Biological Dosimetry of Radiation Workers at the Sellafield Nuclear Facility

Tucker, James D.; Tawn, E. Janet; Holdsworth, Duncan; Morris, Stephen; Langlois, Richard N.; Ramsey, Marilyn J.; Kato, Paula; Boice, John D.; Tarone, Robert E.; Jensen, Ronald H.

doi:10.2307/3579605

Cited by 67 publications

(35 citation statements)

References 47 publications

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“…Humans are exposed to low doses of radiation-during air travel, from radon in homes, during space travel, or in areas of low-level contamination, including former sites of nuclear weapon production-and can encounter much higher radiation doses in contaminated areas such as Chernobyl or during radiotherapy (1)(2)(3)(4)(5). However, ionizing radiation induces a plethora of types of DNA damages (6), and the identity of specific lesions responsible for the biological effects of radiation remains uncertain.…”

mentioning

confidence: 99%

Clustered DNA damages induced in isolated DNA and in human cells by low doses of ionizing radiation

Sutherland

Bennett

Sidorkina

et al. 2000

Proc. Natl. Acad. Sci. U.S.A.

437

279

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Clustered DNA damages-two or more closely spaced damages (strand breaks, abasic sites, or oxidized bases) on opposing strands-are suspects as critical lesions producing lethal and mutagenic effects of ionizing radiation. However, as a result of the lack of methods for measuring damage clusters induced by ionizing radiation in genomic DNA, neither the frequencies of their production by physiological doses of radiation, nor their repairability, nor their biological effects are known. On the basis of methods that we developed for quantitating damages in large DNAs, we have devised and validated a way of measuring ionizing radiationinduced clustered lesions in genomic DNA, including DNA from human cells. DNA is treated with an endonuclease that induces a single-strand cleavage at an oxidized base or abasic site. If there are two closely spaced damages on opposing strands, such cleavage will reduce the size of the DNA on a nondenaturing gel. We show that ionizing radiation does induce clustered DNA damages containing abasic sites, oxidized purines, or oxidized pyrimidines. Further, the frequency of each of these cluster classes is comparable to that of frank double-strand breaks; among all complex damages induced by ionizing radiation, double-strand breaks are only about 20%, with other clustered damage constituting some 80%. We also show that even low doses (0.1-1 Gy) of high linear energy transfer ionizing radiation induce clustered damages in human cells. Ionizing radiation may produce cancer, death, and loss of neural function in humans and animals, and it may induce killing, mutation, and chromosomal aberrations in cells (1). Humans are exposed to low doses of radiation-during air travel, from radon in homes, during space travel, or in areas of low-level contamination, including former sites of nuclear weapon production-and can encounter much higher radiation doses in contaminated areas such as Chernobyl or during radiotherapy (1-5). However, ionizing radiation induces a plethora of types of DNA damages (6), and the identity of specific lesions responsible for the biological effects of radiation remains uncertain. Understanding the long-term effects of low and high doses of ionizing radiation on living organisms requires identification of critical radiation-induced DNA lesions, measurement of their repairability, and determination of the consequences of misrepaired or unrepaired persistent lesions.Lethal and mutagenic effects of ionizing radiation result principally from incompletely or incorrectly repaired DNA lesions (7,8). Ionizing radiation induces high levels of isolated DNA lesions, including SSBs, damaged bases, and abasic sites, located at a distance from other damages (6). Such isolated damages are generally repaired efficiently, and their repair may be increased by priming ionizing radiation doses (9).Ionizing radiation also induces closely spaced lesions, including double-strand breaks (DSBs)-two or more SSBs on opposing strands within about 10-20 bp (10, 11)-and has been postulated to produce other c...

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mentioning

confidence: 99%

Clustered DNA damages induced in isolated DNA and in human cells by low doses of ionizing radiation

Sutherland

Bennett

Sidorkina

et al. 2000

Proc. Natl. Acad. Sci. U.S.A.

437

279

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“…To evaluate the utility of GPA as a biodosimeter of radiation doses accumulated over a long period of time, the GPA assay was applied to 36 radiation workers at the Sellafield Nuclear Facility who had received > 50 mGy cumulative dose based on previously recorded doses. No correlation was evident between variant frequency measured by GPA and radiation dose (Tucker et al, 1997b;. GPA ]N variant frequencies, but not NN V f , were only slightly elevated among the population living near the Semipalatinsk nuclear test site, but were not significantly greater compared with matched controls living in a non-contaminated area .…”

Section: Use Of Gpa In Epidemiologic Studiesmentioning

confidence: 68%

BiodosEPR-2006 consensus committee report on biodosimetric methods to evaluate radiation doses at long times after exposure

Simon

Bailiff

Bouville

et al. 2007

Radiation Measurements

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'kaev, Alexander V.; Tucker, James D.; and Wieser, Albrecht, "BiodosEPR-2006 consensus committee report on biodosimetric methods to evaluate radiation doses at long times after exposure" (2007 AbstractThe requirements for biodosimetric techniques used at long times after exposure, i.e., 6 months to more than 50 years, are unique compared to the requirements for methods used for immediate dose estimation. In addition to the fundamental requirement that the assay measures a physical or biologic change that is proportional to the energy absorbed, the signal must be highly stable over time to enable reasonably precise determinations of the absorbed dose decades later. The primary uses of these biodosimetric methods have been to support long-term health risk (epidemiologic) studies or to support compensation (damage) claims. For these reasons, the methods must be capable of estimating individual doses, rather than group mean doses. Even when individual dose estimates can be obtained, inter-individual variability remains as one of the most difficult problems in using biodosimetry measurements to rigorously quantify individual exposures. Other important criteria for biodosimetry methods include obtaining samples with minimal invasiveness, low detection limits, and high precision. Cost and other practical limitations generally prohibit biodosimetry measurements on a large enough sample to replace analytical dose reconstruction in epidemiologic investigations. However, these measurements can be extremely valuable as a means to corroborate analytical or model-based dose estimates, to help reduce uncertainty in individual doses estimated by other methods and techniques, and to assess bias in dose reconstruction models. There has been extensive use of three biodosimetric techniques in irradiated populations: EPR (using tooth enamel), FISH (using blood lymphocytes), and GPA (also using blood); these methods have been supplemented with luminescent methods applied to building materials and artifacts. A large number of investigations have used biodosimetric methods many years after external and, to a lesser extent, internal exposure to reconstruct doses received from accidents, from occupational exposures, from environmental releases of radioactive materials, and from medical exposures. In most applications, the intent has been to either identify highly exposed persons or confirmed suspected exposures. Improvements in methodology, however, have led many investigators to attempt quantification of whole-body doses received, or in a few instances, to estimate organ doses. There will be a continued need for new and improved biodosimetric techniques not only to assist in future epidemiologic investigations but to help evaluate the long-term consequences following nuclear accidents or events of radiologic terrorism.

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“…FISH has been one of the latest methodologies used in the field of radiation biology, bringing many new insights into the study of mechanism of aberration production including initial chromosome damage and the repair systems involved (Cornforth et al, 1989;Mühlmann-Díaz and Bedford, 1993Folle et al, 1998), radiobiodosimetry (Edwards, 1997Tucker et al, 1997) eters analyzed after nuclear accidents. In this way, it is possible to estimate the risk that the victims will have to confront and to take preventive measures accordingly.…”

Section: Radiation-biologymentioning

confidence: 99%

Molecular Cytogenetics in metaphase and interphase cells for diagnosis and prognosis in cancer and genetic research

Mühlmann-Díaz

2000

Genet. Mol. Biol.

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Biological Dosimetry of Radiation Workers at the Sellafield Nuclear Facility

Cited by 67 publications

References 47 publications

Clustered DNA damages induced in isolated DNA and in human cells by low doses of ionizing radiation

Clustered DNA damages induced in isolated DNA and in human cells by low doses of ionizing radiation

BiodosEPR-2006 consensus committee report on biodosimetric methods to evaluate radiation doses at long times after exposure

Molecular Cytogenetics in metaphase and interphase cells for diagnosis and prognosis in cancer and genetic research

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