Current status of biodosimetry based on standard cytogenetic methods

Pinto, Maria Benegelânia; Santos, Nilcilene Nascimento dos; Amaral, Ademir

doi:10.1007/s00411-010-0311-3

Cited by 116 publications

(56 citation statements)

References 101 publications

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“…Over the past decades, the most commonly used method in biological dosimetry was cytogenetic analysis, in which the stable (translocations) and unstable (dysenteric chromosomes, micronuclei) chromosomal aberrations are counted in peripheral blood lymphocytes, along with a few other methods such as the glycophorin A mutation assay, electron paramagnetic resonance in tooth enamel, and the comet assay [69; 70]. However, cytogenetic analysis is time-consuming; it implies growth stimulation for 48–72 hrs since chromosomal damage can only be measured in metaphases [71]. Thus, such an analysis is not suitable for the rapid identification of the most severely exposed individuals, which is required in the event of a large-scale radiation emergency, when reliable detection is needed for population triage during the first few hours after accidental radiation exposure.…”

Section: Biodosimetrymentioning

confidence: 99%

Use of the γ-H2AX assay to monitor DNA damage and repair in translational cancer research

et al. 2012

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Formation of γ-H2AX in response to DNA double stranded breaks (DSBs) provides the basis for a sensitive assay of DNA damage in human biopsies. The review focuses on the application of γ-H2AX-based methods to translational studies to monitor the clinical response to DNA targeted therapies such as some forms of chemotherapy, external beam radiotherapy, radionuclide therapy or combinations thereof. The escalating attention on radiation biodosimetry has also highlighted the potential of the assay including renewed efforts to assess the radiosensitivity of prospective radiotherapy patients. Finally the γ-H2AX response has been suggested as a basis for an in vivo imaging modality.

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Section: Biodosimetrymentioning

confidence: 99%

Use of the γ-H2AX assay to monitor DNA damage and repair in translational cancer research

et al. 2012

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“…Dose-response curves have shapes and slopes that differ as a function of LET and relative biological effectiveness [17]. For low-LET radiation (e.g.…”

Section: Introductionmentioning

confidence: 99%

“…According to the IAEA [11], each laboratory must have its own dose-response curve, since several factors can influence the dose-effect relationships such as culture conditions or dicentric scoring efficiency [2,3,[12][13][14][15][16]. The main advantages of scoring dicentrics is its high specificity for ionizing radiation, low background in non-exposed populations (about 1 dicentric per 1000 cells) and a low detection limit, about 0.1 Gy for low-LET radiation if 500-1000 metaphases are scored [6,11,17,18]. Studies on both lowand high-LET radiation demonstrated that exposures in vitro and in vivo produce similar yields of dicentrics per unit dose [6,12,16].…”

Section: Introductionmentioning

confidence: 99%

Implementation of a dose–response curve for γ-radiation in the Portuguese population by use of the chromosomal aberration assay

Martins¹,

Antunes²,

Gil³

2013

Mutation Research/Genetic Toxicology and Environmental Mutagene

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“…Cytogenetic assays are the most extensively used biodosimetry assays, such as premature chromosome condensation (PCC) assay, micronuclei formation scoring, translocation and dicentric assay together [48]. Dicentric assay is currently the gold standard dosimetric method.…”

Section: Toward the Automation And Integration Of Assay Chemistries Fmentioning

confidence: 99%

Microfluidics as a new tool in radiation biology

2016

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Ionizing radiations interact with molecules at the cellular and molecular levels leading to several biochemical modifications that may be responsible for biological effects on tissue or whole organisms. The study of these changes is difficult because of the complexity of the biological response(s) to radiations and the lack of reliable models able to mimic the whole molecular phenomenon and different communications between the various cell networks, from the cell activation to the macroscopic effect at the tissue or organismal level. Microfluidics, the science and technology of systems that can handle small amounts of fluids in confined and controlled environment, has been an emerging field for several years. Some microfluidic devices, even at early stages of development, may already help radiobiological research by proposing new approaches to study cellular, tissue and total-body behavior upon irradiation. These devices may also be used in clinical biodosimetry since microfluidic technology is frequently developed for integrating complex bioassay chemistries into automated user-friendly, reproducible and sensitive analyses. In this review, we discuss the use, numerous advantages, and possible future of microfluidic technology in the field of radiobiology. We will also examine the disadvantages and required improvements for microfluidics to be fully practical in radiation research and to become an enabling tool for radiobiologists and radiation oncologists.

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Current status of biodosimetry based on standard cytogenetic methods

Cited by 116 publications

References 101 publications

Use of the γ-H2AX assay to monitor DNA damage and repair in translational cancer research

Use of the γ-H2AX assay to monitor DNA damage and repair in translational cancer research

Implementation of a dose–response curve for γ-radiation in the Portuguese population by use of the chromosomal aberration assay

Microfluidics as a new tool in radiation biology

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