Completed Projects
Russian Health Studies Program
Completed Direction 1 Population Studies
Project 1.2a: Data Preservation and Scanning
Principal Investigators:
R.F.: Nikolai Startsev, Urals Research Center for Radiation Medicine
U.S.: Donna Cragle, Oak Ridge Institute for Science and Education
Description: This was a data preservation/records management project focused on establishing a document imaging system at URCRM for preserving valuable medical records of residents of the Southern Urals region exposed to radiation due to the operations at Mayak and environmental releases from there. These documents contain information from 1951 to the present with details on medical examinations, individual dose measurements, addresses, causes of death, and other data necessary for epidemiologic studies and dose reconstruction.
Results: Computer scanning equipment was installed. Scanning, verification, indexing, and creation of a computer database of the scanned documents were completed.
Date completed: September 2005.
Project 1.4: Ozersk Population Dose Reconstruction from Mayak Operations
R.F.: Yuri Mokrov, Mayak
U.S.: Bruce Napier, Pacific Northwest National Laboratory
Brief Description: Phase II of this dose reconstruction project was to reconstruct time-dependent individual radiation doses to the residents of the city of Ozersk, Russia, and the surrounding area from atmospheric releases of radionuclides from nuclear weapons production activities at Mayak from 1948 to 1982. Focus was on the emission of I-131 and dose to the thyroid glands of children. Data will support the epidemiologic study of thyroid cancer in children of Ozersk. This should help resolve the dichotomy between the studies at Hanford (no observed effect) and Chernobyl (large effect). The data also will determine whether these emissions are a confounding factor in the evaluation of radiogenic cancer risk in other groups under study, such as the Extended Techa River Cohort (Project 1.2b) and the Mayak worker cohort (Project 2.2).
Results to date: The Phase I feasibility study was completed on March 31, 2004 and a final report was prepared. For the first time, an estimate of the monthly atmospheric stack releases of I-131 from the two fuel-processing plants was prepared for the period 1948 to 1982. The final product, a dosimetry system, was delivered to the National Cancer Institute in September 2013.
Date Completed: September 2013.
Completed Direction 2 Worker Studies
Project 2.1: Metabolism and Dosimetry of Plutonium Industrial Compounds
Principal Investigators:
R.F.: Valentin Khokhryakov, Southern Urals Biophysics Institute
U.S.: Ronald E. Filipy, Washington State University Tri-Cities
Brief Description: This project was the first collaborative dosimetric project between scientists of the two countries. The project began as a one-year feasibility study to compare the two autopsy programs and progressed to a five-year project with the objective of combining and jointly analyzing the actinide metabolism data collected by the two registries: the Dosimetric Registry of the Mayak Production Association (DRMPA) and the United States Transuranium and Uranium Registries (USTUR). The first priority task of the feasibility study involved a series of sample exchanges to verify that no systematic differences were present in the analytical results obtained by both Registries. The results of the laboratory intercomparisons led to the conclusion that the data accumulated by both registries are reliable, correct, and can be used in joint investigations of actinide metabolism in humans. The primary objective of Phase 2 of Project 2.1 was to combine the data accumulated by both registries, create a joint database, and perform a mutual analysis of the unique information regarding the metabolism and dosimetry of plutonium and americium in the human body.
Results to date: High priority tasks involving the metabolism study and biokinetic modeling were begun during the project. The first important dosimetric finding was made regarding the systemic distribution of plutonium and 241-Am in humans: liver diseases were shown to affect the distribution of plutonium in the body, suggesting a translocation of the actinides from the liver to the skeleton. A comparative analysis of the SUBI lung model used at Mayak for dose assessment with the ICRP 66 model showed an advantage of the SUBI dosimetric lung model after long periods (10 and more years) of inhalation. The SUBI laboratory has since obtained modern instrumentation and reagents and updated radiochemical methods. The whole body counter from the Rocky Flats Plant became operational for measurements of actinides body burden in the Mayak workers.
Date completed: March 2000
Project 2.3: The Deterministic Effects of Occupational Exposure (Funded by the Nuclear Regulatory Commission)
Principal Investigators:
R.F.: Nadezda Okladnikova, Southern Urals Biophysics Institute
U.S.: Niel Wald, University of Pittsburgh
Brief Description: The main aim of this project was to validate the current dose-response models for acute exposure and develop new dose-response models for chronic exposure to external gamma rays and/or incorporated Pu-239.
Results to date: The study resulted in the development and establishment of the clinical-dosimetry database for 591 Mayak workers. This database included demographic, medical, and dosimetry information for 60 cases of acute radiation syndrome (ARS), 207 cases of chronic radiation sickness (CRS), 121 cases of plutonium pneumosclerosis, and 209 workers, who were not diagnosed with an occupational disease (control group). The procedure of performing quality control of the database was developed and carried out to compare the completeness and correspondence of the primary data with the information contained in the database. A code book containing the guidance for coding the primary data was prepared. A library, including "clear" standard data sets, was created. A data access agreement was developed. The database includes data for more than 17,500 person-years of follow-up and consists of more than 3.5 million individual data points. Vital status is known for 90.4% of the workers. Individually measured external gamma doses are available for 93.7% of the workers, and doses of internal exposure are available for 32.5% of the workers who were exposed to Pu-239 aerosols.
Date completed: May 2002.
Project 2.5: Improved Plutonium Dose Assessment Methods in Mayak Workers
Principal Investigators:
R.F.: Sergey Romanov, Southern Urals Biophysics Institute
U.S.: Raymond Guilmette, Los Alamos National Laboratory
Brief Description: In phase III, researchers developed and implemented an effective, improved modeling approach for estimating organ doses to individual Mayak workers and linked best central estimates of dose with quantitative measures of uncertainty in the doses. In addition, investigators used Monte Carlo computational methods to calculate alpha particle radiation dose and dose rate patterns in the parenchymal regions of the lung so as to evaluate the extent and magnitude of non-uniformity of radiation dose delivered to this region of the lung. The main objective of phase IV of Project 2.5 was to obtain new knowledge and implement additional tools to facilitate the development of a new harmonized plutonium dosimetry system, which was intended to replace the Mayak Worker Doses 2005 dosimetry system in Project 2.4, Mayak Worker Dosimetry. This included: 1) experimentally addressing several issues that are crucial for lung dosimetry modeling, i.e., assessing the dose contribution from submicron alpha-emitting aerosols in the air of Mayak workplaces; further validating the fixed plutonium compartment and its incorporation into the physiologically realistic plutonium biokinetic model for lung; and evaluating the rapid absorption of plutonium from the lungs into the blood; 2) combining plutonium dose estimates with the uncertainties for individual Mayak workers by using available urine bioassay and/or postmortem tissue data together with the Bayesian approach implemented as the LANL/SUBI IMPDOS III computer code for individual dose assessment; and 3) applying the probability distributions for intake and biokinetic model parameters to assess the dose for workers monitored for plutonium to Mayak worker cohort members for whom little or no plutonium monitoring data are available.
In FY 2010, Project 2.5 was merged into Project 2.4.
Results to date: This project provided valuable insights into the radiobiology and dosimetry of plutonium sequestered for decades in the lungs of Mayak workers. It was the first study to demonstrate in humans that inhaled plutonium is sequestered in the lung parenchyma. This information is being used to modify the human respiratory tract dosimetry models for improved lung dosimetry. In Phase II, microscopic analyses of the distribution of plutonium in the lungs of 24 Mayak workers showed that there was significantly more plutonium retained in the parenchymal regions of the lung than was predicted using either ICRP 66 or ICRP 30 respiratory tract dosimetry models. This long-term retention occurred for both allegedly more soluble and less soluble forms of the inhaled plutonium aerosol. Although in some cases, the fraction of plutonium remaining in lung was a small fraction of the plutonium body burden at death, this portion still contributed a significant amount of the total radiation dose to lung because of its very long retention time, i.e., decades after exposure. The consequence of underestimating the lung dose is that it leads to overestimating the risk coefficient per unit dose for radiation-induced lung diseases in epidemiological studies. Thus, using models that do not accurately represent the central values of dose for a population of measured data will introduce bias into the dose and risk assessment.
Date Merged into Project 2.4: September 2009.
Project 2.6: Molecular Markers of Lung Cancer in Mayak Workers
Principal Investigators:
R.F.: Vitaliy Telnov, Southern Urals Biophysics Institute
U.S.: Steve Belinsky, Lovelace Respiratory Research Institute
Brief Description: This molecular epidemiology study tested for existence of early molecular markers of lung cancer due from radiation exposure following the inhalation of airborne plutonium. The first working hypothesis was that the frequency of methylation of the CpG islets of MGMT, p16, DAP-kinase, RASSF1A, and other genes in adenocarcinomas and squamous cell carcinomas was higher in plutonium-exposed workers than in unexposed subjects. The second working hypothesis was that the abnormal methylation of critical regulatory genes of carcinogenesis served as a biomarker for the pre-clinical diagnosis of lung cancer in living plutonium-exposed workers.
Results to date: The original project demonstrated that plutonium plant workers with adenocarcinoma of the lung, when compared to controls and after adjustment for age and gender, had a statistically significant increased risk of methylation of the p16 tumor suppressor gene. This means that the gene designed to prevent lung cancer was inactivated by the exposure to inhaled plutonium. The final phase of the research examined methylation profiles in both adenocarcinomas and squamous cell carcinomas of the lung.
Date Completed: September 2008.
Project 2.7: Radiation Biomarkers
Principal Investigators:
R.F.: Tamara Azizova, Southern Urals Biophysics Institute
U.S.: David Brenner, Columbia University
Brief Description: This molecular epidemiology study developed a new biological dosimetry test using blood samples to determine internal and external radiation exposures. More specifically, by analyzing heritable changes in chromosomes in blood samples from Mayak workers exposed to different combinations of external and internal radiation for many years, the investigators successfully developed a calibrated test that provided an estimate of both the internal and external ionizing radiation doses. Such a biomarker could significantly increase the power of epidemiologic studies of individuals exposed to densely-ionizing radiations, such as alpha particles, e.g., radon, plutonium workers, or neutrons, e.g., DOE/NRC workers, airline personnel.
Results to date: This study was the first to demonstrate a statistically significant dose-response between plutonium exposure and intra-arm chromosomal aberrations from worker blood samples. In fact, the test was sensitive enough to distinguish internal from external exposures. The researchers successfully developed a dosimetry test capable of calibrating both internal and external ionizing radiation doses with the effects.
Date Completed: September 2008.
Project 2.9: Database Integration
Principal Investigators:
R.F.: Sergey Romanov, Southern Urals Biophysics Institute and Evgeny Vasilenko, Mayak
U.S.: Eric Grant, Radiation Effects Research Foundation
Brief Description: The fundamental goal of this project was to improve the quality and accessibility of the data needed for studies of radiation health effects and dosimetry in Mayak workers and the Ozersk population carried out by SUBI researchers and their collaborators. This project was developed to combine databases located in four different laboratories of two Russian organizations so as to facilitate researcher access to data. Much of this work has been accomplished through the creation of a unified relational database that serves as the source of primary data required for the radiation effects research studies along with the development of easy-to-use tools for accessing these data in formats needed by researchers. Efforts included:
- The continued development of the data access tools with particular emphasis on implementing requested features based on user feedback;
- Incorporation of additional data that has been identified for inclusion into the unified database;
- Development of quality assurance and quality control procedures for data contained in the unified database; and
- Technical support and administration of the existing database.
Results to date: Prior to the development of the unified database, each of the four Russian laboratories involved in studies of the Mayak worker and offspring cohorts independently collected and organized their data in a manner unsuited for joint studies. This project has led to significant progress toward creating a unified, shared database in which each participating group contributes and takes responsibility for the maintenance and documentation for those data for which they have particular expertise.
Date Completed: September 2005.
Completed Direction 3 Emergency Response Activities Information
Direction 3: Information Technologies and Decision Making Support for Radiation Accidents and Health Effects from Radiation Exposure
For many years, Dr. Vince McClelland of DOE's Office of Nonproliferation and National Security led United States-Russian Joint efforts in Emergency Response.
Brief Description: The objective of Direction 3 was to identify further areas of collaborative research in the fields of accident consequence management and to facilitate joint exercises.
Date Completed: September 2014
FOR ADDITIONAL INFORMATION
Dr. Joey Zhou
(301) 903-3602