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.

HUman MicroNucleus project: international database comparison for results with the cytokinesis-block micronucleus assay in human lymphocytes: I. Effect of laboratory protocol, scoring criteria, and host factors on the frequency of micronuclei.

Micronucleus (MN) expression in peripheral blood lymphocytes is well established as a standard method for monitoring chromosome damage in human populations. The first results of an analysis of pooled data from laboratories using the cytokinesis-block micronucleus (CBMN) assay and participating in the HUMN (HUman MicroNucleus project) international collaborative study are presented. The effects of laboratory protocol, scoring criteria, and host factors on baseline micronucleated binucleate cell (MNC) frequency are evaluated, and a reference range of "normal" values against which future studies may be compared is provided. Primary data from historical records were submitted by 25 laboratories distributed in 16 countries. This resulted in a database of nearly 7000 subjects. Potentially significant differences were present in the methods used by participating laboratories, such as in the type of culture medium, the concentration of cytochalasin-B, the percentage of fetal calf serum, and in the culture method. Differences in criteria for scoring micronuclei were also evident. The overall median MNC frequency in nonexposed (i.e., normal) subjects was 6.5 per thousand and the interquartile range was between 3 and 12 per thousand. An increase in MNC frequency with age was evident in all but two laboratories. The effect of gender, although not so evident in all databases, was also present, with females having a 19% higher level of MNC frequency (95% confidence interval: 14-24%). Statistical analyses were performed using random-effects models for correlated data. Our best model, which included exposure to genotoxic factors, host factors, methods, and scoring criteria, explained 75% of the total variance, with the largest contribution attributable to laboratory methods.

Radiation effects in lymphocytes of children living in a Chernobyl contaminated region of Belarus.

PURPOSE: To investigate cytogenetic and mutational effects in lymphocytes from individuals chronically exposed to radiation from the Chernobyl catastrophe. MATERIALS AND METHODS: Nine years after the Chernobyl accident (1986), peripheral blood lymphocytes from 20 Kalinkovichi children (age 10-15) and 10 Minsk children (age 10-17) were analysed for genetic damage by several assays. Radiation damage in exposed children was investigated in descendants of progenitor cells that were irradiated during a short period immediately after the accident. In the time-span between the accident and blood sampling the cells were also irradiated chronically by internal radiation originating from ingested radionuclides and, to a smaller extent, by external radiation from radionuclides. The parameters measured in whole blood smears were the frequency of micronucleated mononucleated lymphocytes and binucleated lymphocytes with nucleoplasmic bridges and associated micronuclei. Cultures of cytokinesis-blocked lymphocytes were used to analyse mononuclear and binuclear cells for the presence of micronuclei, also cell killing effects. A colony assay was used to study induction of recessive mutations in the HPRT gene. RESULTS: The analysis of whole-blood smears indicated a doubling of the frequency of micronuclei per 100 mononuclear lymphocytes in exposed children compared with unirradiated children. Small numbers of binucleated lymphocytes with nucleoplasmic bridges and associated micronuclei were found in blood smears from exposed children. Analysis of cytokinesis-blocked cultures indicated in mononuclear cells of exposed children a statistically significant increase in the frequency of micronuclei. When the same parameters were studied in binucleated cells there was no difference between exposed and unexposed children. Results of the dye-exclusion assay showed a four-fold increase in the percentage of dead cells between exposed and unexposed children. There was no evidence for induction of HPRT mutations in exposed children. CONCLUSION: These results indicate that the frequently advocated procedure of simply analysing micronuclei in cytokinesis-blocked binucleated lymphocytes can result in an underestimate of genetic damage induced by radiation accidents. Biodosimetric studies should therefore employ a battery of assays for the detection of several types of genetic damage in different generations of lymphocytes.

Low prevalence of the ret/PTC3r1 rearrangement in a series of papillary thyroid carcinomas presenting in Belarus ten years post-Chernobyl.

After the Chernobyl accident in 1986, there was a significant increase in the incidence of papillary thyroid cancer in fallout-exposed children from Belarus. Radiation-induced rearrangements of chromosome 10 involving the c-ret proto-oncogene have been implicated in the pathogenesis of these cancers. The ret/PTC3r1 rearrangement was the most prevalent molecular lesion identified in post-Chernobyl papillary thyroid cancers arising in 1991 and 1992. We identified the ret/PTC1 rearrangement in 29% of 31 papillary thyroid cancers presenting in Belarus in 1996. In the present report, we examined 14 cases from this series (plus 1 additional case) and found a ret/PTC3r1 rearrangement in only 1 (7%). The prevalence of ret/PTC3r1 in this series is significantly lower than previously reported (p = 0.0006, Fisher exact test). This result suggests a switch in the ratio of ret/PTC3 to ret/PTC1 rearrangements in late (1996) versus early (1991-1992) post-Chernobyl papillary thyroid cancers.

A more comprehensive application of the micronucleus technique for biomonitoring of genetic damage rates in human populations--experiences from the Chernobyl catastrophe.

The current method for scoring micronuclei as a measure of genetic damage rate in peripheral blood cells is to enumerate this end point in cytokinesis-blocked binucleated cultured lymphocytes. However, one can expect that, due to chronic exposure to genotoxins or inherent genetic instability, micronuclei may be expressed continually in vivo in dividing cell populations such as the progenitor cell lineages leading to mature lymphocytes or erythrocytes. Consequently, micronuclei may already be expressed in peripheral blood lymphocytes prior to culture. In view of these considerations, we have performed a study in children living in regions of Belarus that are contaminated by radionuclides from the Chernobyl disaster and compared their micronucleus frequency in erythrocytes, nondivided lymphocytes, and cultured cytokinesis-blocked binucleated lymphocytes to that of controls living in noncontaminated areas. Preliminary data presented in this paper indicate a significant two- to fourfold increase in micronucleus expression (P < 0.05) in exposed children relative to controls in erythrocytes or peripheral blood lymphocytes in blood smears as well as in mononuclear and cytokinesis-blocked binucleated lymphocytes in cultures. The measurement of micronuclei in nondivided mononuclear lymphocytes represents chromosomal damage expressed during in vivo divisions. The micronuclei in binucleated cultured cells represent micronuclei expressed ex-vivo and may include micronuclei already present in a cell prior to tissue culture. These preliminary data suggest that a different spectrum and level of damage may be observed in nondivided mononuclear lymphocytes, binucleated lymphocytes, and erythrocytes and that a combination of these approaches may provide a more comprehensive assessment of the extent of genetic damage induced by chronic exposure to radionuclides or other genotoxins in haematopoietic tissue.