Medical Radiology and Radiation Safety. 2017. Vol. 62.  No. 1. P. 27-31

DOI: 10.12737/25046

Lifetime Risk of Lung Cancer Death for Inhalation ²³⁹Pu

M.E. Sokolnikov, V.V. Vostrotin, A.V. Ephimov, E.K. Vasilenko, S.A. Romanov

Southern Ural Biophysics Institute. Chelyabinsk region, Ozersk, Russia, e-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.

M.E. Sokolnikov - Head of Lab., MD; V.V. Vostrotin - Head of Lab., PhD in Biological Sciences; A.V. Ephimov - Acting head of the division of radiation safety and dosimetry; E.K. Vasilenko - Chief, Southern Urals regional medical-dosimetry center; S.A. Romanov - Director, Southern Ural Biophysics Institute, PhD in Biological Sciences

Abstract

Aim of the study: Assessment of reliability of radiation safety standards after inhalation intake of Pu-239.

Material and methods: Using results of epidemiological study of lung cancer mortality in Mayak workers cohort and statistical data on all causes and lung cancer mortality in Russia the excess lifetime risk of lung cancer death was calculated.

Results: Current radiation safety standards restrict annual intake of Pu-239 class “S” at 1300 Bq/year level. The annual limit of intake is calculated in a way that the level of committed effective dose in 50 years after intake should not exceed 20 mSv. At the same time radiation safety standards restrict the level of the excess lifetime risk of cancer death at the level of 0.05 (for category A personnel) and/or annual increment of excess lifetime risk at the level 0.001. The equivalent dose of alpha-particles to the lung after 50 years of inhalation intake of Pu class “S” when calculated according to DOSE-2008 model will be 7 Sv. Given the pattern of dose accumulation over time after this scenario of Pu class “S” inhalation intake we calculated excess relative risk of lung cancer death, lifetime excess risk of lung cancer death and annual increment of excess lifetime risk. In 50 years of exposure to inhalation intake of Pu-239 class “S” the excess lifetime risk of lung cancer death will be 0.08, i.e. will exceed the 0.05 limit provided in radiation safety standards. The annual increment of the lifetime risk will exceed limit of 0.001, provided by the radiation safety standards, at age 45 and older.

These results demonstrate that the protection of personnel working with Pu-239 class “S” is insufficient in current radiation safety standards. One of the potential reasons is that lung contribution to total detriment for organism provided by ionizing radiation is averaged for all ages whereas for people of working age who contact to Pu at work this detriment doubles.

Key words: radiation safety standards, lifetime risk, inhalation intake, Plutonium-239

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For citation: Sokolnikov ME, Vostrotin VV, Ephimov AV, Vasilenko EK, Romanov S.A. Lifetime Risk of Lung Cancer Death for Inhalation ²³⁹Pu. Medical Radiology and Radiation Safety. 2017;62(2):27-31. Russian.DOI: 10.12737/25046

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