 |
|
Major Source of Radon Exposure Overlooked at Former Ohio Uranium Processing Plant
October 24, 2008CINCINNATI-University of Cincinnati (UC) scientists say that a recent scientific study of a now-closed uranium processing plant near Cincinnati has identified a second, potentially more significant source of radon exposure for former workers.
That source-six silos filled with uranium ore in the production area-resulted in relatively high levels of radon exposure to 12 percent of the workers. More than half (56 percent) of the workers were exposed to low levels of radon while working at the site.
"Our findings have scientific and political ramifications," explains Susan Pinney, PhD, corresponding author of the study and associate professor of environmental health at UC. "Now we know workers in the plant's production area prior to 1959 may be at increased risk for developing lung cancer and other exposure-related health problems."
Third-shift plant workers were most affected, during some years being exposed to three times more harmful radon gas than workers on other shifts, according to the UC study. Researchers say the elevated exposure was the result of decreased air movement and less dispersion of radon gas during the night.
Pinney and Richard Hornung, PhD, recently reported their findings in the September issue of the Journal of Exposure Science and Environmental Epidemiology. This is the first time on-site radon exposure at the plant has been quantified in workers.
A previous study identified two silos, known by the code name "K-65," as the only source of radon exposure. The silos were located on the west side of the U.S. Department of Energy Uranium Processing Plant in Fernald.
"Our original intention was to develop and validate radon exposure estimates for the K-65 silos," explains Hornung. "But when we studied radon tracks on film placed on window glass in the Fernald plant, we found evidence of a second, previously unidentified radon source."
UC researchers traced the radon to six silos, known by the code name "Q-11," centrally located near a major production area. The silos were originally used to store high grade uranium ore and later held byproducts from the ore chemical separation process known as raffinate.
"The initial site review conducted by the federal government overlooked the Q-11 silos as a source of radon emissions," says Hornung, a professor of environmental health at UC and director of the biostatistics and data core at Cincinnati Children's Hospital Medical Center. "This second source of radon dominates the total radon exposure from both sources during the period of 1952 to 1958 for workers near the Q-11 silos. Our study revealed that a small number of Fernald workers' cumulative radon exposures were in the range of underground uranium miners."
"When the plant was in operation, employees wore badges to measure gamma radiation exposure-but not alpha radiation sources like radon," he adds.
According to company records, 7,143 people worked at the uranium processing plant between 1952 and the plant's closing in 1989.
Uranium is a heavy metal that is essential for operation of electricity-producing nuclear reactors around the world. The metal can be removed from ore through a chemical separation process that leaves a soupy mixture of liquid and chemical byproducts known as "raffinate." That raffinate was stored in the K-65 silos.
"Uranium raffinate has high levels of radium and radon decay products," explains Pinney, "and for more than 30 years the K-65 silos emitted radon gas into the plant's atmosphere. The gas is odorless and colorless, so the workers never knew they were breathing it."
According to the National Academy of Sciences, radon is the second leading cause of lung cancer in the United States. The substance, which can be dispersed in the form of gas through air or water, genetically alters cells in the lung's lining and can greatly increase a person's risk for lung cancer.
Pinney's team conducted a four-year study, based on questionnaire information about actual work location and the time of work shifts, to determine how much radon workers from different areas of the plant were exposed to.
Fernald personnel records did not include work locations, so to accurately evaluate radon exposure levels the UC researchers developed a complex worker-location coding system to place employees at specific sites across the plant. They also used a specialized plastic film to measure radon exposure at the various plant locations. By studying the number of tracks left on the film by radon decay products, they found the second radon source.
"Radon gas disperses widely," explains Pinney, "and since the level of radon exposure is based on your proximity to a specific source, we had to know approximately where each worker stood or sat during their shift to figure out what level of radon they were being exposed to."
Pinney's team divided the 1,000-acre Fernald facility into numerous work locations within areas of the facility: the "production area," which included all production plants and outlying buildings; "controlled production areas" other non-production areas where workers were also required to undergo decontamination measures; and "uncontrolled areas," which included common destinations such as the cafeteria, administrative offices, laundry and laboratories. Employees were further differentiated into 41 categories based on what years and shifts they worked in the plant.
Using information from individual worker's job history files, the team was able to assign workers to locations across the plant, for each calendar year. Worker locations were verified using data from more than 2,100 detailed questionnaires completed by employees enrolled in the plant's medical monitoring program.
"Although we can't determine the exact number," says Hornung, "our research suggests that over 2,500 people may have been exposed to levels of radon gas that were higher than previously thought during their daily work, coming from a combination of the Q-11 silo and K-65 sources."
Researchers point out that the radon emitting materials in the K-65 and Q-11 silos were removed in the process of cleaning up the site, so there is no longer any source of radon gas related to the site.
This research was funded by the U.S. Public Health Service, the National Institute of Occupational Safety and Health and the National Institute of Environmental Health Sciences.
Study collaborators include David Brewer and James Nasuta. George Killough of Hendecagon Corp. and Jeffrey Lodwick, PhD, a former UC staff member who is now with the U.S. Department of Labor, also contributed to the study. Hornung has a dual affiliation with UC and Cincinnati Children's.
Several medical screening programs are available to former Fernald workers. They include:
* Fernald Worker Medical Monitoring Program, (513) 870-0900
* Building Trades National Medical Screening Program, www.btmed.org or (800) 866-9663.
* Worker Health Protection Program, www.worker-health.org or (513) 367-1333.
More information about radon is available at www.epa.gov/radon. Specific questions from workers should be directed to the Centers for Disease Control and Prevention by calling (800)-CDC-INFO.
University of Cincinnati
Third-shift plant workers were most affected, during some years being exposed to three times more harmful radon gas than workers on other shifts, according to the UC study. Researchers say the elevated exposure was the result of decreased air movement and less dispersion of radon gas during the night.
Pinney and Richard Hornung, PhD, recently reported their findings in the September issue of the Journal of Exposure Science and Environmental Epidemiology. This is the first time on-site radon exposure at the plant has been quantified in workers.
A previous study identified two silos, known by the code name "K-65," as the only source of radon exposure. The silos were located on the west side of the U.S. Department of Energy Uranium Processing Plant in Fernald.
"Our original intention was to develop and validate radon exposure estimates for the K-65 silos," explains Hornung. "But when we studied radon tracks on film placed on window glass in the Fernald plant, we found evidence of a second, previously unidentified radon source."
UC researchers traced the radon to six silos, known by the code name "Q-11," centrally located near a major production area. The silos were originally used to store high grade uranium ore and later held byproducts from the ore chemical separation process known as raffinate.
"The initial site review conducted by the federal government overlooked the Q-11 silos as a source of radon emissions," says Hornung, a professor of environmental health at UC and director of the biostatistics and data core at Cincinnati Children's Hospital Medical Center. "This second source of radon dominates the total radon exposure from both sources during the period of 1952 to 1958 for workers near the Q-11 silos. Our study revealed that a small number of Fernald workers' cumulative radon exposures were in the range of underground uranium miners."
"When the plant was in operation, employees wore badges to measure gamma radiation exposure-but not alpha radiation sources like radon," he adds.
According to company records, 7,143 people worked at the uranium processing plant between 1952 and the plant's closing in 1989.
Uranium is a heavy metal that is essential for operation of electricity-producing nuclear reactors around the world. The metal can be removed from ore through a chemical separation process that leaves a soupy mixture of liquid and chemical byproducts known as "raffinate." That raffinate was stored in the K-65 silos.
"Uranium raffinate has high levels of radium and radon decay products," explains Pinney, "and for more than 30 years the K-65 silos emitted radon gas into the plant's atmosphere. The gas is odorless and colorless, so the workers never knew they were breathing it."
According to the National Academy of Sciences, radon is the second leading cause of lung cancer in the United States. The substance, which can be dispersed in the form of gas through air or water, genetically alters cells in the lung's lining and can greatly increase a person's risk for lung cancer.
Pinney's team conducted a four-year study, based on questionnaire information about actual work location and the time of work shifts, to determine how much radon workers from different areas of the plant were exposed to.
Fernald personnel records did not include work locations, so to accurately evaluate radon exposure levels the UC researchers developed a complex worker-location coding system to place employees at specific sites across the plant. They also used a specialized plastic film to measure radon exposure at the various plant locations. By studying the number of tracks left on the film by radon decay products, they found the second radon source.
"Radon gas disperses widely," explains Pinney, "and since the level of radon exposure is based on your proximity to a specific source, we had to know approximately where each worker stood or sat during their shift to figure out what level of radon they were being exposed to."
Pinney's team divided the 1,000-acre Fernald facility into numerous work locations within areas of the facility: the "production area," which included all production plants and outlying buildings; "controlled production areas" other non-production areas where workers were also required to undergo decontamination measures; and "uncontrolled areas," which included common destinations such as the cafeteria, administrative offices, laundry and laboratories. Employees were further differentiated into 41 categories based on what years and shifts they worked in the plant.
Using information from individual worker's job history files, the team was able to assign workers to locations across the plant, for each calendar year. Worker locations were verified using data from more than 2,100 detailed questionnaires completed by employees enrolled in the plant's medical monitoring program.
"Although we can't determine the exact number," says Hornung, "our research suggests that over 2,500 people may have been exposed to levels of radon gas that were higher than previously thought during their daily work, coming from a combination of the Q-11 silo and K-65 sources."
Researchers point out that the radon emitting materials in the K-65 and Q-11 silos were removed in the process of cleaning up the site, so there is no longer any source of radon gas related to the site.
This research was funded by the U.S. Public Health Service, the National Institute of Occupational Safety and Health and the National Institute of Environmental Health Sciences.
Study collaborators include David Brewer and James Nasuta. George Killough of Hendecagon Corp. and Jeffrey Lodwick, PhD, a former UC staff member who is now with the U.S. Department of Labor, also contributed to the study. Hornung has a dual affiliation with UC and Cincinnati Children's.
Several medical screening programs are available to former Fernald workers. They include:
* Fernald Worker Medical Monitoring Program, (513) 870-0900
* Building Trades National Medical Screening Program, www.btmed.org or (800) 866-9663.
* Worker Health Protection Program, www.worker-health.org or (513) 367-1333.
More information about radon is available at www.epa.gov/radon. Specific questions from workers should be directed to the Centers for Disease Control and Prevention by calling (800)-CDC-INFO.
University of Cincinnati
Study in Spain and Romania confirms radon as second leading cause of lung cancer
Exposure to radon gas in homes is the second leading cause of lung cancer after smoking, according to a study carried out by researchers from the University of Cantabria and the Babes-Bolyai University in Romania.
Guide on lung cancer in 'never-smokers': A different disease and different treatments
A committee of scientists led by Johns Hopkins investigators has published a new guide to the biology, diagnosis and treatment of lung cancer in never-smokers, fortifying measures for what physicians have long known is a very different disease than in smokers.
Deaths from lung cancer could be reduced by better policies to control indoor radon
About 1100 people each year die in the UK from lung cancer related to indoor radon, but current government protection policies focus mainly on the small number of homes with high radon levels and neglect the 95% of radon related deaths caused by lower levels of radon, according to a study published on bmj.com today.
New Study Finds Exposure to Low Levels of Radon Appears to Reduce the Risk of Lung Cancer
Exposure to levels of radon gas typically found in 90 percent of American homes appears to reduce the risk of developing lung cancer by as much as 60 percent, according to a study published in the March issue of the journal Health Physics.
More Radon Exposure Current Events and Radon Exposure News Articles
 |
Health Effects of Exposure to Radon: BEIR VI (Beir, 6) by Committee on Health Risks of Exposure to Radon (BEIR VI) (Author), National Research Council (Author) Report of the Committee on Health Risks of Exposure to Radon. Discusses the risks of exposure to radon, a natural radioactive carcinogen. Considers research on radon and lung cancer. For policy makers and environmental advocates. |
|
High natural radiation exposure in radon spa areas: a detailed field investigation in Niska Banja (Balkan region) [An article from: Journal of Environmental Radioactivity] by Z.S. Zunic (Author), I. Kobal (Author), J. Vaupotic (Author), K. Kozak (Author), Mazur (Author) This digital document is a journal article from Journal of Environmental Radioactivity, published by Elsevier in 2006. The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser. Description: The measurement campaigns have been done in the rural community of Niska Banja, a spa town located in southern Serbia, to evaluate population exposure to natural radioactivity. After a screening survey in 200 houses, annual radon and thoron concentrations were measured in 34 houses, and in 2004 a detailed investigation was carried out at six houses with elevated indoor radon concentrations. The paper presents the results of these detailed measurements. The complementary techniques were applied... | |
|
Dosimetry Aspects of Exposure to Radon and Thoron Daughter Products by Organisation for Economic Co-Operation and Development (Author), Nuclear Energy Agency (Author) | |
 |
Radon exposure : human health threat: Hearing before the Subcommittee on Health and the Environment of the Committee on Energy and Commerce, House of Representatives, ... session on H.R. 2837 ... November 5, 1987 by United States. Congress. House. Committee on Energy and Commerce. Subcommittee on Health and the Environment (Author) This volume is produced from digital images created through the University of Michigan University Library's large-scale digitization efforts. The Library seeks to preserve the intellectual content of items in a manner that facilitates and promotes a variety of uses. The digital reformatting process results in an electronic version of the original text that can be both accessed online and used to create new print copies. The Library also understands and values the usefulness of print and makes reprints available to the public whenever possible. This book and hundreds of thousands of others can be found in the HathiTrust, an archive of the digitized collections of many great research libraries. For access to the University of Michigan Library's digital collections, please see... |
|
Radon Exposure of the U.S. Population-Status of the Problem (Ncrp Commentary) by National Council on Radiation Protection and Measurements (Author) | |
|
Evaluation of Occupational and Environmental Exposures to Radon and Radon Daughters in the United States (N C R P Report) by National Council on Radiation Protection and Measurements (Author) | |
|
Lung cancer attributable to indoor radon exposure in France: impact of the risk models and uncertainty analysis.(Research): An article from: Environmental Health Perspectives by Olivier Catelinois (Author), Agnes Rogel (Author), Dominique Laurier (Author), Solenne Billon (Author), Denis Hemon (Author), Pierre Verger (Author), Margot Tirmarche (Author) This digital document is an article from Environmental Health Perspectives, published by Thomson Gale on September 1, 2006. The length of the article is 7755 words. The page length shown above is based on a typical 300-word page. The article is delivered in HTML format and is available in your Amazon.com Digital Locker immediately after purchase. You can view it with any web browser. Citation Details Title: Lung cancer attributable to indoor radon exposure in France: impact of the risk models and uncertainty analysis.(Research) Author: Olivier Catelinois Publication: Environmental Health Perspectives (Magazine/Journal) Date: September 1, 2006 Publisher: Thomson Gale Volume: 114 Issue: 9 Page: 1361(6) Distributed by Thomson... | |
 |
Risk Assessment of Radon in Drinking Water (Compass Series) by Committee on Risk Assessment of Exposure to Radon in Drinking Water (Author), National Research Council (Author) Presents a valuable synthesis of information about the total inhalation and ingestion risks posed by radon in public drinking water, including comprehensive review of data on the transfer of radon from water to indoor air and outdoor levels of radon in the U.S. DLC: Drinking water--Contamination--U.S. |
|
Criteria for a Recommended Standard, Occupational Exposure to Radon Progeny in Underground Mines by United States Government Printing (Publisher) | |
|
Criteria for a Recommended Standard: Occupational Exposure to Radon Progeny in Underground Mines (Dhhs Publications Niosh No. 88-101) by United States Government Printing (Publisher) |
| © 2009 BrightSurf.com |