Long-term development of the radionuclide exposure of murine rodent populations in Belarus after the Chernobyl accident.

As a determinant of the associated health risks, the behavior of radionuclides in natural ecosystems needs to be better understood. Therefore, the activity concentration of various long-lived radionuclides released due to the Chernobyl accident, and the corresponding contributions to the whole-body dose rate, was studied as a function of time in mammalian indicator species inhabiting the natural forest ecosystems of Belarus, the bank vole (Clethrionomys glareolus) and the yellow-necked mouse (Apodemus flavicollus). The activity concentrations of 137Cs, 134Cs, 90Sr, 238Pu, 239,240Pu, 241Pu and 241Am in soil and in animals were measured at five monitoring sites with different ground deposition of radionuclides at different distances from the destroyed reactor. The observed temporal pattern of the radionuclide activity concentration in the studied animal populations reflects the changes in biological availability of these isotopes for biota, mostly due to fuel particle destruction and appearance of dissolved and exchangeable forms of radionuclides. The time course of 134+137Cs activity concentrations in animal populations appeared as a sequence of increase, peak and decrease. Maximal levels of radiocesium occurred 1-2 years after deposition, followed by an exponential decrease. Concentrations of incorporated 90Sr increased up to the tenth year after deposition. The activity concentrations of transuranic elements (238Pu, 239,240Pu, 241Pu and 241Am) were much lower than those of the other radionuclides, in the studied animals. A considerable activity of 241Am in animals from areas with high levels of contamination was firstly detected 5 years after deposition, it increased up to the tenth year and is expected to increase further in the future. Maximal values of the whole-body absorbed dose rates occurred during the year of deposition, followed by a decrease in the subsequent period. Generally, this decrease was monotonic, mainly determined by the decrease of the external gamma-ray dose rate, but there were exceptions due to the delayed maximum of internal exposure. The inter-individual distributions of radionuclide concentrations and lifetime whole-body absorbed doses were asymmetric and close to log-normal, including concentrations and doses considerably higher than the population mean values.

[Genetic efficacy of low doses of ionizing radiation in chronically-irradiated small mammals]. / Geneticheskaia éfffektivnost' malykh doz ioniziruiushchei radiatsii pri khornicheskom obluchenii melkikh mlekopitaiushchikh.

Earlier we have established the genetic effects of low dose chronic irradiation in bank vole (somatic and germ cells, embryos), in pond carp (fertilized eggs, embryos, fry) and in laboratory mice (somatic and germ cells) in the range of doses from near-background to 10 cGy. These low dose effects observed in mammals and fish are not expected from extrapolation of high dose experiments. For understanding reasons this discrepancy the comparative analysis of genetic efficiency of low dose chronic irradiation and the higher doses of acute irradiation was carried out with natural populations of bank vole which inhabited the two sites differing in ground of radionuclide deposition. For comparing efficiency the linear regression model of dose-effect curve was used. Dose-effect equations were obtained for animals from two chronically irradiated bank vole populations. The mean population absorbed doses were in the range 0.04-0.68 cGy, the main part of absorbed doses consisted of external radiation of animals exposed to 137Cs gamma-rays. Dose-effect equations for acute irradiation to 137Cs gamma-rays (10-100 cGy) were determined for the same populations. Comparison of genetic efficiency was made by extrapolation, using regression coefficient beta and doubling dose estimation. For chronic exposure the doubling doses calculated from low-dose experiments are 0.1-2 cGy and the doubling doses determined from high-dose experiments are in the range of 5-20 cGy. Our hypothesis that the doubling dose estimate is calculated in higher-dose ionizing radiation experiments should be much higher than the deduced from the low dose line regression equation was verified. The doubling dose estimates for somatic cells of bank vole and those for germ cells of laboratory mice are in close agreement. The radiosensitivity of bank vole chromosomes were shown is practically the same as that for human lymphocytes since doubling dose estimates for acute irradiation close to each other. For low LET radiation a higher genetic efficiency of chronic low doses in comparison with the higher doses of acute gamma-irradiation (137Cs source) was proved by three methods.