Radiation protection biology then and now

Wójcik, Andrzej; Harms‐Ringdahl, Mats

doi:10.1080/09553002.2019.1589027

Cited by 20 publications

(12 citation statements)

References 42 publications

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“…In the case of accidents involving important radiation sources, when first responders, firefighters, or groups of selected plant personnel are called upon to intervene, prior knowledge of any particular radiosensitivity of the personnel is of primary importance [57,94,110]. It is, therefore, necessary to indicate the mechanisms that govern the variability of the cell's radiosensitivity at the genetic level and, in particular, in the various phases of the cell cycle.…”

Section: Radiation-induced Dna Damage and Repairmentioning

confidence: 99%

“…As the cells complete this cycle, their radiosensitivity varies. The middle and final parts of the synthesis and the G1 phase are known as radioresistant phases, while the mitosis and the passages from G1 to S and from G2 to phase M are particularly sensitive to radiation [57,79,94,[110][111][112][113] In order to explain this variation in terms of sensitivity, as well as an elongation of the intermediate phases G1 and G2 after exposure of the cells to radiation, many probable mechanisms have been proposed. A first hypothesis concerned the variation of radiosensitivity related to the organization of chromatin during irradiation.…”

Section: Radiation-induced Dna Damage and Repairmentioning

confidence: 99%

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Cytogenetic bio-dosimetry techniques in the detection of dicentric chromosomes induced by ionizing radiation: A review

et al. 2021

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Ionizing radiation is ubiquitous in the environment. Its source can be natural, such as radioactive materials present in soil and cosmic rays, or artificial, such as the fuel for nuclear power plants. Overexposure to ionizing radiation may damage living tissue and could cause severe health problems (i.e., mutations, radiation sickness, cancer, and death). Cytogenetic bio-dosimetry has the great advantage to take into account the inter-individual variation, and it is informative even when physical dosimetry is not applicable; moreover, it is the definitive method to assess exposure to ionizing radiation recommended by the World Health Organization (WHO). Such a procedure involves counting the frequency of dicentric chromosomes (DCs), which are the most studied chromosomal aberrations used as absorbed radiation biomarkers, during the metaphase of cells. A set of algorithms, tested on different programming languages to automatically identify DCs, is analyzed by the authors together with an Automated Dicentric Chromosome Identifying software (ADCI) mostly based on OpenCV programming libraries. The purpose of this work is to review the main results regarding the correlation between ionizing radiation and dicentric chromosomes in cytogenetic bio-dosimetry.

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Section: Radiation-induced Dna Damage and Repairmentioning

confidence: 99%

Section: Radiation-induced Dna Damage and Repairmentioning

confidence: 99%

Cytogenetic bio-dosimetry techniques in the detection of dicentric chromosomes induced by ionizing radiation: A review

et al. 2021

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“…Radiation biology ( 69 ) is more than 100 years old since x-rays were discovered in 1895 by Roëntgen. As the field started to understand radiation’s interaction with cellular structures, physicists studied radiation’s biological effects, becoming a pillar of radiation biology.…”

Section: Biologymentioning

confidence: 99%

Moving Forward in the Next Decade: Radiation Oncology Sciences for Patient-Centered Cancer Care

Coleman¹,

Buchsbaum

Prasanna

et al. 2021

JNCI Cancer Spectrum

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In a time of rapid advances in science and technology the opportunities for radiation oncology are undergoing transformational change. The linkage between and understanding of the physical dose and induced biological perturbations are opening entirely new areas of application. The ability to define anatomic extent of disease and the elucidation of the biology of metastases has brought a key role for radiation oncology for treating metastatic disease. That radiation can stimulate and suppress subpopulations of the immune response makes radiation a key participant in cancer immunotherapy. Targeted radiopharmaceutical therapy delivers radiation systemically with radionuclides and carrier molecules selected for their physical, chemical and biochemical properties. Radiation oncology usage of “big data” and machine learning/artificial intelligence adds the opportunity to markedly change the workflow for clinical practice while physically targeting and adapting radiation fields in real time. Future precision targeting requires multi-dimensional understanding of the imaging, underlying biology and anatomical relationship among tissues for radiation as spatial and temporal “focused biology”. Other means of energy delivery are available as are agents that can be activated by radiation with increasing ability to target treatments. With broad applicability of radiation in cancer treatment, it is a necessity for effective cancer care, opening a career path for global health serving the medically underserved in geographically isolated populations as a substantial societal contribution addressing health disparities. Understanding of risk and mitigation of radiation injury make it an important discipline for and beyond cancer care including energy policy, space exploration, national security and global partnerships.

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“…Nowadays, X-ray is important in many section of life. It is invaluable in many applied fields of science such as radiology, nuclear energy and radiation damage [1][2][3][4][5][6]. In 1895, W. Röntgen discovered X-rays which are produced when a beam of electrons interacts a target [7].…”

Section: Introductionmentioning

confidence: 99%

Proportional Counter in X-ray Fluorescence

Qadr

2021

Aksaray University Journal of Science and Engineering

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The purpose of this work is to investigate and quantify x-ray fluorescence, its production and its spectroscopy. Characteristic x-ray with different energies was obtained from six various elements using Am-241 source with 59.5 keV. It was found that x-ray energy and intensity increase with increasing atomic number of material. X-ray spectroscopy was studied for such elements in respect to their atomic number and intensity of Kα using proportional counter. Furthermore, x-ray fluorescence was produced from different thicknesses of copper foil using different energies. It was found that there is no substantial difference in x-ray fluorescence yield with higher thickness of the target.

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Radiation protection biology then and now

Cited by 20 publications

References 42 publications

Cytogenetic bio-dosimetry techniques in the detection of dicentric chromosomes induced by ionizing radiation: A review

Cytogenetic bio-dosimetry techniques in the detection of dicentric chromosomes induced by ionizing radiation: A review

Moving Forward in the Next Decade: Radiation Oncology Sciences for Patient-Centered Cancer Care

Proportional Counter in X-ray Fluorescence

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