Medical Radiology and Radiation Safety. 2021. Vol. 66. № 6. P. 102–110

Comparative Analysis of Approaches to Regulation and Monitoring
of Workers for Internal Radiation Exposure

A.A. Molokanov, B.A.Kukhta, E.Yu. Maksimova 

A.I. Burnasyan Federal Medical Biophysical Center, Moscow, Russia.

Contact person: Andrey Alekseevich Molokanov, e-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.

Abstract

Purpose: Harmonization and improvement of the system for regulating the internal radiation exposure of workers and the basic requirements for ensuring radiation safety with international requirements and recommendations.

Material and methods:  Issues related to the development of approaches to regulation and monitoring of workers for internal radiation exposure in the process of evolution of the ICRP recommendations and the national radiation safety standards, are considered. The subject of analysis is the standardized values: dose limits for workers and permissible levels as well as directly related methods of monitoring of workers for internal radiation exposure, whose purpose is to determine the degree of compliance with the principles of radiation safety and regulatory requirements, including non-exceeding the basic dose limits and permissible levels. The permissible levels of inhalation intake of insoluble compounds (dioxide) of plutonium-239 are considered as a numerical example.

Results: Based on the analysis of approaches to the regulation and monitoring of workers for internal radiation exposure for the period from 1959 to 2019, it is shown that a qualitative change in the approach occurred in the 1990s. It was due to a decrease in the number of standardized values by introducing a single dose limit for all types of exposure: the effective dose E, which takes into account the different sensitivity of organs and tissues for stochastic radiation effects (WT), using the previously accepted concepts of the equivalent dose H and groups of critical organs. From the analysis it follows that the committed effective dose is a linear transformation of the intake, linking these two quantities by the dose coefficient, which does not depend on the time during which the intake occurred, and reflects certain exposure conditions of the radionuclide intake (intake routes, parameters of aerosols and type of radionuclide compounds). It was also shown that the reference value of the function z(t) linking the measured value of activity in an organ (tissue) or in excretion products with the committed effective dose for a reference person, which is introduced for the first time in the publications of the ICRP OIR 2015-2019, makes it possible to standardize the method of measuring the normalized value of the effective dose.

Based on the comparison of the predicted values of  the lung and daily urine excretion activities following constant chronic inhalation intake of insoluble plutonium compounds at a rate equal annual limit of intake (ALI) during the period of occupational activity 50 years it was shown that the modern biokinetic models give a slightly lower level (on average 2 times) of the lungs exposure compared to the models of the previous generation and a proportionally lower level (on average 1.4 times) of plutonium urine excretion for the standard type of insoluble plutonium compounds S. However, for the specially defined insoluble plutonium compound, PuO2, the level of plutonium urine excretion differs significantly downward (on average 11.5 times) compared to the models of the previous generation.

Conclusion: With the practical implementation of new ICRP OIR models, in particular for PuO2 compounds, additional studies should be carried out on the behavior of insoluble industrial plutonium compounds in the human body. Besides, additional possibilities should be used to determine the intake of plutonium by measuring in the human body the radionuclide Am-241, which is the Pu-241 daughter. To determine the plutonium urine excretion, the most sensitive measurement techniques should be used, having a decision threshold about fractions of mBq in a daily urine for S-type compounds and an order of magnitude lower for PuO2 compounds. This may require the development and implementation in monitoring practice the plutonium-DTPA Biokinetic Model.

Key words: committed effective dose, annual equivalent dose on critical organ, regulation, radiation safety standards, monitoring of workers for internal radiation exposure, biokinetic model, dosimetric model 

For citation: Molokanov AA, Kukhta BA, Maksimova EYu. Comparative Analysis of Approaches to Regulation and Monitoring of Workers for Internal Radiation Exposure. Medical Radiology and Radiation Safety. 2021;66(6):102–110.

DOI: 10.12737/1024-6177-2021-66-6-102-110

References

1. Нормы радиационной безопасности НРБ-99/2009. Гигиени¬ческие нормативы СП 2.6.1.2523-09. М. 2009. 100 с. [Radiation safety standards NRB-99/2009. Hygienic standards SP 2.6.1.2523- 09. Moscow. 2009. 100 p. (In Russ.)].

2. Панфилов А.П. Эволюция системы обеспечения радиационной безопасности атомной отрасли страны и ее современное состояние. Радиация и риск. 2016. Том 25. № 1. [Panfilov AP.  Evolution of the radiation safety system of the country's nuclear industry and its current state. Radiation and risk. 2016; 25(1):47-64 (In Russ.)]

3. Нормы радиационной безопасности НРБ-76/87 и Основные санитарные правила работы с радиоактивными веществами и другими источниками ионизирующих излучений ОСП-72/87. – М. 1988. 160 с. [Radiation safety standards NRB-76/87 and Basic sanitary rules for working with radioactive substances and other sources of ionizing radiation OSP-72/87. Moscow. 1988. 160 p. (In Russ.)].

4. Нормы радиационной безопасности НРБ-96. Гигиенические нормативы ГН 2.6.1.054-96. Moscow. 1996. [Radiation safety standards NRB-96. Hygienic standards GN 2.6.1.054-96. Moscow. 1996. (In Russ.)].

5. ICRP, 2007. The 2007 Recommendations of the International Commission on Radiological Protection. ICRP Publication 103. Ann. ICRP 37 (2-4).

6. ICRP, 1991. 1990 Recommendations of the International Commission on Radiological Protection. ICRP Publication 60. Ann. ICRP 21 (1-3).

7. ICRP, 2015. Occupational Intakes of Radionuclides: Part 1. ICRP Publication 130. Ann. ICRP 44(2).

8. ICRP, 2016. The ICRP computational framework for internal dose assessment for reference adults: specific absorbed fractions. ICRP Publication 133. Ann. ICRP 45(2), 1–74.

9. ICRP, 2016. Occupational Intakes of Radionuclides: Part 2. ICRP Publication 134. Ann. ICRP 45(3/4), 1–352.

10. ICRP, 2017. Occupational Intakes of Radionuclides: Part 3. ICRP Publication 137. Ann. ICRP 46(3/4).

11. ICRP, 2019. Occupational intakes of radionuclides: Part 4. ICRP Publication 141. Ann. ICRP 48(2/3).

12. INTERNATIONAL RECOMMENDATIONS FOR X-RAY AND RADIUM PROTECTION, Stokholm, 1992.

13. ICRP, 1951. International recommendations on radiological protection. Revised by the International Commission on Radiological Protection at the Sixth International Congress of Radiology, London, 1950. Br. J. Radiol. 24, 46–53.

14. ICRP, 1959. Recommendations of the International Commission on Radiological Protection. Now known as ICRP Publication 1. Pergamon Press, New York.] и 1960 гг. [ICRP, 1960. Report of Committee II on Permissible Dose for Internal Radiation. ICRP Publication 2. Pergamon Press, London.

15. Нормы радиационной безопасности НРБ-69. М. Атомиздат. 1972. [Radiation safety standards NRB-69. Moscow. Atomizdat. 1972. (In Russ.)].

16. ICRP, 1960. Report of Committee II on Permissible Dose for Internal Radiation. ICRP Publication 2. Pergamon Press, London.

17. ICRP, 1964. Recommendations of the International Commission on Radiological Protection. ICRP Publication 6. Pergamon Press, Oxford.

18. ICRP, 1966. Recommendations of the International Commission on Radiological Protection. ICRP Publication 9. Pergamon Press, Oxford.

19. Санитарные правила работы с радиоактивными веществами и источниками источниками ионизирующих излучений. СПП № 333-60. М. Атомиздат. 1960. [Sanitary rules for working with radioactive substances and sources of ionizing radiation. SPP № 333-60. Moscow. Atomizdat 1960. (In Russ.)].

20. ICRP, 1968. Report of Committee IV on Evaluation of Radiation Doses to Body Tissues from Internal Contamination due to Occupational Exposure. ICRP Publication 10. Pergamon Press, Oxford.

21. ICRP, 1972. The Metabolism of Compounds of Plutonium and Other Actinides. ICRP Publication 19. Pergamon Press, Oxford.

22. ICRP, 1973. Alkaline Earth Metabolism in Adult Man. ICRP Publication 20. Pergamon Press, Oxford.

23. ICRP, 1979. Limits for Intakes of Radionuclides by Workers. ICRP Publication 30 (Part 1). Ann. ICRP 2 (3-4).

24. ICRP, 1986. The Metabolism of Plutonium and Related Elements. ICRP Publication 48. Ann. ICRP 16 (2-3).

25. ICRP, 1994. Human Respiratory Tract Model for Radiological Protection. ICRP Publication 66. Ann. ICRP 24 (1-3).

26. ICRP, 2006. Human Alimentary Tract Model for Radiological Protection. ICRP Publication 100. Ann. ICRP 36 (1-2).

27. ICRP, 1975. Report of the Task Group on Reference Man. ICRP Publication 23. Pergamon Press, Oxford.

28. ICRP, 2002. Basic Anatomical and Physiological Data for Use in Radiological Protection Reference Values. ICRP Publication 89. Ann. ICRP 32 (3-4). 

29. ICRP, 2009. Adult Reference Computational Phantoms. ICRP Publication 110. Ann. ICRP 39 (2).

30. ICRP, 1971. The Assessment of Internal Contamination Resulting from Recurrent or Prolonged Uptakes. ICRP Publication 10A. Pergamon Press, Oxford.

31. ICRP, 1977. Recommendations of the ICRP. ICRP Publication 26. Ann. ICRP 1 (3).

 PDF (RUS) Full-text article (in Russian)

Conflict of interest. The authors declare no conflict of interest.

Financing. The study had no sponsorship.

Contribution. Article was prepared with equal participation of the authors.

Article received: 10.08.2021 

Accepted for publication: 21.09.2021.