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1.
Radiat Prot Dosimetry ; 164(1-2): 51-6, 2015 Apr.
Article in English | MEDLINE | ID: mdl-25394649

ABSTRACT

The purpose of this paper is to present (1) the method of assessing the contribution of short-lived radioiodines to the thyroid for members of the public in Fukushima and neighbouring prefectures based on available data and (2) the results of a realistic assessment of such a contribution. The estimates of that contribution for the inhalation intake that occurred on the day of the main fallout (15 March 2011) are within 15 % of the dose to the thyroid from (131)I. The contribution to the thyroid dose from intake of (132)Te is higher than that from the intake of (133)I by a factor of ∼3. The contribution of short-lived radioiodines to the thyroid dose for the public in the case of inhalation intake occurring as early as March 12 might be as great as 30-40 %.


Subject(s)
Fukushima Nuclear Accident , Iodine Radioisotopes/pharmacokinetics , Models, Biological , Radioactive Fallout/analysis , Radiometry/methods , Thyroid Gland/metabolism , Absorption, Radiation/physiology , Administration, Inhalation , Computer Simulation , Half-Life , Humans , Iodine Radioisotopes/administration & dosage , Reproducibility of Results , Sensitivity and Specificity
2.
Med Tr Prom Ekol ; (10): 1-5, 2012.
Article in Russian | MEDLINE | ID: mdl-23210176

ABSTRACT

The nuclear accident occurred at Fukushima Dai-ichi Nuclear Power Plant (NPP) (March 11, 2011) similarly to the accident at the Chernobyl NPP (April 26, 1986) is related to the level 7 of the INES. It is of interest to make an analysis of the radionuclide composition of the fallout following the both accidents. The results of the spectrometric measurements were used in that comparative analysis. Two areas following the Chernobyl accident were considered: (1) the near zone of the fallout - the Belarusian part of the central spot extended up to 60 km around the Chernobyl NPS and (2) the far zone of the fallout--the "Gomel-Mogilev" spot centered 200 km to the north-northeast of the damaged reactor. In the case of Fukushima accident the near zone up to about 60 km considered. The comparative analysis has been done with respect to refractory radionuclides (95Zr, 95Nb, 141Ce, 144Ce), as well as to the intermediate and volatile radionuclides 103Ru, 106Ru, 131I, 134Cs, 137Cs, 140La, 140Ba and the results of such a comparison have been discussed. With respect to exposure to the public the most important radionuclides are 131I and 137Cs. For the both accidents the ratios of 131I/137Cs in the considered soil samples are in the similar ranges: (3-50) for the Chernobyl samples and (5-70) for the Fukushima samples. Similarly to the Chernobyl accident a clear tendency that the ratio of 131I/137Cs in the fallout decreases with the increase of the ground deposition density of 137Cs within the trace related to a radioactive cloud has been identified for the Fukushima accident. It looks like this is a universal tendency for the ratio of 131I/137Cs versus the 137Cs ground deposition density in the fallout along the trace of a radioactive cloud as a result of a heavy accident at the NPP with radionuclides releases into the environment. This tendency is important for an objective reconstruction of 131I fallout based on the results of 137Cs measurements of soil samples carried out at late dates after the Fukushima accident.


Subject(s)
Cesium Radioisotopes/analysis , Chernobyl Nuclear Accident , Fukushima Nuclear Accident , Iodine Radioisotopes/analysis , Radioactive Fallout/analysis , Humans , Japan , Nuclear Power Plants , Radiation Dosage , Radiation Monitoring/methods , Soil Pollutants, Radioactive/analysis , Spectrometry, Gamma , USSR
3.
J Radiol Prot ; 28(4): 499-509, 2008 Dec.
Article in English | MEDLINE | ID: mdl-19029584

ABSTRACT

Regulatory cooperation between the Norwegian Radiation Protection Authority and the Federal Medical Biological Agency (FMBA) of the Russian Federation has the overall goal of promoting improvements in radiation protection in Northwest Russia. One of the projects in this programme has the objectives to review and improve the existing medical emergency preparedness capabilities at the sites for temporary storage of spent nuclear fuel and radioactive waste. These are operated by SevRAO at Andreeva Bay and in Gremikha village on the Kola Peninsula. The work is also intended to provide a better basis for regulation of emergency response and medical emergency preparedness at similar facilities elsewhere in Russia. The purpose of this paper is to present the main results of that project, implemented by the Burnasyan Federal Medical Biophysical Centre. The first task was an analysis of the regulatory requirements and the current state of preparedness for medical emergency response at the SevRAO facilities. Although Russian regulatory documents are mostly consistent with international recommendations, some distinctions lead to numerical differences in operational intervention criteria under otherwise similar conditions. Radiological threats relating to possible accidents, and related gaps in the regulation of SevRAO facilities, were also identified. As part of the project, a special exercise on emergency medical response on-site at Andreeva Bay was prepared and carried out, and recommendations were proposed after the exercise. Following fruitful dialogue among regulators, designers and operators, special regulatory guidance has been issued by FMBA to account for the specific and unusual features of the SevRAO facilities. Detailed sections relate to the prevention of accidents, and emergency preparedness and response, supplementing the basic Russian regulatory requirements. Overall it is concluded that (a) the provision of medical and sanitary components of emergency response at SevRAO facilities is a priority task within the general system of emergency preparedness; (b) there is an effective and improving interaction between SevRAO and the local medical institutions of FMBA and other territorial medical units; (c) the infrastructure of emergency response at SevRAO facilities has been created and operates within the framework of Russian legal and normative requirements. Further proposals have been made aimed at increasing the effectiveness of the available system of emergency preparedness and response, and to promote interagency cooperation.


Subject(s)
Civil Defense/legislation & jurisprudence , Emergency Medical Services/legislation & jurisprudence , Industrial Waste/prevention & control , Radiation Monitoring/legislation & jurisprudence , Radiation Protection/legislation & jurisprudence , Radioactive Waste/prevention & control , Waste Management/legislation & jurisprudence , Government Regulation , Humans , Nuclear Reactors/legislation & jurisprudence , Russia , Safety Management/legislation & jurisprudence
4.
Radiat Prot Dosimetry ; 108(2): 143-60, 2004.
Article in English | MEDLINE | ID: mdl-14978294

ABSTRACT

Following the Chernobyl accident, radioactive fission products, including (131)I and (137)Cs, were deposited in Bryansk Oblast in Russia. Intakes of radioiodines, mainly (131)I in milk, were the principal sources of radiation doses to thyroids of residents of the contaminated areas, but those radionuclides decayed before detailed contamination surveys could be performed. As a result, (137)Cs deposition density is the primary measure of the contamination due to the accident and there are relatively few measurements of the ratio of (131)I to (137)Cs in vegetation or soil samples from this area. Although many measurements of radiation emitted from the necks of residents were performed and used to estimate thyroidal (131)I activities and thyroid doses, such data are not available for all subjects. The semi-empirical model was selected to provide a dose calculation method to be applied uniformly to cases and controls in the study. The model was developed using dose estimates from direct measurements of (131)I in adult thyroids, and relates settlement average thyroid doses to (137)Cs contamination levels and ratios of (131)I to (137)Cs. This model is useful for areas where thyroid monitoring was not performed and can be used to estimate doses to exposed individuals. For application to children in this study, adjustment factors are used to address differences in age-dependent intake rates and thyroid dosimetry. Other individual dietary factors and sources (private/public) of milk consumed are reflected in the dose estimates. Countermeasures that reduced thyroid dose, such as cessation of milk consumption and intake of stable iodine, are also considered for each subject. The necessary personal information of subjects was obtained by interview, most frequently of their mothers, using a questionnaire developed for the study. Uncertainties in thyroid dose, estimated using Monte Carlo techniques, are presented for reference conditions. Thyroid dose estimates for individual children made using the semi-empirical model and questionnaire data compare reasonably well with dose estimates made for 19 children whose thyroid burdens of (131)I were measured from May to June 1986.


Subject(s)
Neoplasms, Radiation-Induced/epidemiology , Radiometry/methods , Thyroid Gland/radiation effects , Thyroid Neoplasms/etiology , Animals , Case-Control Studies , Cesium Radioisotopes , Child , Female , Humans , Iodine Radioisotopes , Male , Milk/metabolism , Models, Theoretical , Monte Carlo Method , Power Plants , Radioactive Hazard Release , Russia , Soil Pollutants, Radioactive , Thyroid Neoplasms/epidemiology , Ukraine
5.
Health Phys ; 76(2): 105-19, 1999 Feb.
Article in English | MEDLINE | ID: mdl-9929121

ABSTRACT

The Chernobyl accident in April 1986 resulted in widespread contamination of the environment with radioactive materials, including (131)I and other radioiodines. This environmental contamination led to substantial radiation doses in the thyroids of many inhabitants of the Republic of Belarus. The reconstruction of thyroid doses received by Belarussians is based primarily on exposure rates measured against the neck of more than 200,000 people in the more contaminated territories; these measurements were carried out within a few weeks after the accident and before the decay of (131)I to negligible levels. Preliminary estimates of thyroid dose have been divided into 3 classes: Class 1 ("measured" doses), Class 2 (doses "derived by affinity"), and Class 3 ("empirically-derived" doses). Class 1 doses are estimated directly from the measured thyroidal (131)I content of the person considered, plus information on lifestyle and dietary habits. Such estimates are available for about 130,000 individuals from the contaminated areas of the Gomel and Mogilev Oblasts and from the city of Minsk. Maximum individual doses are estimated to range up to about 60 Gy. For every village with a sufficient number of residents with Class 1 doses, individual thyroid dose distributions are determined for several age groups and levels of milk consumption. These data are used to derive Class 2 thyroid dose estimates for unmeasured inhabitants of these villages. For any village where the number of residents with Class 1 thyroid doses is small or equal to zero, individual thyroid doses of Class 3 are derived from the relationship obtained between the mean adult thyroid dose and the deposition density of (131)I or 137Cs in villages with Class 2 thyroid doses presenting characteristics similar to those of the village considered. In order to improve the reliability of the Class 3 thyroid doses, an extensive program of measurement of (129)I in soils is envisaged.


Subject(s)
Cesium Radioisotopes , Iodine Radioisotopes , Power Plants , Radiation Dosage , Radioactive Fallout , Radioactive Hazard Release , Thyroid Gland/radiation effects , Adolescent , Adult , Age Factors , Animals , Child , Child, Preschool , Diet , Geography , Humans , Infant , Life Style , Milk , Republic of Belarus , Rural Population , Soil Pollutants, Radioactive , Tellurium , Ukraine , Urban Population
6.
Health Phys ; 71(5): 733-40, 1996 Nov.
Article in English | MEDLINE | ID: mdl-8887520

ABSTRACT

Radioiodine released to the atmosphere from the accident at the Chernobyl nuclear power station in the spring of 1986 resulted in large-scale thyroid-gland exposure of populations in Ukraine, Belarus, and Russia. Because of the short half life of 131I (8.04 d), adequate data on the intensities and patterns of iodine deposition were not collected, especially in the regions where the incidence of childhood-thyroid cancer is now increasing. Results are presented from a feasibility study that show that accelerator-mass-spectrometry measurements of 129I (half life 16 x 106 y) in soil can be used to reconstruct 131I-deposition density and thus help in the thyroid-dosimetry effort that is now urgently needed to support epidemiologic studies of childhood-thyroid cancer in the affected regions.


Subject(s)
Iodine Radioisotopes/analysis , Radiation Monitoring/methods , Soil Pollutants, Radioactive/analysis , Cesium Radioisotopes/analysis , Nuclear Reactors , Plutonium/analysis , Power Plants , Radioactive Hazard Release , Republic of Belarus , Ukraine
7.
Vestn Akad Med Nauk SSSR ; (2): 35-43, 1992.
Article in Russian | MEDLINE | ID: mdl-1385668

ABSTRACT

The authors provide the results of studying the reconstruction of individual doses of thyroid radiation among the community living in polluted areas of the Byelorussian Republic according to radiation monitoring data and with regard to the nature of radioactive pollution of the land. Every individual result of estimating the degree of thyroid radiation was characterized by 3 magnitudes: the lower and upper limit of possible values and by the intermediate (basic) value. The authors hold that studies of the correlations between the values of individual doses of thyroid radiation and different parameters of the radiation situation in every region will promote further specification of individual doses of thyroid radiation.


Subject(s)
Accidents , Nuclear Reactors , Population Surveillance , Thyroid Gland/radiation effects , Humans , Radiation Dosage , Republic of Belarus , Ukraine
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