we observed a generally better agreement between our frequency-mean, than dose-mean, specific energy results and the KURBUC results. CONCLUSION: Using Geant4-DNA to account for the stochastic nature of energy depositions due to physical interactions between radiation and matter, we calculated microdosimetry parameters concerning proton irradiation. By employing microdosimetry concepts in conjunction with simulation results of our previous work on radiation effects on the DNA, we pinpointed and quantified correlations between microdosimetry parameters and DNA damage. As such, for a volume with comparable mass and mean chord length to the DNA, we could observe the clear correspondence of the mean lineal and specific energy results with the double-strand-break yields of protons in Gy-1.Gbp-1.
Assuntos
Dano ao DNA , Método de Monte Carlo , Prótons , Algoritmos , Doses de Radiação , Processos Estocásticos , ÁguaRESUMO
Purpose: Interaction of ionizing radiations with cells leads to single- and double-strand breaks (SSBs and DSBs) as well as base lesions of DNA. Employing the Geant4-DNA toolkit, we simulated the transportation of primary alphas and secondary particles in liquid water to study the damage in the form of SSBs and DSBs.Materials and Methods: Simulations were performed in a spherical water medium, where we used a B-DNA model and classified the DNA damage and its complexity. We assumed that in a certain vicinity of the DNA volume, energy depositions of more than 17.5 eV or hydroxyl radicals with a chemical-reaction probability of 0.13 would lead to strand breaks.Results: The results of 2 to 20 MeV alpha particles showed that more than 65% of the energy-deposition cases within the DNA volume would result in a form of break. The frequency pattern of higher-complexity damage types appeared to peak at higher deposited energies. Conclusion: We observed a reasonable agreement in terms of trend and value between our DSB yield results and experimental data. The yield results, as function of LET, suggested independence from particle type and converge to some extent at large LET. This manifests the dominant contribution of secondary electrons.
Assuntos
Partículas alfa/uso terapêutico , Dano ao DNA , Elétrons/uso terapêutico , Método de Monte Carlo , Terapia com Prótons , Transferência de EnergiaRESUMO
Thymolipoma is a benign and rare tumor that could be found at any age. Thymolipoma associated with the myasthenia gravis, Graves disease, aplastic anemia, and hypogammaglobulinemia was reported previously, but in this case, thymolipoma is associated with lymphocytosis. A 6-year-old girl was brought to the hospital because of a chronic cough. Her evaluation revealed a 130 × 160× 160 mm fat-containing soft tissue mass arising from anterior mediastinum with complete left lung collapse and contralateral mediastinal shift. Her past medical history showed that she had been evaluated and treated unsuccessfully due to severe lymphocytosis two years earlier. Her peripheral blood and bone marrow cell morphology were normal; in contrast, blood cell count and CD flow cytometry showed severe lymphocytosis. The patient's tumor was excised entirely without any complications, and lymphocytosis resolved during the follow-up period. Because the T lymphocytes are developed in the thymus, and more than 80% of cells in CD flow cytometry were T lymphocytes, and the lymphocytosis resolved with tumor removal; therefore, the authors suggested that Thymolipoma could be associated with lymphocytosis.
RESUMO
To study the molecular damage induced in the form of single-strand and double-strand breaks by ionizing radiation at the DNA level, the Geant4-DNA Monte Carlo simulation code for complete transportation of primary protons and other secondary particles in liquid water has been employed in this work. To this aim, a B-DNA model and a thorough classification of the complexity of the DNA damage were used. Strand breaks were assumed to have primarily originated by direct physical interactions via energy depositions, assuming a threshold energy of 17.5 eV, or indirect chemical reactions of hydroxyl radicals, assuming a probability of 0.13. The simulation results on the complexity and frequency of various damages are computed for proton energies of 0.5-20 MeV. The yield results for a cell (Gy cell)-1 are presented, assuming 22 chromosomes per cell and a mean number of 245 Mbp per chromosome. The results show that for proton energies below 2 MeV, more than 50% of the energy depositions within the DNA volume resulted in strand breaks. For double-strand breaks (DSBs), there is considerable sensitivity of DSB frequency to the proton energy. A comparison of DSB frequencies predicted by different simulations and experiments is presented as a function of proton linear energy transfer (LET). We show that our yield results (Gy Gbp)-1 are generally comparable with various experimental data and there seems to be a better agreement between our results and a number of experimental studies when compared to other simulations.