Follow-up of stable chromosomal aberrations in gamma-ray irradiated non-human primates.

PURPOSE: The purpose of this study was to examine a new approach to retrospective biological dosimetry, by using a long-term animal model to determine the stability of translocation frequency after in vivo irradiation. While the frequency of dicentrics is known to decrease over time, the persistence of more stable chromosomal aberrations such as translocations could be useful if their stability were definitively proved. MATERIALS AND METHODS: Four monkeys (Macaca fascicularis) were exposed to two different doses of ionizing radiation: 2 Gy whole body irradiation for two and 4 Gy for two others. Blood samples were obtained at various times after irradiation. Both total and two-way translocations were detected by fluorescence in situ hybridization. Translocations were scored in stable cells, that is, those without dicentrics, rings or fragments. The course of translocation frequency was analysed at four time-points: one hour (H1), 2 months (M2), 10 months (M10) and 31 months (M31) after irradiation. RESULTS: We observed two separate trends in translocation frequency: Total translocation frequency decreased slightly in animals irradiated with a dose of 2 Gy, while two-way translocation frequency was relatively stable in all irradiated animals. CONCLUSIONS: We confirmed the long-term stability of translocations and found that it seems to depend on the type of the translocation recorded. Overall translocations were stable for up to 31 months regardless of dose, but two-way translocations were more stable than those that were non-reciprocal, especially in stable cells.

Study of the tools available in biological dosimetry to estimate the dose in cases of accidental complex overexposure to ionizing radiation: the Lilo accident.

PURPOSE: To compare the efficiency of different cytogenetic tools in estimating the doses received by four people involved in the Lilo accident and to monitor the dose estimate over 4.5 years. MATERIALS AND METHODS: Several young Georgian frontier guards handled at least one of the 12 Caesium sources found in a former Russian military camp. Overexposure lasted from July 1996 to May 1997. The Institute for Radiological Protection and Nuclear Safety (IRSN) obtained blood samples taken at several intervals post-exposure from the four most highly-exposed people. Dose estimation was performed using dicentric and translocation scoring. RESULTS: The first dose estimations performed by dicentric scoring gave whole-body doses ranging from 0.4 to 1.3 Gy. Overexposure was complex and several mathematical models were used to take this complexity into account. This could provide information concerning the circumstances of overexposure. Concerning follow-up, the yield of dicentrics decreased by about 50% in the first 4 months following the end of overexposure whereas translocations were stable over the period of analysis. CONCLUSION: It has been useful to compare cytogenetic results with clinical results. The results presented here reveal good stability of translocations. However the first dose estimation was not attempted until 6 months after the last exposure.

Biological estimates of dose to inhabitants of Belarus and Ukraine following the Chernobyl accident.

The purpose of this paper is to investigate how well various assays on blood can detect radiation dose to people exposed many years previously and, if possible, to estimate that dose. The assays were applied to persons resident close to Chernobyl in 1986. Blood samples were taken 13-15 years after the reactor accident. The assays used were the frequencies of lymphocyte chromosomal translocations, micronuclei, HPRT mutations and apoptotic cells. Translocation yields in the exposed groups were marginally higher than in their respective controls, leading to dose estimates of about 0.2 Gy but with large uncertainties. All other assays showed inconsistency from person to person or other variations apparently not related to dose. The measurement of translocations, it is concluded, is the biological method of choice for retrospective dosimetry.

A new image analysis system for biological dosimetry by fluorescent in situ hybridization. Step 1: metaphase finder and automatic metaphase acquisition validation.

Because of the large number of cells to be analyzed in cases of overexposure to ionizing radiation, an automated imaging system is desirable for scoring both translocations and dicentrics. This system should include three essential steps: automatic metaphase finding, automatic image capture at high magnification, and, finally, optimized data analysis for aberration interpretation. We evaluated a new image analysis system (CYTOGEN, IMSTAR, France) and found that its metaphase finder saved time, as much as quadrupling the speed of scoring chromosomal aberrations. Automatic metaphase selection did not appear to induce bias. We confirmed the equivalence of observing aberrations on a screen after automatic image capture and direct observation under a microscope. This work validated all of the steps necessary for obtaining images for automatic chromosomal aberration detection. The protocols for the detection of translocations may now be applied for biological dosimetry. This step will be validated in a future study.

The cytogenetic dosimetry of recent accidental overexposure.

When accidental exposure to ionizing radiations is suspected, optimal choice of a treatment strategy requires, in addition to information about the clinical signs and physical dosimetry, a determination by biological parameters of the dose received. The scoring of unstable chromosomal aberrations in peripheral blood lymphocytes is the current reference method. Preparation of these samples depends on the goal sought--an exact assessment of several irradiations or rapid triage in the case of a large-scale accident. Moreover, some adaptation may be necessary if the irradiation is either heterogenous or not recent. Despite the robustness and adaptability of this procedure, conventional cytogenetics remains a tedious and time-consuming technique, and it requires specialized staff. Scoring micronuclei in binucleated lymphocytes may be an easier, simpler altemative to a dicentric assay. This paper, which is based on the experience acquired by the IPSN in recent years in expert assessment of suspected radiations, has as its goal to provide a succinct technical guideline of these different approaches, as they are adapted to suspected recent irradiation and triage.

Level of Flt3-ligand in plasma: a possible new bio-indicator for radiation-induced aplasia.

PURPOSE: To follow plasma Flt3-ligand (FL) concentrations in irradiated animals in order to evaluate it as an indicator of bone marrow damage for the management of accidental radiation-induced aplasia. MATERIALS AND METHODS: Non-human primates were irradiated at doses ranging from 2 to 8 Gy, using whole- or partial-body irradiation. Plasma FL concentrations and blood cell counts were determined daily. RESULTS: FL concentrations increased as early as day 2 after irradiation, whatever the irradiation dose. Increase in plasma FL concentration on day 5 post-irradiation was correlated with radiation dose and with the severity of radiation-induced aplasia. During the course of aplasia, FL concentrations in plasma were inversely correlated with neutrophil counts. A peak in FL concentration appeared before the neutrophil nadir, and the subsequent decrease in FL concentration was correlated with the recovery of blood-cell populations. CONCLUSIONS: Monitoring plasma FL concentration can be used as an indicator of radiation-induced marrow aplasia, and this may be of use in accidental irradiation situations.

Mathematical methods in biological dosimetry: the 1996 Iranian accident.

PURPOSE: To report 18 months of cytogenetic follow-up for an Iranian worker accidentally overexposed to 192Ir, the mathematical extrapolation and comparison with clinical data. MATERIAL AND METHODS: Unstable chromosome aberrations were measured using conventional cytogenetic tests by French and Iranian biological dosimetry laboratories on five occasions after the exposure. The decrease in dicentrics over time was analysed mathematically. In addition, Dolphin and Qdr extrapolations were applied to the data to check the exposure estimates. FISH determination of translocation yields was performed twice by the French laboratory and the results compared with the Dolphin and Qdr corrected values. RESULTS: Dose estimates based on dicentrics decreased from 3.1 +/- 0.4 Gy at 5 days after the accident to 0.8 +/- 0.2 Gy at 529 days. This could be fitted by double-exponential regression with an inflexion point between rapid and slow decrease of dicentrics after about 40 days. Dose estimates of 3.4 +/- 0.4 Gy for the Qdr model and 3.6 +/- 0.5 Gy for the Dolphin model were calculated during the post-exposure period and were remarkably stable. FISH translocation data at 26 and 61 days appeared consistent with the Dolphin and Qdr estimates. CONCLUSION: Dose correction by the Qdr and Dolphin models and translocation scoring appeared consistent with the clinical data and provided better information about the radiation injury than did crude estimates from dicentric scoring alone. Estimation by the Dolphin model of the irradiated fraction of the body seemed unreliable: it correlated better with the fraction of originally irradiated lymphocytes.

Fast-FISH technique for rapid, simultaneous labeling of all human centromeres.

Fluorescence in situ hybridization (FISH) has become a powerful tool in chromosome analysis. This report describes the systematic optimization of the Fast-FISH technique for centromere labeling of human metaphase chromosomes for radiobiological dosimetry purposes. For the present study, the hybridization conditions and the efficiency of two commercially available alpha-satellite DNA probes were compared ("human chromosome 1 specific", Oncor, Gaithersburg, MD, vs. "all-human chromosomes specific", Boehringer-Mannheim, Germany). These probes were hybridized to human lymphocyte metaphase plates by using a hybridization buffer without formamide and without any other equivalent denaturing chemical agents. The results indicate the suitability of the method for automated image analysis on the basis of thresholding. The optimal conditions concerning hybridization time and temperature were determined by a systematic quantitative evaluation of the fluorescent labeling sites after the hybridization procedures. Under defined "low stringency" conditions, we found that the "human chromosome 1 specific" DNA probe labeled not only the centromere of the human chromosome 1 but also the other human centromeres in the same way as the "all-human chromosome specific" DNA probe. The optimized conditions to complete all centromere labeling were applied to the detection of dicentric chromosomes on irradiated human lymphocyte samples (gamma-rays of 60Co source, 0.5 Gy/min, for doses of 1, 3, and 4 Gy). The yield of dicentrics was determined after Fast-FISH and compared with results obtained after Giemsa staining. These results are very compatible and indicate that, because of its simplicity, this optimized Fast-FISH procedure would be useful for fast screening purposes in biological dosimetry after accidental overexposure.

Is FISH painting an appropriate biological marker for dose estimates of suspected accidental radiation overexposure? A review of cases investigated in France from 1995 to 1996.

From 1995 to 1996 about 15 people suspected of being overexposed to ionizing radiation were referred to the Institute for Nuclear Safety and Protection in Fontenay-aux-Roses, France, for investigation by chromosome aberration analysis. Biological estimates of accidental overexposure were first obtained by scoring radio-induced unstable structural chromosome aberrations (dicentrics, centric rings, and fragments) in peripheral blood lymphocytes. For dose estimates, the yield of these chromosomal aberrations observed in 500 metaphases was compared with the laboratory dose-response relationship established from human blood irradiated in vitro (gamma-rays, 60Co, 0.5 Gy/min). To extend the possibilities of detecting DNA damage from earlier exposures by visualizing stable chromosome aberrations, chromosome painting by fluorescence in situ hybridization (FISH painting) was developed using a cocktail of three composite whole human chromosome-specific DNA probes (numbers 2, 4, and 12). A laboratory calibration curve for scoring terminal and/or reciprocal translocations was established for the same radiation quality and dose rate as those used for conventional cytogenetics (gamma-rays, 60Co, 0.5 Gy/min). For dosimetry purposes, it was also important to verify whether FISH painting could be applied to each human blood sample assessed for conventional expertise. For each individual, 2000 metaphases were scored for the presence or absence of reciprocal and terminal translocations. We present here a comparison between the results obtained by the two technologies for each of the cases studied separately. We describe their similarities or differences and discuss the suitability of using FISH painting for routine expertise analysis.

Comparison between fluorescence in situ hybridization and conventional cytogenetics for dicentric scoring: a first-step validation for the use of FISH in biological dosimetry.

In this study the suitability of fluorescence in situ hybridization (FISH) for dicentric detection using a commercially available alpha-satellite probe (Oncor) to label centromeres was compared with the conventional technique for the detection of unstable aberrations. A standard FISH protocol was applied for centromere labelling. Dose-response curves using blood samples irradiated in vitro with gamma-rays (60Co) at a dose-rate of 0.1 Gy/min were established using both techniques and compared. No statistical difference was observed between either method. The FISH technique thus allows a correct detection of unstable aberrations when an alpha-satellite DNA probe is used.