The methodology developed in the present work provides appropriate storage conditions during irradiation of both red blood cells and platelet blood components using a teletherapy unit.
The method used to store the blood bags during irradiation guaranteed that all damage caused to the cells was exclusively due to the action of radiation at the doses applied. It was demonstrated that prolonged storage of 60Co-irradiated RBCs results in loss of membrane phospholipids asymmetry, exposing phosphatidylserine (PS) on the cells' surface with a time and dose dependence, which can reduce the in vivo recovery of these cells. A time- and dose-dependence effect on the extracellular K+ and plasma-free Hb levels was also observed. The magnitude of all these effects, however, seems not to be clinically important and can support the storage of irradiated RBC units for at last 28 days.
Irradiation of whole blood and blood components before transfusion is currently the only accepted method to prevent Transfusion-Associated Graft-Versus-Host-Disease (TA-GVHD). However, choosing the appropriate technique to determine the dosimetric parameters associated with blood irradiation remains an issue. We propose a dosimetric system based on the standard Fricke Xylenol Gel (FXG) dosimeter and an appropriate phantom. The modified dosimeter was previously calibrated using a 60Co teletherapy unit and its validation was accomplished with a 137Cs blood irradiator. An ionization chamber, standard FXG, radiochromic film and thermoluminescent dosimeters (TLDs) were used as reference dosimeters to determine the dose response and dose rate of the 60Co unit. The dose distributions in a blood irradiator were determined with the modified FXG, the radiochromic film, and measurements by TLD dosimeters. A linear response for absorbed doses up to 54 Gy was obtained with our system. Additionally, the dose rate uncertainties carried out with gel dosimetry were lower than 5% and differences lower than 4% were noted when the absorbed dose responses were compared with ionization chamber, film and TLDs.
An x-ray sensitometer is used to measure the characteristic curve of radiographic films exposed with fluorescent intensifying screens. The series of relative exposures, necessary to cover the full density range of the film, can be obtained by either time-scale or intensity-scale sensitometric methods. We have developed a convenient method of exposing film-screen systems for time-scale sensitometry. In this method, during exposure the x-ray kilovoltage, tube current and x-ray intensity remain constant and a geometric series of exposures of the film is modulated by varying the exposure time. This time variation can be obtained when a lead disc with different sector openings is rotated in front of the film system by a stepping motor. The conditions normally used are 70 kVp x-rays, 3.5 mm Al total filtration at the tube, and 2.4 m focal spot-film distance. This exposure latitude gives a complete characteristic curve of film-screen systems.
Current studies have shown that ionizing radiation (IR) could increase the efficiency of radiation therapy by the stimulation of the immune system. This occurs in low-dose radiation as well as doses within hypofractionated range usually used in radiotherapy. However, the elucidation of the mechanisms of immunogenic modulation reported at these doses remain an issue. In this study, we analyzed transcriptome data available in Gene Expression Omnibus (GEO) database related to B cells isolated from whole blood of 95 donors and then irradiated with 10 Gy. The aim of this study is to investigate the regulation of genes and pathways of the immune system considering the B7-CD28/CTLA4 superfamily, CD40-CD40LG molecules, and cytokines expressed by B cells irradiated. The connection between genes and pathways is established by the Reactome database. Relative activity and diversity of pathways were calculated to determine the modulation of the immune system response to irradiation. Analysis of variance (ANOVA) with repeated measures and Bonferroni's method were used to determine differentially expressed genes. It was observed that IR up-modulates the response of pathways and genes considered in this study, which indicates that 10 Gy can enhance antitumor immune responses.Acknowledgments: This research was partially supported by CAPES. This work is based in a MSc thesis part submitted for the partial fulfillment of the requirements of the graduate programme in physics at the Federal University of Rio Grande, Rio Grande, Rio Grande do Sul, Brazil.
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