Literature DB >> 15658887

Post-Chornobyl thyroid cancers in Ukraine. Report 1: estimation of thyroid doses.

I Likhtarov1, L Kovgan, S Vavilov, M Chepurny, A Bouville, N Luckyanov, P Jacob, P Voillequé, G Voigt.   

Abstract

About 1.8 EBq of 131I was released into the atmosphere during the Chornobyl accident that occurred in Ukraine on April 26, 1986. More than 10% of this activity was deposited on the territory of Ukraine. Beginning 4-5 years after the accident, an increase in the incidence of thyroid cancer among children, believed to be caused in part by exposure to 131I, has been observed in different regions of Ukraine. A three-level system of thyroid dose estimation was developed for the reconstruction of thyroid doses from 131I for the entire population of Ukrainian children aged 1 to 18 at the time of accident: (1) At the first level, individual doses were estimated for the approximately 99,000 children and adolescents with direct measurements of radioactivity in the thyroid (so-called direct thyroid measurements) performed in May-June of 1986; (2) at the second level, group doses by year of age and by gender were estimated for the population of 748 localities (with 208,400 children aged 1-18 in 1986) where direct thyroid measurements of good quality were performed on some of the residents; and (3) at the third level, group doses by age and by gender were estimated for the population of the localities where no thyroid measurements were made in 1986. The third-level doses were then aggregated over the population of each oblast. Data, models and procedures required for each level of thyroid dose estimation are described in the paper. At the first level, individual doses were found to range up to 27,000 mGy, with geometric and arithmetic means of 100 and 300 mGy, respectively. At the second level, group doses were found to be highest for the younger children (aged 1 to 4 years); doses for the older children (aged 16 to 18 years) were 3.5 times smaller. At the third level, average population-weighted doses were found to exceed 35 mGy in the five northern oblasts closer to the Chornobyl reactor site; to be in the 14- to 34-mGy range in seven other oblasts, Kyiv city and Crimea; and to be less than 13 mGy in all other oblasts.

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Year:  2005        PMID: 15658887     DOI: 10.1667/rr3291

Source DB:  PubMed          Journal:  Radiat Res        ISSN: 0033-7587            Impact factor:   2.841


  21 in total

1.  Thyroid cancer incidence in Ukraine: trends with reference to the Chernobyl accident.

Authors:  M Fuzik; A Prysyazhnyuk; Y Shibata; A Romanenko; Z Fedorenko; L Gulak; Y Goroh; N Gudzenko; N Trotsyuk; O Khukhrianska; V Saenko; S Yamashita
Journal:  Radiat Environ Biophys       Date:  2010-11-10       Impact factor: 1.925

2.  Estimation of radiation risk in presence of classical additive and Berkson multiplicative errors in exposure doses.

Authors:  S V Masiuk; S V Shklyar; A G Kukush; R J Carroll; L N Kovgan; I A Likhtarov
Journal:  Biostatistics       Date:  2016-01-20       Impact factor: 5.899

3.  Estimation of the thyroid doses for ukrainian children exposed in utero after the chernobyl accident.

Authors:  I Likhtarov; L Kovgan; M Chepurny; O Ivanova; Z Boyko; G Ratia; S Masiuk; V Gerasymenko; V Drozdovitch; V Berkovski; M Hatch; A Brenner; N Luckyanov; P Voillequé; A Bouville
Journal:  Health Phys       Date:  2011-06       Impact factor: 1.316

4.  Screening effects in risk studies of thyroid cancer after the Chernobyl accident.

Authors:  Jan Christian Kaiser; P Jacob; M Blettner; S Vavilov
Journal:  Radiat Environ Biophys       Date:  2009-02-12       Impact factor: 1.925

5.  Methods for estimation of radiation risk in epidemiological studies accounting for classical and Berkson errors in doses.

Authors:  Alexander Kukush; Sergiy Shklyar; Sergii Masiuk; Illya Likhtarov; Lina Kovgan; Raymond J Carroll; Andre Bouville
Journal:  Int J Biostat       Date:  2011-02-16       Impact factor: 0.968

6.  American Thyroid Association Scientific Statement on the Use of Potassium Iodide Ingestion in a Nuclear Emergency.

Authors:  Angela M Leung; Andrew J Bauer; Salvatore Benvenga; Alina V Brenner; James V Hennessey; James R Hurley; Stacey A Milan; Arthur B Schneider; Krishnamurthi Sundaram; Daniel J Toft
Journal:  Thyroid       Date:  2017-06-21       Impact factor: 6.568

7.  Genomic copy number analysis of Chernobyl papillary thyroid carcinoma in the Ukrainian-American Cohort.

Authors:  Martin Selmansberger; Herbert Braselmann; Julia Hess; Tetiana Bogdanova; Michael Abend; Mykola Tronko; Alina Brenner; Horst Zitzelsberger; Kristian Unger
Journal:  Carcinogenesis       Date:  2015-08-29       Impact factor: 4.944

8.  A screening study of thyroid cancer and other thyroid diseases among individuals exposed in utero to iodine-131 from Chernobyl fallout.

Authors:  M Hatch; A Brenner; T Bogdanova; A Derevyanko; N Kuptsova; I Likhtarev; A Bouville; V Tereshchenko; L Kovgan; V Shpak; E Ostroumova; E Greenebaum; L Zablotska; E Ron; M Tronko
Journal:  J Clin Endocrinol Metab       Date:  2008-12-23       Impact factor: 5.958

9.  Thyroid cancer study among Ukrainian children exposed to radiation after the Chornobyl accident: improved estimates of the thyroid doses to the cohort members.

Authors:  Ilya Likhtarov; Lina Kovgan; Sergii Masiuk; Mykola Talerko; Mykola Chepurny; Olga Ivanova; Valentina Gerasymenko; Zulfira Boyko; Paul Voillequé; Vladimir Drozdovitch; André Bouville
Journal:  Health Phys       Date:  2014-03       Impact factor: 1.316

10.  Thyroid doses in Ukraine due to 131I intake after the Chornobyl accident. Report II: dose estimates for the Ukrainian population.

Authors:  Sergii Masiuk; Mykola Chepurny; Valentyna Buderatska; Olga Ivanova; Zulfira Boiko; Natalia Zhadan; Galyna Fedosenko; Andriy Bilonyk; Alexander Kukush; Tatiana Lev; Mykola Talerko; Vladimir Drozdovitch
Journal:  Radiat Environ Biophys       Date:  2021-08-05       Impact factor: 1.925
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