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Sealed Source Safety RetrainingUpdated 09/2012 Radiological & Environmental Management Purdue University
Training Goals • Basic Radiation Safety Principles • Familiarization with Regulations • Purdue’s Policies and Procedures
What is radioactivity? • Radioactivity is an energy • This energy is produced when an unstable nucleus spontaneously emits particles and/or electromagnetic radiation • Radioactive material sources • Sources are characterized as either sealed or unsealed (or “open”) • To qualify as a “sealed” source, the source must pass a battery of stress tests and be certified under NRC regulations
Definition Sealed Source Means any byproduct material that is encased in a capsule designed to prevent leakage or escape of the byproduct material (USNRC Regulations 10CFR30.4)
Ionizing Radiation Types • Alpha • Molecularly large particle (2 protons and 2 neutrons), give up their energy in a short distance (approximately 1 ½ inches in air) • Beta • Smaller particle (electron), distance traveled ranges from several inches to a few feet (depending on its energy) • Gamma • Non-particulate energy wave, can travel several feet and easily penetrates material with low atomic mass • Neutron • Neutral particle, can travel greater distances than gamma radiation and easily penetrate material with low hydrogen ion concentrations
Risks of Radiation Exposure • An average person in the United States receives annual radiation dose of ~620 mrem, which includes exposure received from cosmic and natural radiation, medical treatment, and consumer products. • Large doses of radiation have been known to increase risk of cancer, birth defects, and possibly genetic effects. • Low doses seem to show no statistical differences in biological risk; however, some people believe there is risk at all levels above background exposure. • At radiation levels around 1 rem, it has been estimated that the increased incidence of cancer is 0.03% - the normal incidence of cancer for the average person is 25%. • Risk of developing genetic effects is half the risk of cancer.
4 Factors to Reduce Exposure • Contamination Control • gloves, lab coats, fume hoods, absorbent paper • Time • do dry run, practice procedure to minimize time • Distance • a little distance between you and a source can significantly decrease your exposure from it (follows the “Inverse-Square Law”) • Shielding • Use proper shielding between you and a source to decrease personal exposure • betas - wood, Plexiglas (do NOT use lead) • gammas - lead, leaded glass
2 2 2 1 = I2 d I1d Inverse Square Law • Point Sources • The intensity of radiation decreases as the inverse square of the distance. • Doubling distance, exposure = ¼ of original; Tripling distance, exposure = 1/9 of original. Click here for a sample calculation
Sample Calculation I1 = 20 mR/hr I2 = ?? d1 = 1 ft d2 = 2 ft • (I1)(d1)2 = (I2)( d2)2 • (20 mR/hr)(1ft)2 = (I2)(2ft)2 • (20 mR/hr)(1ft)2 = I2 (2ft)2 • (20 mR/hr)(1ft2) = I2 (4ft2) I2 = 5 mR/hr
Ionizing Radiation Shielding • Different shields are needed to minimize external exposure
Rules Governing Use of Radionuclides • Radioactive material use must be licensed by the United States Nuclear Regulatory Commission (USNRC) or state agency. In Indiana, the USNRC is the regulating body. • Radiation Safety Officer (RSO) develops and maintains a Radiation Safety Manual, which must be followed by individuals working under the NRC license, and it is enforceable by law • Purdue University’s Radiation Safety Committee (RSC) also oversees and governs the radiation safety program.
Regulations • 10CFR19 • Rights and responsibilities of radioactive material licensees are outlined. • 10CFR20 • Standards for protection against radiation: this discusses issues such as procedures and regulatory limits • Declared pregnant worker • Security of radioactive materials
10CFR Part 19Instruction to workers • Rights • to be informed of storage, transfer, and use of radioactive materials • to further instruction on health protection problems associated with radiation exposure and procedures to minimize exposure • to receive radiation exposure history • to request an NRC inspection • to be instructed in and required to observe applicable provisions of NRC regulations and licenses • to be instructed in the appropriate response to warnings
NRC Policy Statement • Retaliation against employees or students engaged in protected activities, whether they have raised safety concerns within the University or to the NRC, will not be tolerated • Problems should be addressed within the existing University hierarchy – contact the radiation safety office if you have any concerns regarding issues involving radioactive materials.
10CFR20 • Occupational dose limits • Surveys and monitoring • Precautionary procedures • Waste disposal • Records of surveys • Enforcement • Storage and control of licensed material
10CFR20Occupational Dose Limits All dose limits include exposure from both internal and external sources.
Regulatory Guide 8.13Prenatal Exposure • If a worker wishes to declare her pregnancy, she must declare it in writing to the Radiation Safety Officer. • A declaration of pregnancy is entirely voluntary, and can be withdrawn at any time – no reason needs to be given. • For a worker wishing to declare her pregnancy, she should contact REM for Declared Pregnant Worker Training, which covers important information, and provides her the declaration form she needs in order to declare her pregnancy. REM will also provide a fetal dosimeter at the time of declaration, assuming that it is warranted by the type of radiation that has the potential for exposure to the worker. • The dose limits will be reduced from 5 rem per year to the worker, to 0.5 rem to the fetus for the 9-month gestation period (this is for both external and internal exposure)
Radiation Units • Exposure= ability of photons to ionize air • Roentgen (milliroentgen, mR) • Geiger-Mueller readings • Absorbed Dose= energy deposited in matter • Rad (millirad, mrad) • Dose Equivalent= biological weighted absorbed dose (tissue) • rem (millirem, mrem) • these units are what film badge (dosimetry) results are reported
Acute Effects of Radiation Exposure • Non-stochastic: • Until a minimum exposure level is reached, there is no biological effect. • Once that minimum exposure level is exceeded, the biological effect grows proportionally with the exposure. • The Lethal Dose to 50% of the population (LD50) is about 600 rad • Examples of biological response (effects) from radiation • erythema (skin reddening) • blood changes (marrow depression is seen at approximately 200 rad) • Gastrointestinal Syndrome (severe vomiting, diarrhea) – happens at approximately 1000 rad, and death is a likely outcome.
Delayed Effects of Radiation Exposure • Stochastic (occur by chance, statistical basis) • No threshold, but as the dose increases, the probability of the effect also increases • Examples of stochastic effects: may be seen 5 to 20 years after the exposure • Cancer • Leukemia • Cataracts • Life Shortening • Data extrapolated from high dose data (early radiology, Hiroshima/Nagasaki bombing, Chernobyl nuclear plant fire)
Risk Analysis • High doses - there is a correlation between dose and effect • Low doses (<10 rem) - it is unclear what the risk is at this level • difficulty performing long-term studies on effected people, while eliminating other factors (e.g. did the radiation worker get cancer from her work, or that she smoked cigarettes, or that she was genetically programmed that way) • Hormesis – this is a theory that low doses of radiation may actually be beneficial
Surveys • You can use Geiger-Mueller Survey instrument for detection of higher-energy beta and gamma sources. • REM will be conducting “leak tests” on sealed sources to evaluate whether the source containment is intact • this will be done at timely intervals. • Survey work areas, floors around work areas and any doors, lab coat, hands, shoes, if it is felt that the source integrity has been compromised (e.g. dropped, smashed, had acid spilled on it) • Record survey results, maintain records for 3 years
SecurityNRC Area of Emphasis • Secure laboratories when unoccupied (if this is not feasible, secure the radioactive material) • Challenge visitors or unauthorized individuals • REM accounts for RAM through inventory records • Assume only you are approved for the type of materials you are using. If another group wants to borrow them, you must ALWAYS check with the radiation safety office before relinquishing control of the material.
Emergency Procedures • Call 911 • Assist personnel if injured • Monitor personnel if contamination is suspected • Control area - inform other personnel of the situation and advise them not to enter • Notify radiation safety office, once emergency personnel are en route
Severe Personal Injury • Medical needs come first! Postpone monitoring, call 911, notify of radioactive material use • Wait for medical personnel - calmly advise radioactive materials may be involved • Trained radiation worker may need to accompany patient to treatment center. • Notify REM
Review • Always use ALARA • No eating, drinking, or smoking in labs • Always secure materials, lock doors • Never allow unauthorized users access to radioactive materials • Call REM for any related questions (49-46371) • All Emergencies – call 911
REM’s Radiation Safety Group • James F. Schweitzer, Ph.D. 49-42350 Radiation Safety Officer jfschweitzer@purdue.edu • Zachariah C. Tribbett49-41478 Health Physicistztribbet@purdue.edu • Sharon K. Rudolph 49-47969 Isotope Ordering & Distribution skrudolph@purdue.edu • Jerry J. Gibbs 49-40207 Waste Handling & Meter Calibration jjgibbs@purdue.edu • Mike Nicholson 49-40205 Waste Handling & Animal Hospital Support mlnicholson@purdue.edu • REM Main Office 49-46371 Civil Engineering Building, Room B173 www.purdue.edu/rem
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