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2014 Radiation Safety Manual Integrated Risk Management To ensure that all information is the most up-to-date, no forms or SOPs are included in this manual but rather a link to their location on the IRM website is provided from which they can be directly filled-out and/or downloaded RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 2 of 50 Integrated Risk Management TABLE OF CONTENTS TABLE OF CONTENTS .......................................................................................................................................................... 3 LIST OF TABLES ................................................................................................................................................................... 6 LIST OF FIGURES ................................................................................................................................................................. 6 1. 2. ADMINISTRATION AND RESPONSIBILITY ......................................................................................................................... 7 1.1. Scope ............................................................................................................................................................ 7 1.2. Authority and Responsibility...................................................................................................................... 7 1.3. Legislation and Guidance Documents .................................................................................................. 7 1.4. Stakeholder feedback mechanisms ...................................................................................................... 8 1.5. Radiation Safety Officer .......................................................................................................................... 10 1.6. Department Chairs ................................................................................................................................... 10 1.7. Permit Holders............................................................................................................................................ 10 1.8. Individuals Working with Radionuclides ............................................................................................... 11 SETTING UP A LABORATORY FOR UNSEALED RADIOACTIVE MATERIALS ......................................................................... 12 2.1. Top 5 Requirements.................................................................................................................................. 12 2.2. Approval and Design of Radionuclide Laboratory Locations ......................................................... 12 2.3. Ryerson Radiation Permit Requirements .............................................................................................. 13 2.3.1 Projects involving more than 10000 Exemption Quantities of a radionuclide ............................. 14 2.4. 2.4.1. Personal Dosimetry ........................................................................................................................... 14 2.4.2. Permissible Doses .............................................................................................................................. 15 2.4.3. Internal Contamination – Bioassay Requirements ..................................................................... 16 2.5. Selection of Radiation Detection Equipment ..................................................................................... 16 2.5.1. Dose Rate Monitoring (External Radiation Levels) ..................................................................... 16 2.5.2. Contamination Monitoring (Amount of Radioactive Material) .............................................. 17 2.6. 3. Occupational Exposure Monitoring ...................................................................................................... 14 Training Requirements ............................................................................................................................. 17 STANDARD OPERATING PROCEDURES FOR LABORATORY WORK ................................................................................. 18 3.1. ALARA ......................................................................................................................................................... 18 3.2. Personal Protective Equipment.............................................................................................................. 18 3.2.1. Laboratory Coats ............................................................................................................................. 18 3.2.2. Gloves ................................................................................................................................................. 18 3.2.3. Safety Glasses/Goggles or Face Shields ...................................................................................... 19 RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 3 of 50 Integrated Risk Management 3.2.4. Footwear ............................................................................................................................................ 19 3.3. General Requirements for Work Area Safety ...................................................................................... 19 3.4. Exposure Monitoring ................................................................................................................................. 20 3.4.1. Action Levels ..................................................................................................................................... 20 3.4.2. Bioassay Requirements.................................................................................................................... 21 3.5. Posting of Required Laboratory Signs ................................................................................................... 22 3.6. Purchasing Radioactive Materials ........................................................................................................ 25 3.6.1. 3.7. Procedures for Ordering Radioactive Materials ........................................................................ 25 Transfer of Radioactive Materials .......................................................................................................... 26 3.7.1. Transfers within the University ......................................................................................................... 26 3.7.2. Transfers from Outside Institutions.................................................................................................. 26 3.8. Receipt of Radioactive Packages ........................................................................................................ 26 3.9. Inventory Control ...................................................................................................................................... 27 3.10. Storage ....................................................................................................................................................... 27 3.11. Waste Disposal .......................................................................................................................................... 28 3.11.1. General .............................................................................................................................................. 28 3.11.2. Specific Radioactive Waste Streams ........................................................................................... 28 3.11.3. Aqueous Washes .............................................................................................................................. 29 3.12. Radiation Detection Equipment ............................................................................................................ 30 3.12.1. Choice of Instrument ....................................................................................................................... 30 3.12.2. Efficiency............................................................................................................................................ 31 3.12.3. Annual Calibration ........................................................................................................................... 31 3.12.4. Registration ........................................................................................................................................ 31 3.12.5. Maintenance .................................................................................................................................... 31 3.13. Radiation Surveys for External Radiation and Contamination ........................................................ 31 3.13.1. Dose Rate Surveys ............................................................................................................................ 31 3.13.2. Detection of Surface Contamination .......................................................................................... 32 3.14. Record Keeping Requirements.............................................................................................................. 36 3.14.1. Inventory Records ............................................................................................................................ 36 3.14.2. Contamination Monitoring ............................................................................................................. 36 3.14.3. Waste Records .................................................................................................................................. 36 3.14.4. Training Records ............................................................................................................................... 36 RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 4 of 50 Integrated Risk Management 3.14.5. Inspection Records .......................................................................................................................... 37 3.14.6. Sealed Source records .................................................................................................................... 37 3.14.7. Calibration Records ......................................................................................................................... 37 3.15. Work Practices for Specific Radionuclides .......................................................................................... 37 3.15.1. Low Energy Beta Emitters ................................................................................................................ 37 3.15.2. High Energy Beta Emitters ............................................................................................................... 38 3.15.3. Gamma Emitters............................................................................................................................... 38 3.16. Sealed Sources.......................................................................................................................................... 39 3.16.1. Leak testing for sealed sources of 50 MBq (1.35 mCi) or more .................................................... 39 3.17. Decommissioning Rooms ........................................................................................................................ 40 3.18. Ryerson Radiation Permit Revisions ....................................................................................................... 41 3.18.1. Amendments .................................................................................................................................... 41 3.18.2. Renewals ............................................................................................................................................ 41 3.18.3. Sabbatical/Extended Leave.......................................................................................................... 41 3.18.4. Inactive Status................................................................................................................................... 42 3.18.5. Suspension/Revocation .................................................................................................................. 42 3.18.6. Expiry/Termination ............................................................................................................................ 42 3.19. 4. Self-Audit Checklist – Top 10 Things to Remember ............................................................................ 42 SECURITY ................................................................................................................................................................. 43 4.1. Authorized Access .................................................................................................................................... 43 4.2. Maintaining Security................................................................................................................................. 43 4.3. Bringing Radioactive materials on Campus ....................................................................................... 43 4.4. Missing Radioactive materials ................................................................................................................ 43 5. EMERGENCY PROCEDURES ....................................................................................................................................... 43 6. REFERENCES ............................................................................................................................................................ 46 6.1. Regulatory Agencies ............................................................................................................................... 46 6.2. Professional Radiation Safety Associations .......................................................................................... 47 APPENDIX A ................................................................................................................................................................ 48 RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 5 of 50 Integrated Risk Management LIST OF TABLES Table 1. Classification of Basic and Intermediate Rooms for Various Isotopes ............................................. 13 Table 2. Radiation Exposure - Annual Limits ......................................................................................................... 15 Table 3. Action Levels for Individual Doses ........................................................................................................... 21 Table 4. Action Levels for Bioassay Monitoring .................................................................................................... 22 Table 5. Requirements for Laboratory Signs ......................................................................................................... 24 Table 6. Exemption quantities for selected radionuclides ................................................................................ 25 Table 7. Radioactive Waste Disposal Criteria for Individual Radioisotopes ................................................... 30 Table 8. Action Levels for Removable Surface Contamination in Controlled Areas for Selected Radioactive materials .............................................................................................................................................. 32 Table 9. Decontamination Methods for Removable Surface Contamination ............................................. 35 Table 10. Classification of Selected Radioactive materials for Removable Surface Contamination Levels in Decommissioned or Public Areas .......................................................................................................... 40 Table 11. Classification of Minor Spills for Selected Radionuclides.................................................................. 44 Table 12. Procedures for Decontamination of Contaminated Personnel ..................................................... 45 LIST OF FIGURES Figure 1. Organization/Reporting Structure at Ryerson University ..................................................................... 9 Figure 2. Thermoluminescent dosimeter showing internal lithium fluoride chip ............................................ 14 Figure 3. Radioactive Warning Sign ....................................................................................................................... 24 RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 6 of 50 Integrated Risk Management 1. ADMINISTRATION AND RESPONSIBILITY 1.1. Scope These procedures form part of the Radiation Safety Program and apply to all faculty, staff and students using, receiving, possessing, working and disposing open radioactive sources in all areas and facilities controlled by Ryerson University. The Canadian Nuclear Safety Commission issues Ryerson University a Consolidated Licence for all its radioactive materials. The license allows Ryerson University to possess, store and use specified radioactive materials. The Radiation Safety Program outlines the regulatory requirements in observance with this license and associated legislation. 1.2. Authority and Responsibility The University shall establish a Radiation Safety Program for ionizing radiation producing open sources in accordance with Canada’s Nuclear Safety and Control Act and applicable regulations and regulatory documents, administered by the Canadian Nuclear Safety Commission. All occupational exposures to ionizing radiation shall be limited in accordance with the ALARA principle (As Low As Reasonably Achievable) and within legislated prescribed dose limits. Ryerson University’s Radiation Safety Program is designed to keep exposures ALARA through training and implementation of standard operating procedures and protocols to control the storage, handling and disposal of radioactive materials. Responsibility for controlling all activities related to ionizing radiation safety at Ryerson University rests with the offices of the Provost and Vice President Administration and Finance. Their authority in this regard is received from the President of Ryerson University. Details of the enforcement policy are outlined in Appendix A. 1.3. Legislation and Guidance Documents All radioactive materials are regulated under the jurisdiction of various acts and regulations under the Canadian Nuclear Safety Commission (CNSC), including the Nuclear Safety Control Act, almost 75 regulations and guidance documents, and a Consolidated Licence issued by the CNSC to the University. The Consolidated Licence allows Ryerson University to purchase, possess, use, store and dispose of radioactive materials, provided all the conditions of the Licence are followed. This type of licence allows the University flexibility for managing its own radiation protection program. However, because it is a single licence, all actions impact on the licence's viability. In other words, if a serious event in one location were to occur, this single licence may be jeopardized which would affect work throughout the entire University. Copies of all relevant CNSC Acts, regulations, and guidance documents are available via the Radiation Safety Officer or through the department's website (www.ryerson.ca/irm) under the Radiation Safety Program. RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 7 of 50 Integrated Risk Management 1.4. Stakeholder feedback mechanisms In order to receive advice and direction on radiation safety matters, all stakeholders (permit holders, technical staff, and other parties involved such as Faculty, Deans/Directors implicated or specialized in radiation-related fields) are encouraged to provide feedback to the RSO who will collect and report back to the VP Administration and Finance and Provost. Every year, a report will go out to all permit holders, the VP Administration & Finance, and Provost. This reports is prepared by the RSO and will include the following statistics: • • • • • • • Number of new permits Number of permit renewals/updates Number of individuals trained Inspection results List of licence amendments (if any) Updates to CNSC act or regulations List of stakeholders' comments/advice/requests and follow-up The current organizational structure for radiation safety at Ryerson University is shown in Figure 1 below. RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 8 of 50 Integrated Risk Management Figure 1. Organization/Reporting Structure at Ryerson University President Vice President Administration & Finance Provost Vice President Research & Innovation Director Integrated Risk Management Deans Assistant Director Risk Management & Prevention Chairs & Academic Directors Radiation Safety Officer Permit Holders Users RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 9 of 50 Integrated Risk Management 1.5. Radiation Safety Officer The position of Radiation Safety Officer receives its authority from the Vice President, Administration & Finance, through the Director, Integrated Risk Management and the Associate Director, Risk Management & Prevention of Ryerson University. The Radiation Safety Officer is responsible for coordinating all activities related to radiation safety, and for making recommendations to the Vice Presidents, through the Assistant Director, Risk Management & Prevention, regarding the control of all activities related to radiation safety. The Radiation Safety Officer is responsible for coordinating the daily activities of the Radiation Safety Program. Annual reports to the Canadian Nuclear Safety Commission will be prepared and submitted on behalf of the University by the Radiation Safety Officer. The RSO also has the duty to report, upon having been made aware of , any incident or situation defined in Section 29 of the General Nuclear Safety and Control Regulations and file a full report of the situation within 21 days, unless some other period is specified in the licence, and this report shall contain the following information: • • • • • • the date, time and location of becoming aware of the situation; a description of the situation and the circumstances; the probable cause of the situation; the effects on the environment, the health and safety of persons and the maintenance of security that have resulted or may result from the situation; the effective dose and equivalent dose of radiation received by any person as a result of the situation; and the actions that have been taken or proposed to be taken with respect to the situation. 1.6. Department Chairs For areas using radioactive material(s), each departmental chair is responsible for providing adequate facilities, equipment, instruments, supervision to control radiation hazards and to comply with the University’s radiation protection requirements. And ensure that faculty, staff and students receive proper training. 1.7. Permit Holders Each individual who directs and supervises the use of unsealed radioactive materials is responsible for complying with the requirements outlined in the Canadian Nuclear Safety Commission, licences issued to the University, as well as with any additional requirements prescribed by internal procedures contained in the Radiation Safety Program. This individual will required to obtain an internal permit for the use of unsealed radioactive materials and will be deemed to be a Permit Holder. NOTE : Strict adherence to the conditions of approval for each and every internal permit is critical. Failure to comply will not only result in cancellation of individual permits but will seriously jeopardize the continuance of the University’s Consolidated Licence. Each Permit Holder is responsible for: a) Following the conditions as stated in the permit and that safe laboratory practices as stated in the standard operating procedures as prescribed by the Radiation Safety Program. RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 10 of 50 Integrated Risk Management b) Ensuring all staff using radioactive materials have been trained regarding the policies, procedures and programs on the safe use of radioactive materials at Ryerson University and are authorized to use radioactive materials. c) Ensuring that students using radioactive materials are properly supervised and ensuring they receive instruction in the safety procedures and University protocols on the safe handling of radioactive materials. d) Ensuring that all staff, students and researchers participate in required radiation safety training. e) Ensuring that designating work and storage areas for radioactive materials are maintained in proper working order, kept clean, properly labelled, are adequately shielded and that existing ventilation is not impaired. f) Ensuring that all staff working with radioactive materials have been issued, and wear a thermoluminescent dosimeter and participate in the bioassay program, as required. g) Ensuring that any radiation monitoring equipment used by the laboratory staff is adequate to the task and functioning properly. h) Allowing only authorized persons to enter rooms that are specified as restricted areas for reason of ionizing radiation protection. i) Maintaining an up to date inventory of all radiation sources (isolated sources or sources incorporated into equipment). This is to include a listing of the rooms in which radioactive materials are located or used. http://www.ryerson.ca/irm/forms/index.html provides a standard inventory form (different form for Sealed Vs Unsealed sources). j) Reporting to the Radiation Safety Officer any incidents involving abnormal activities such as loss of materials, suspected exposures to ionizing radiation exceeding permissible standards. k) Ensuring that all radioactive materials are properly stored. l) Coordinating all purchases, acquisitions, transfers and disposal of radioactive materials, sealed sources and devices containing such sources with the Radiation Safety Officer, prior to any arrivals or movement off campus. m) Notifying the Radiation Safety Officer whenever the permit holder will be unavailable to supervise, identifying another permit holder who has accepted the responsibility as the temporary supervisor. 1.8. Individuals Working with Radionuclides All persons working with unsealed radioactive materials have certain responsibilities. These are: a) Working in compliance with all policies, procedures and requirements at the University using protective and/or monitoring equipment required for the safe use of radioactive materials. b) Reporting to the Permit Holder any defective equipment, violation or situation that may endanger a worker or create an unauthorized release of radioactive materials to the environment. c) Not creating or participating in any activity which may endanger themselves, any other worker or create the potential for unauthorized release of radioactive materials to the environment. RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 11 of 50 Integrated Risk Management 2. SETTING UP A LABORATORY FOR UNSEALED RADIOACTIVE MATERIALS 2.1. Top 5 Requirements Before any work is performed with unsealed radioactive materials, advance preparation is required to set up equipment, and implement regulatory and administration protocols. Here are the top five items that are required to be completed before the first isotope is purchased: 1. LAB DESIGN a) Approval of radioisotope laboratory design and classification of containment level 2. RADIATION PERMIT a) Submitting an application and receiving approval for a Ryerson Radiation Permit 3. EXPOSURE MONITORING a) Depending on the activity and type of isotope(s) used, occupational exposure monitoring for all lab personnel that will be working with radioisotopes may be required: i. For high energy beta emitters (e.g.P-32) and gamma emitters (e.g. Cr-51, I-125, I-131) an application for TLD badge must be submitted and a badge assigned and received from the Radiation Safety Officer ii. Where applicable, bioassays for radioiodines or low energy beta emitters such as H-3 may be required. 4. EQUIPMENT a) Radiation detection equipment is required to monitor surface contamination and in some cases external dose rate. 5. TRAINING a) Laboratory staff, from principal investigator to summer student, will not be allowed to use unsealed radioactive materials or order materials without appropriate training. Training will be mandatory prior to the issuing of any TLD badge. Training requirements may vary – consult Radiation Safety Officer. b) Below is a more comprehensive explanation for each topic that expands on the requirements. 2.2. Approval and Design of Radionuclide Laboratory Locations All areas including laboratories, storage areas, counting rooms, etc, where the use of radioactive materials is proposed must be approved by the Radiation Safety Officer prior to radioactive materials being used or stored. All rooms intended to be used for the handling, storage or disposal of a radioactive material must conform to the requirements of Canadian Nuclear Safety Commission (CNSC) Regulatory Guide R52 (Rev 1) Design Guide for Basic and Intermediate Level Radioisotope Laboratories, or updated regulation : http://nuclearsafety.gc.ca/eng/acts-and-regulations/regulatory-documents/index.cfm If a laboratory has not been previously approved, it will require an inspection by the Radiation Safety Officer before any use of radioactive materials is permitted in the laboratory. The Canadian Nuclear Safety Commission (CNSC) regulates the classification of rooms, based on the amounts of activity (and by isotope) in each room. A radioisotope laboratory is classified as Basic Level, Intermediate Level, High Level, or Containment Level. RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 12 of 50 Integrated Risk Management Laboratory classification is based on the radioactive material to be handled in the laboratory. For Basic Level Rooms, the Radiation Safety Officer will authorize the area and designate the room. For proposed work in laboratories with activities greater than listed for a Basic-Level Room, the University requires written approval from the CNSC for every higher containment areas (i.e. Intermediate-Level Rooms or greater levels of containment). Table 1 outlines the classification of basic and intermediate rooms for a few of the most common radioisotopes. Table 1. Classification of Basic and Intermediate Rooms for Various Isotopes Isotope Exemption Quantity (MBq) a ALI (MBq) b Basic Level Intermediate Level (≤ 5 ALI per container) (>5 & ≤ 50 ALI) MBq b MBq mCi mCi C-14 10 34 170 4.6 1700 46 Cr-51 10 530 2650 71.6 26,500 716 1000 1000 5000 135.1 50,000 1351 I-125 1 1.3 6.5 0.2 65 2 P-32 0.1 6.9 34.5 0.9 345 9 P-33 100 15 75 2.0 750 20 S-35 100 26 130 3.5 1300 35 H-3 Source link: the nuclear substances and radiation devices licence application guide Notes: a) ALI ( Annual Limit on Intake) means the quantity, in Becquerels of a radionuclide which, when taken into the body, will deliver an effective dose of 20 mSv over the 50 years following its intake. Only the most restrictive ALI is listed here (either Inhalation or Ingestion) b) 37 MBq = 1 mCi If multiple radioisotopes are proposed to be used in the same location, then the proposed laboratory would be classified according to the most restrictive quantity. For example, if a researcher intends to use 150 MBq of Sulphur-35, 37 MBq of Tritium and 37 MBq of Carbon-14, the radioisotope laboratory would be required to be classified as an intermediate level laboratory due to the quantity of Sulphur35 present and will require written approval from the CNSC. No permit can be issued until this approval has been received. Depending on designation of the Level of Classification, CNSC lab posters will be required to be posted as well. These are available through the RSO, who must assign the lab classification based on the permit application/update information provided by the permit holder. 2.3.Ryerson Radiation Permit Requirements A Ryerson Radiation Permit issued by the University is required for any purchase, possession and use of radioactive material. A prospective user of open sources of radioisotopes must obtain an internal radioisotope permit before any radioactive material is brought onto the campus. This applies to all acquisitions of radioactive material, whether purchased, transferred, or donated. Apply on-line for a RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 13 of 50 Integrated Risk Management permit at: https://ccs.cf.ryerson.ca/cehsm/portalv2/ or contact the Radiation Safety Officer if the system is not available for any reason. Applications for an internal RU Radiation Permit are reviewed and approved by the Radiation Safety Officer on behalf of the University. Permits are normally only issued to professorial or other approved staff having documented training and at least two years of experience in the use of radioisotopes. The term of the permit is at the discretion of the University, but cannot exceed the term of the CSNC issued Consolidated Licence. A copy of the most recent permit must be posted by the permit holder in each location listed on the permit. Radioactive material may not be used, stored, or disposed in a location not listed on the permit. Once a permit has been issued, there may be no changes to the facilities used, isotopes and quantities allowed without prior approval from the University. An internal permit does not normally cover off-campus use of radioactive materials. A special and separate approval will be required from the University. 2.3.1 Projects involving more than 10000 Exemption Quantities of a radionuclide In addition, written approval will be required from the Canadian Nuclear Safety Commission for any single use with more than 10,000 exemption quantities (EQ) of any radionuclide. In these cases, the actual research protocol must be approved by the CNSC. Refer to Table 1 for a listing of exemption quantities for common radionuclides. For radionuclides not listed in Table 1, please contact the Radiation Safety Officer. 2.4. Occupational Exposure Monitoring 2.4.1. Personal Dosimetry Exposure monitoring with personal dosimeters monitors an individual’s exposure history by recording the cumulative dose received from occupational exposure to high energy radiation sources. TLDs have a lithium fluoride chip which records the exposure to ionizing radiation. The badges are worn at chest or waist levels to record whole body exposure. Information obtained from exposure reports is useful to evaluate the effectiveness of protective measures and to prevent over-exposure. When working with a gamma or high energy beta emitter, a thermoluminescent dosimeter (TLD) badge is required to be worn. Depending on the proposed isotope and activity, a ring dosimeter may also be required to monitor extremity exposures. For example, P-32 users working with activities greater than 37 MBq, will be required to wear a ring dosimeter. Figure 2. Thermoluminescent dosimeter showing internal lithium fluoride chip All dosimetry is coordinated through the Radiation Safety Officer. The Radiation Safety Officer will determine the extent of dosimetry required. In order to receive a personal dosimeter, an application RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 14 of 50 Integrated Risk Management form must be submitted to the Radiation Safety Officer for every individual planning to work with radioactive materials, prior to any work commencing. All information is considered confidential but is required to register new individuals with the National Dosimetry Services (NDS) in the Radiation Protection Branch of Health Canada. Badges are issued and processed by the National Dosimetry Services (NDS) where the records of exposure are maintained by the NDS. New badges to individuals are assigned and issued by the Radiation Safety Officer. A blank application form is available at http://www.ryerson.ca/irm/forms/index.html. All monitoring results are maintained and evaluated by the Radiation Safety Officer. Refer to Section 3.4 and http://www.ryerson.ca/irm/programs_policies/radiation.html under Standard Operating Procedures for the proper use and storage of TLD badges. TLDs are insensitive to weak beta emitters such as Tritium (H-3), Sulphur 35 (S-35) and Carbon 14 (C-14), and therefore TLD badges are ineffective. Refer to Section 2.4.3 for monitoring for these isotopes. 2.4.2. Permissible Doses 2.4.2.1. General Public The exposure from sources of ionizing radiation shall normally be controlled in such a way as to provide assurance that no individual or user shall receive an absorbed dose in excess of the values outlined by the CNSC and listed in Table 2. Table 2. Radiation Exposure - Annual Limits Member of the Public/ Non-NEW Whole Body Nuclear Energy Worker (NEW) Annual (mSv) Pregnant (mSv) Annual (mSv) Pregnant (mSv) 1 1 20 20 4 over 9 months Extremities 50 50 500 500 Lens of the Eye 15 15 150 150 Skin 50 50 500 500 (hands & feet) Source: http://laws-lois.justice.gc.ca/eng/regulations/SOR-2000-203/ 2.4.2.2. Nuclear Energy Workers a) Under the Nuclear Safety and Control Act, a “Nuclear Energy Worker” (NEW) means any person who in the course of his work, business or occupation, is likely to receive a dose of ionizing radiation in excess of the annual dose to the general public specified in Table 2. Each person who, in the opinion of the Radiation Safety Officer, may be exposed to external or internal radiation from sources (except prescribed medical treatment) in excess of the limits for a member of the public as listed in Table 2, will be classified as a Nuclear Energy Worker. Those individuals classified as a NEW will be required to sign an acknowledgement of their classification. RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 15 of 50 Integrated Risk Management b) Any pregnant worker designated as a Nuclear Energy Worker must inform the Radiation Safety Officer, in writing, as soon as she is aware of her condition. The dose rate to a pregnant NEW may not exceed 0.25 mSv over 2 weeks to a maximum of 4 mSv for the period of her pregnancy. 2.4.3. Internal Contamination – Bioassay Requirements Thermoluminescent dosimeters do not monitor exposure to low energy beta emission isotopes (e.g. H3, C-14). Workers using such isotopes may be required to participate in the bioassay program and submit biological samples for monitoring of radioisotopes. In addition, handling radioiodines such as Iodine 131 (I-131) and Iodine 125 (I-125) may require additional biological monitoring. Biological monitoring uses bioassay techniques to determine the amount of a particular radioisotope in the body. Two methods can be used for carrying out a bioassay technique - in vitro and in vivo. In vitro techniques are used when a small sample of a body fluid or tissue is sampled and analyzed in a detector. This is the technique used when urine is monitored for assessing tritium uptake. In vivo techniques involve measuring the amount of radioactive material by placing detectors close to the surface of the body. This technique is used for assessing the uptake of radioiodine in the thyroid. Refer to Section 3.4 for action limits for bioassay requirements. The Ryerson Radiation Permit will stipulate the conditions under which a bioassay is required. The frequency of the bioassay monitoring is dictated by the activity of the radioisotope. It is the responsibility of the Permit Holder to ensure that bioassay monitoring is carried out when required by the conditions outlined in the Ryerson Radiation Permit. Contact the Radiation Safety Officer to arrange for a bioassay measurement. 2.5. Selection of Radiation Detection Equipment Appropriate radiation detection equipment must be obtained by the Permit Holder and made available to laboratory staff working with radioactive materials. Depending on the isotope and activity proposed to be used in laboratory work, Permit Holders may be required to carry out two different radiation surveys for: 1. External radiation levels 2. Surface contamination The ability of various radiation detection instruments to detect radionuclides of interest will vary with the instrument and manufacturer. Instrument sensitivity for direct reading portable instruments must be capable of making reproducible measurements at the criteria limits. The Radiation Safety Officer shall be contacted for guidance on the selection of instruments. 2.5.1. Dose Rate Monitoring (External Radiation Levels) It is a requirement for researchers working with high energy beta emitters such as Phosphorus-32 (P-32) and gamma emitters such as Chromium-51, Iodine-125, etc, to be able to determine dose rates. Survey meters will be required to survey incoming packages and monitor radiation levels around the work space, storage and disposal areas for such isotopes. Detectors with ion chambers are very RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 16 of 50 Integrated Risk Management efficient. Geiger Mueller (GM) counters can also be used. A GM counter can measure radiation at lower radiation levels and is less expensive than a survey meter with an ion chamber detector. It is a requirement of the CNSC to have dose rate survey meters calibrated annually. Contact the Radiation Safety Officer to make arrangements. 2.5.2. Contamination Monitoring (Amount of Radioactive Material) Monitoring for surface contamination from unsealed radioactive materials will be required by all Open Source Permit Holders. Radioactive contamination may be measured directly or indirectly. Direct measurements use portable radiation detection instruments to detect both fixed and removable surface contamination. Direct measurement may be used when background radiation levels are negligible and the detector has sufficient sensitivity. To monitor large areas, it is more convenient to use a direct reading instrument, if it is suitable for the isotope being surveyed (ask the RSO). Indirect measurement of contamination is used when portable instruments are not sensitive enough or when the radiation background is too high. Indirect methods can only be used to monitor removable contamination. The higher efficiency, low background and multiple sample counting makes them ideal for contamination survey work. The most effective means of monitoring for surface contamination is through the use of swipes and liquid scintillation counting. Swipe tests only detect removable contamination. Low energy beta emitters (e.g. H-3, C-14 and S-35) have a very low efficiency for portable survey meters, and are best detected through the scintillation counting method. All radioisotope laboratories, except those exclusively using tritium (H-3), will have available a functioning portable instrument for contamination. Most laboratories will use a meter with a pancaketype Geiger-Muller (GM) probe. These detectors are useful for detecting the spread of contamination but Geiger counters have poor detection efficiency for gamma emitters, weak beta emitters, and cannot detect tritium. For high energy gamma emitters, a thick (2 or 3 mm) sodium iodide detector is best and for low-energy gamma emitters such as I-125, a detector with a thin (1 or 2 mm) sodium iodide scintillation crystal must be used. For low energy beta emitters like C-14 and tritium, only indirect methods can be used, such as liquid scintillation counting. Liquid scintillation counting is also good for all radionuclides. Discuss with the RSO to find the best method of detection for your particular needs. 2.6. Training Requirements The CNSC requires that all persons working with radioactive material obtain training in the safe handling of radioactive material prior to beginning work with the radioactive material. This training must include information on the risks associated with exposure to ionizing radiation, the safe use, handling, storage and disposal of radioactive material. It is the responsibility of the permit holder to ensure that all personnel working with radioactive materials under the permit holder’s permit receive the appropriate training and know the proper policies and procedures for the use of radioactive materials before beginning work. Permit Holders are responsible to supervise and document the hands-on laboratory training involving experimental procedures, techniques and equipment used in working with radioactive materials. RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 17 of 50 Integrated Risk Management The Radiation Safety Officer may exempt a person from the requirement to complete the Radiation Safety Course offered by Integrated Risk Management if the individual can provide proof of successful completion of an equivalent course at another institution or facility. However, all persons must be familiar with the policies and procedures in force at Ryerson University and successfully complete an examination before starting any work with radioactive materials. Participants who have successfully completed the examination are designated as authorized users and allowed to work with radioactive materials without direct supervision. Summer students or other temporary employees are also required to be trained before beginning work with radioactive materials. However, they may not work with radioactive materials without direct supervision by someone who has successfully completed the regular training course and examination. Permit Holders will be required to participate in refresher training every five years and all other radioisotope users such as staff and students will be required to participate in refresher training within a period of three to five years. 3. STANDARD OPERATING PROCEDURES FOR LABORATORY WORK 3.1. ALARA It is the policy of the University to maintain all occupational exposures to ionizing radiation in accordance with the ALARA principle. ALARA is an acronym for As Low As Reasonably Achievable. This takes into account the regulatory dose limits, social and economic factors being taken into consideration to ensure that every possible effort is used to keep radiation exposures as far below the regulated dose limit as practical. All occupational exposures to ionizing radiation shall be limited in accordance with CNSC legislation and the ALARA principle. 3.2. Personal Protective Equipment Direct contact with unsealed radioactive materials must be avoided by the proper use of protective clothing. Disposable items must be placed into radioactive waste disposal containers immediately after use. As a minimum, this consists of: 3.2.1. Laboratory Coats Laboratory coats will be worn fully buttoned and should not be worn outside the active laboratory working areas. Lab coats may not be worn into non laboratory areas such as any eating areas. Where possible, coat hooks should be installed near the exit door to encourage laboratory personnel to remove such clothing before leaving the laboratory. 3.2.2. Gloves Disposable, impervious gloves used for radioisotope work must be removed before leaving the laboratory or after use to prevent the spread of contamination to non radioactive areas (e.g., to telephones and refrigerator or freezer door handles). RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 18 of 50 Integrated Risk Management 3.2.3. Safety Glasses/Goggles or Face Shields Safety glasses/goggles are required for any work involving unsealed radioactive materials. It is recommended that contact lenses not be worn in a laboratory. 3.2.4. Footwear Open-toed shoes are not permitted when handling unsealed radioactive materials. 3.3. General Requirements for Work Area Safety a) There shall be no smoking, drinking, eating or storage of food or food containers in any fridge, freezer or other areas used to contain radioactive materials. b) All personnel are expected to practice ALARA in their work practices. Each Permit Holder must implement procedures designed to reduce exposures to radiation to ALARA. c) Prior to conducting a new procedure involving radioisotopes, a test run using non-radioactive material should be carried out to test the procedure. d) Use the minimum quantity necessary to satisfy the objective of the procedure. e) Where ever possible, the handling of radioactive materials shall be restricted to a one area of the laboratory (e.g. dedicated bench area). The work area must be covered with disposable absorbent materials (e.g. bench covering material), which must be immediately discarded if radioactive material has been spilled. Disposable absorbent material must be replaced on a regular basis. f) External exposures to radiation will be minimized through the appropriate use of shielding material, increasing the distance from the radioactive source and reducing the time spent working with the nuclear substance. g) Internal exposures are minimized by preventing INGESTION, INHALATION, and ABSORPTION through the skin, by implementing proper work safety procedures. h) All equipment and other items used during a radioisotope procedure must be labelled with appropriate radiation warning labels. i) Where feasible, this equipment should be stored in a separate area away from general laboratory use. Before being returned to general use, all equipment must be properly decontaminated. Warning labels must be removed when the item has been decontaminated. j) Where possible, only one sink should be used for the washing of contaminated glassware and equipment. This sink should be clearly labelled with radiation warning signs. Glassware designated for work with radioactive materials should be washed separately. k) When not in use, all containers containing radioactive solutions must be covered and labelled with radiation warning tape, the name of the radioisotope and activity. l) Never pipette radioactive solutions by mouth. A radioactive solution must never be poured from one container to another, but must be transferred carefully with a disposable pipette or tip. m) Radioactive solutions must be transported in such a way as to avoid the spread of radioactive contamination in the event of breakage (e.g. in an outer plastic beaker or tray lined with disposable absorbent liner). RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 19 of 50 Integrated Risk Management n) Where work with unsealed radioactive materials will result in release of radioactive material through volatilization, dispersion of aerosols or splatter, the work will be carried out in a fume hood equipped with an alarming flow monitoring device. o) All radioisotope work areas must be monitored within seven days of usage. Records of monitoring and corrective actions must be maintained and available for inspection. Particular attention should be paid to the floor below the radioisotope work area. Hands and clothing should be monitored to ensure that no contamination has occurred. p) Any radiation detector should be kept away from the radioisotope handling areas to prevent accidental contamination. While materials such as plastic wrap may be used to prevent contamination of the monitor from routine handling, it must be considered that any material placed over the detector will reduce the efficiency of the unit and will no longer be adequate for contamination monitoring purposes. q) Upon completion of a radioisotope experiment, all materials must be properly labelled. All material and equipment used during the procedure must be safely stored or prepared for disposal. r) Materials used in radioisotope area will be easily decontaminated. Cloth or fabric covered chairs are not permitted in radioactive work area. s) All equipment or devices which are to be sent for repair or maintenance must be decontaminated before being released from the radioactive working area. t) Before leaving the laboratory, all persons must wash their hands thoroughly. 3.4. Exposure Monitoring Care should be taken that the dose recorded by the thermoluminescent dosimeter (TLD) badge and/or ring dosimeter is representative of the true dose to the individual to whom it is assigned. The dosimeter must not be left in an area where it could receive a radiation exposure when not worn by the individual (e.g. left near a radiation source). In addition, the lithium fluoride chips inside the TLD badge are sensitive to light and may produce false results if exposed to ultraviolet, fluorescent lights or sunlight. Always store your dosimeters in a dark area with a low radiation background. Care should be taken to maintain dosimeters away from contamination, since this may also result in a false positive reading. Refer to “Procedures for TLD Badges” at http://www.ryerson.ca/irm/programs_polic ies/radiation.html under Standard Operating Procedures. 3.4.1. Action Levels An action level is defined by the Radiation Protection Regulations under the Nuclear Safety and Control Act of Canada as “a specific dose of radiation or other parameter that, if reached may indicate a loss of control of part of a licensee’s radiation protection program and triggers a requirement for specific action to be taken”. They are compared to the annual exposure limits to ionizing radiation are set by the Canadian Nuclear Safety Commission (CNSC). The primary goal of the action to be taken is to prevent a re-occurrence of the event. Action levels are part of Ryerson’s overall radiation protection program. They are designed to alert Ryerson faculty, staff and students before regulatory exposure limits are reached. Table 3 outlines the action limits for individual doses to external radiation and the steps required in the event of an overexposure. Refer to Ryerson’s Radiation Safety Procedures for Action Levels RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 20 of 50 Integrated Risk Management (http://www.ryerson.ca/irm/programs_policies/radiation.html under Standard Operating Procedures) for more details. Table 3. Action Levels for Individual Doses Investigation Level Action Level Quarterly Annually (mSv) (mSv) whole body Member of Public/ Non-NEW Nuclear Energy Worker (NEW) extremities whole body extremities 0.4 10 0.8 10 1 10 10 50 In the event of exposure greater than action levels in Table 3, the Radiation Safety Officer will: a) Conduct an investigation to establish the cause for reaching the action level b) Identify and take action to restore the effectiveness of the radiation protection program c) Notify the Canadian Nuclear Safety Commission within period specified in licence. In the event of when the CNSC dose limit is exceeded, the Radiation Safety Officer will: a) Immediately notify the individual and the CNSC b) Require the affected individual to immediately leave the work that may add to the dose c) Conduct an investigation to establish an estimate of the dose and the cause for the exposure d) Within 21 days, report to the CNSC on the progress of the investigation. 3.4.2. Bioassay Requirements Thermoluminescent dosimeters do not monitor low energy beta emission isotopes (e.g. H-3, C-14, S35). Workers using such isotopes may be required to participate in the bioassay program (i.e. biological monitoring) and submit biological samples for monitoring the amount of a specific radioisotope in the body. In addition, laboratory workers handling radioiodines (e.g. Iodine 131 and Iodine 125) are also required to participate in the bioassay program. The frequency of the bioassay monitoring is dictated by the activity and the radionuclide. The Ryerson Radiation Permit will stipulate the conditions under which a bioassay is required. Two methods can be used for carrying out a bioassay technique - in vitro and in vivo. In vitro techniques are used when a small sample of a body fluid or tissue is sampled and analyzed in a detector. This is the technique used when urine is monitored for assessing tritium uptake. In vivo techniques involve measuring the amount of radioactive material by placing detectors close to the surface of the body. This technique is used for assessing the uptake of radioiodine in the thyroid. RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 21 of 50 Integrated Risk Management It is the responsibility of the Permit Holder to ensure that bioassay monitoring is carried out when required by the conditions outlined in the Ryerson Radiation Permit. Contact the Radiation Safety Officer to arrange for a bioassay measurement. Table 4. Action Levels for Bioassay Monitoring Isotope Iodine I-125 & I-131 Bioassay Monitoring • > 5 MBq (0.13 mCi) in single use on open bench • OR spill > 5 MBq of volatile radioiodine in room • >50 MBq (1.3 mCi) in fume hood • >500 MBq (13 mCi) in glove box • external contamination is detected on the person • process where significant intake is possible dependent on nature of H-3 (e.g., tritiated water vs. compounds, etc), method of handling (open bench or fumehood) and quantities • Tritium (H-3) Frequency Investigation Level 24 hours after use & no later than 4 days after use 1 kBq (thyroid) Action Level 10 kBq (thyroid) 100 kBq/litre (urine) 1 MBq/litre (urine) In the event of exposure greater than action levels in Table 4, the Radiation Safety Officer will: a) conduct an investigation to establish the cause for reaching the action level b) identify and take action to restore the effectiveness of the radiation protection program c) notify the Canadian Nuclear Safety Commission within specified period of licence. In the event of when the CNSC dose limit is exceeded, the Radiation Safety Officer will: a) immediately notify the individual and the CNSC b) require the affected individual to immediately leave the work that may add to the dose c) conduct an investigation to establish an estimate of the dose and the cause for the exposure d) within 21 days, report to the CNSC on the progress of the investigation. 3.5. Posting of Required Laboratory Signs After receiving a Radiation Permit and work begins with radioactive materials, the rooms where radioactive materials will be used or stored will require a variety of signage (Summarized in Table 5 below). Frivolous posting of radiation warning signs or labels is prohibited under federal legislation. a) Internal Permits are required to be posted in a visible location inside all locations listed on permit. The current staff list must be posted with the permit in the main laboratory of the permit holder. RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 22 of 50 Integrated Risk Management b) A copy of the CNSC Rules for Working with Radioisotopes in a Basic/Intermediate/High Level Laboratory or updated information must be posted in each room where radioactive material is handled. Copies may be obtained from the Radiation Safety Officer. c) Entrances to areas where the effective dose rate is greater than 25 µSv/h (or 2.5 mR/hr) or the radioactive substance is in a quantity greater than 100 times its exemption quantity (as outlined in Table 6 below) in the room/area must be marked with a sign (shown in Figure 3) that has a radiation warning symbol and the words “Rayonnement- Danger - Radiation”. Signs can be obtained from the Radiation Safety Officer. RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 23 of 50 Integrated Risk Management Rayonnement - Danger - Radiation Figure 3. Radioactive Warning Sign d) Equipment with more than one (1) exemption quantity (EQ) must have a label with a radiation warning symbol and the words “Rayonnement- Danger - Radiation”. The name, quantity, date of measurement and form of the radioactive substance in the container or device. Refer to Table 6 for some exemption quantities. A more detailed list is available from the Radiation Safety Officer. Table 5. Requirements for Laboratory Signs Location Information and Type of Posting Entrance to: • Radioactive Warning Sign with Permit Holder name and office phone #, 24 hour contact number laboratory, storage area, or other permitted area with more than 100 EQs • Radiation Safety Officer phone # • Copy of the Internal Permit • Current list of authorized users (inside main lab only) • CNSC Safety poster for appropriate Lab category • Radioactive Warning Sign • Indicate dose rate if > 2.5 µSv/h at contact • Radioactive Warning tape identifying work area Inside the lab, in a prominent location Storage Location Work Area RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 24 of 50 Integrated Risk Management Table 6. Exemption quantities for selected radionuclides Radionuclide Exemption Quantity (Bq) Exemption Quantity (µCi) 4 0.27 Carbon-14 7 1 x 10 270 Cesium-137 1 x 104 0.27 Cobalt-60 1 x 105 2.7 Nickel-63 1 x 108 2700 Americium-241 1 x 10 5 2.7 Phosphorus-33 8 1 x 10 2700 Sulphur-35 1 x 108 2700 Tritium (H-3) 1 x 109 27000 Phosphorus-32 1 x 10 Exemption quantities for other radionuclides may be obtained from the Radiation Safety Officer * Based on SCHEDULE I of the Nuclear Substances & Devices Regulations which is available online (most current): http://laws.justice.gc.ca/eng/regulations/SOR-2000-207/index.html 3.6. Purchasing Radioactive Materials The Canadian Nuclear Safety Commission (CNSC) requires that the University maintain a record of all radioactive materials received under the Consolidated Licence. This information is reported to the CNSC annually and must be available for inspection by the CNSC on demand. Therefore acquisition protocols for radioactive materials have been developed and must be strictly observed: 3.6.1. Procedures for Ordering Radioactive Materials Orders can only be placed by permit holders or authorized staff to the Radiation Safety Officer. The Radiation Safety Officer will place the order with the company and charge back the researcher's cost centre. All orders must go through the Radiation Safety Officer. The Radiation Safety Officer must also approve any acquisitions (gifts, free samples, donations, loans, external transfers, exchanges, etc.) of radioactive materials, including sealed sources in devices, before shipment/transfer to the university. The following information will be required for the approval: permit Holder Name and permit number radionuclide activity per unit number of units supplier date expected delivery location (Building and room number) Any acquisitions which do not meet the criteria for approval will have to be corrected by the person reporting the acquisition. Failure to provide the necessary information will delay the approval. Any radioactive material arriving at the University for which there is no prior approval may be confiscated. RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 25 of 50 Integrated Risk Management 3.7.Transfer of Radioactive Materials 3.7.1. Transfers within the University a) Permit Holders are not permitted to “lend” or “borrow” unsealed radioactive materials between laboratories of other Permit Holders without prior approval from the Radiation Safety Officer. The Radiation Safety Officer must ensure that the “Borrower” is authorized to use the radioisotope and the quantity that is being requested. b) Record the quantity, the name of the person “borrowing” and their Permit Number on Inventory Record Form. c) The “borrower” must complete the new Inventory Record Form for their use and disposal of the “borrowed” nuclear substance. All inventory records must be retained and be available upon request. 3.7.2. Transfers from Outside Institutions a) No radioactive materials may be transferred to or from another institution or person outside the University, without prior written notice and approval from the Radiation Safety Officer. b) The receiving institution will require a valid CNSC licence. In addition, the materials must be properly packaged and documented according to CNSC and Transport Canada Regulations. c) Other institutions such as teaching hospitals will have their own separate CNSC licence. Radioactive materials intended for use within the University must be purchased under the University licence and material for use within another outside institution must be purchased under the other institution’s CNSC licence. Any person who is in possession of radioactive material which is not covered by a valid Permit may have the material confiscated and face disciplinary action. 3.8. Receipt of Radioactive Packages Only persons trained and having a valid TDG Class 7 training certificate may receive radioactive packages. The following procedures should be used upon receipt of any radioactive material: a) Shipments must be inspected immediately upon arrival using the guidance of CNSC poster INFO-0744 “Guidelines for Handling Packages Containing Nuclear Substances”. b) Wear a laboratory coat and gloves when inspecting the package. c) Verify the radioisotope, the activity and other details with information on the packaging slip and purchase order, transport labels. Where applicable, monitor the radiation field about the package and compare with units stated on the package. d) Swipe test the packaging for removable surface contamination. Contamination may occur due to defective containers which have not been properly checked upon arrival. If contamination is suspected, open the package only in a fume hood. If no contamination is found on the outer packaging material, the warning labels must be removed or defaced to remove any reference to radioactive materials prior to disposing in the non radioactive regular waste. e) Report any anomalies (leakage, contamination, incorrect shipment) to the shipper. f) Store the radioactive material according to the requirements of the manufacturer in a secure area. RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 26 of 50 Integrated Risk Management g) Remove gloves and wash hands after handling the material and check hands and clothing for contamination and wash hands following these procedures. h) Log the appropriate information in the package receipt form. i) Prepare a new inventory sheet(s) for the radioactive material(s) received. 3.9. Inventory Control CNSC Regulations require that an inventory of all radioactive materials in possession under the terms of the Nuclear Substances and Radiation Devices Licences be maintained. a) A Radiation Permit Holder will maintain an accurate, current inventory of all radioactive material in his/her possession. Blank Inventory Forms can be downloaded from: http://www.ryerson.ca/irm/programs_policies/radiation.html under Laboratory Forms for unsealed radioactive materials that can be used to ensure updated and complete laboratory inventory. For each stock vial, the inventory record must be completed after each use including amount used each time and person using radioactive materials, as well as the final date of disposal. b) The inventory records must be kept up to date and available for inspection by the Radiation Safety Officer or the Canadian Nuclear Safety Commission. c) All radioisotope inventory records must be maintained for three years following disposal of the material. If a Permit Holder leaves the University, these records should be transferred to Integrated Risk Management. 3.10. Storage A radionuclide storage area or container is defined as that area within a licensed facility that provides appropriate shielding, ventilation and security for the materials. The area may be a lead or Plexiglas box, refrigerator, cupboard, or fume hood. For security and safety reasons, it is important that access control to areas storing radioactive materials be strictly observed. Radioactive material shall be kept or stored in a manner that: a) Access to radioactive materials is restricted to only those persons authorized by the Ryerson Radiation Permit. b) All radionuclides (stock, aliquots, products, wastes) must be stored in approved containers within approved areas/laboratories. All radioactive chemicals must be kept in storage cabinets, refrigerators or freezers that have been designated for this purpose. Radio-labelled biological materials or other radioactive compounds that must be stored below -15 0C may be kept in freezers in departmental laboratories as long as they are adequately protected against accidental breakage and unauthorized access. c) All cabinets, refrigerators or freezers used for the storage must be clearly marked with a radiation warning sign on the outside. If only a section of a cupboard or freezer is used, the inside area must be clearly marked. The storage container is labelled in accordance with requirements outlined in section 3.5. All approved containers must be labelled with the date, activity, and name of radionuclide. d) When the area is unattended, all radioactive materials must be stored in a locked location to prevent access. RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 27 of 50 Integrated Risk Management e) Radioactive materials must be properly shielded and stored such that dose rates are less than 2.5 µSv/h at all normally occupied areas outside of the storage area. Many radioisotopes have high energy beta and gamma energies which can create a potential external radiation hazard and must be kept in suitably shielded containers. For example, P-32 which emits high energy beta radiation should also be kept in containers with sufficiently thick Plexiglas shielding. f) Provides adequate protection against theft, fire, explosion, flooding or accidental breakage of primary storage containers. g) Radioactive waste must not be stored under the work area without adequate shielding and containment, as this may present a radiation exposure to personnel working in this area. 3.11. Waste Disposal The Canadian Nuclear Safety Commission is informed of all disposals of radioactive materials from the University. Contact the Radiation Safety Officer for the disposal of all radioactive materials and devices. 3.11.1. General a) Radioactive waste must be kept secured while in the laboratory awaiting disposal. b) Record the quantity and method of disposal, date of disposal and the user name on the Radioisotope Inventory Control Form: http://www.ryerson.ca/irm/programs_policies/radiation.html under laboratory Forms. The Form must be completed and kept current at all times and must be signed and dated when disposal is complete. c) Waste materials must be adequately shielded or stored in a location to minimize potential exposure. d) Each waste container must have a completed Radioactive Waste Tag. Waste tags will be provided by external radioactive waste disposal contractor. Information (waste type, date, isotope and radioactivity) must be legibly and accurately recorded. e) Radioactive waste must not contain any viable biohazardous agents. f) Radioactive waste container must not show any evidence of leaking and must be checked for non-fixed contamination on surfaces (mainly outside) using a wipe test procedure. There are several different types of radioactive waste streams that may require specialized radioactive waste disposal. The procedures for several waste streams are outlined below. 3.11.2. Specific Radioactive Waste Streams RADIOACTIVE DEVICES (SEALED SOURCES) • In equipment containing sealed sources (e.g., gas chromatographs, etc.) the sealed source must be removed and equipment decommissioned prior to disposal. Contact the Radiation Safety Officer prior to disposal of radiation devices to arrange for removal of source(s) and decommissioning. See Section 3.16 on Sealed Sources. SOLID RADIOACTIVE WASTE • All solid radioactive waste must be collected in assigned radioactive waste container. RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 28 of 50 Integrated Risk Management • • • Waste containers must be monitored and shielded if required. Non-contaminated materials must not be discarded with radioactive waste. Solid waste that does not contain any other hazardous materials and is less than the disposal limits outlined in Table 7 can be disposed of as regular waste. RADIOACTIVE SHARPS (needles and syringes) • • All sharps used for dispensing radioactive materials must be placed in an approved sharps container with a Radioactive Waste Tag attached. The outside of sharps containers must be free of any contamination before submitting for disposal. RADIOACTIVE STOCK SHIPMENT VIALS • • All stock vials must be collected and submitted for disposal as solid radioactive waste. All vials with some residual activity must affix label, indicating the date and the amount of activity remaining in the vial. LIQUID SCINTILLATION VIALS • • Liquid scintillation vials must be collected separately in the laboratory. Vial caps must be securely fastened prior to placing them into waste disposal container. Environmentally safe biodegradable scintillation fluid is highly recommended for wipe test and experimental procedures whenever possible. LIQUID RADIOACTIVE WASTE • • • No liquid containing radioactive materials shall be discharged to the laboratory drains. Following addition of liquid waste to the waste container, the radioactive waste tag must be fully completed. The outside of containers must be free of any contamination before submitting for disposal. 3.11.3. Aqueous Washes a) Aqueous liquid wastes (e.g. wash water used to wash lightly contaminated glassware or equipment) resulting from experiments with radioactive materials often contains insignificant amounts of activity, defined by the Canadian Nuclear Safety Commission (CNSC) as nonradioactive. If the quantity of radioactivity is below the release criteria outlined in Table 7 , the CNSC considers the hazard to be non-radioactive and insignificant. However, attention must be paid whether there still exists a biological or chemical hazard in terms of disposal. b) The Permit Holder must obtain authorization from the Radiation Safety Officer prior to any release into the sewer system. The CNSC prescribes release limits on an annual basis per building. The Radiation Safety Officer will track the annual per building release to ensure that the annual limit is not exceeded. c) Any aqueous liquid waste authorized for release may be disposed to the regular drain, followed by several litres of running water to ensure that the sink trap is flushed completely. d) Any non-aqueous liquid waste (e.g. organic solvent) meeting the criteria in Table 7 should be disposed as chemical waste. RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 29 of 50 Integrated Risk Management e) Activities discovered in any liquid waste above the levels in Table 7 must be disposed to the liquid waste container, completing the waste tag, identifying the contents. Table 7. Radioactive Waste Disposal Criteria for Individual Radioisotopes CNSC DISPOSAL LIMITS* Aqueous Liquid Waste For Sewer Release Per Building Solid Waste Radionuclide MBq /kg µCi/kg MBq/ yr mCi/yr Carbon 14 3.7 100 10,000 270 Hydrogen 3 37 1000 1,000,000 2700 Phosphorus 32 0.37 10 1 0.027 Phosphorus 33 1 27 10 0.27 Sulphur 35 0.37 10 1000 27 For other radionuclides, please contact the Radiation Safety Officer * Based on CNSC C-222 Release Criteria & Licence conditions f) Alternatively, the release of short-lived radioactive materials may be delayed until such time that the material has decayed to meet the release criteria outlined in Table 7. This process is termed delay and decay. Consult the Radiation Safety Officer for storage criteria per container. Authorization is still required from the Radiation Safety Officer prior to any release. 3.12. Radiation Detection Equipment Radiation detection equipment in a radiation safety program is used to perform surveys for either contamination or for dose rates. Not all meters are suitable or sensitive enough to detect all types of radiation. 3.12.1. Choice of Instrument Detection equipment must be chosen to have sufficient sensitivity for the radioisotope being monitored. The Permit Holder must determine the radioisotope(s) and thus the type of radiation that will be monitored (beta, gamma, alpha, X-ray or a mixture) and anticipated levels. Special consideration must be given for such parameters as minimum detection limits, efficiency for radioisotope in question, ease of use, etc. Portable instruments are available for contamination and dose rate survey monitoring. The most commonly used dose rate survey meter has an ion chamber detector. However, another popular detector, the Geiger Mueller (GM) counter, can measure radiation levels at lower levels and is less expensive than a survey meter with an ion chamber detector. GM detectors are also frequently used as contamination meters for beta emitting radionuclides with enough energy to penetrate though the detector window. Such GM detectors are often referred to as “pancake” detectors because of their shape. Solid inorganic scintillator crystal detectors, such as thallium-doped sodium iodide (NaI(Tl)) are used for the detection of gamma emitting radionuclides. The thickness of the crystal will depend on RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 30 of 50 Integrated Risk Management the energy range of the gammas to be detected. Thicker crystals are used for high energy gamma detectors, while thinner crystals are used for low energy gamma detectors. Non-portable instruments used for counting wipes, such as liquid scintillation counters are also used for contamination monitoring. Because of the direct contact between the radionuclide on the wipe surface and the organic liquid scintillation “cocktail”, these instruments offer higher detection efficiency and are the only approved method for tritium (H-3) detection. Whatever your purpose, instrument selection must be approved by the Radiation Safety Officer. 3.12.2. Efficiency Efficiencies for all radiation detection equipment must be obtained for those radionuclides that will be used in the laboratory. Portable contamination survey meters must be checked for efficiency annually. Besides electronics, shape and size of detector, many other factors can affect overall efficiency of your instrument. The most important factor, which is also in the control of the user, is distance from source. 3.12.3. Annual Calibration It is a requirement of the CNSC to have a dose rate survey meter calibrated annually. Additionally, it is also a University requirement to have contamination monitoring equipment calibrated annually as well. For calibration of equipment, please contact the Radiation Safety Officer. 3.12.4. Registration Radiation detection equipment must be registered with the Radiation Safety Officer. 3.12.5. Maintenance Radiation detection equipment should be routinely serviced according to the manufacturer's instructions. Keep a record of the service information and dates. Refer to Contamination Monitoring Procedures: http://www.ryerson.ca/irm/programs_policies/radiation.html under Standard Operating Procedures for further information. 3.13. Radiation Surveys for External Radiation and Contamination 3.13.1. Dose Rate Surveys It is a requirement for researchers working with high energy beta emitters such as Phosphorus-32 (P-32) and gamma emitters such as Cr-51, I-125, etc., to be able to determine dose rates. Survey meters will be required to survey incoming packages and monitor levels in the vicinity of active work and storage areas. The radiation levels in radioisotope laboratories (workspace) should be less than 2.5 µSv/h (< 0.25 mR/h). Appropriate shielding should be applied to the radioactive source to reduce the dose rates to below the aforementioned level. Entrances to areas where the effective dose rate is greater than 25 µSv/h (> 2.5 mR/h) in the room/area must be marked with a sign that has a radiation warning symbol and the words RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 31 of 50 Integrated Risk Management “Rayonnement- Danger - Radiation”. Signs can be obtained from the Radiation Safety Officer. Refer to Section 3.5 Posting of Required Laboratory Signs for further details. Following completion of a dose rate survey, record results of levels and locations monitored. Keep the results of the monitoring in a log book, stored in a location accessible for inspection. 3.13.2. Detection of Surface Contamination All radioisotope facilities must be monitored for contamination. Monitoring and contamination control checks must be carried out routinely, and at a minimum within seven days of the usage of radioisotopes. Contaminated areas must be cleaned without delay and verified by further contamination control checks. There are several elements to a monitoring program for surface contamination including frequency, location, decontamination procedures and record keeping. Refer to Contamination Monitoring procedures: http://www.ryerson.ca/irm/programs_policies/radiation.html under Standard Operating Procedures for more specific details. 3.13.2.1. Calculating Amount of Contamination Contamination criteria established by the CNSC for commonly used radioisotopes are outlined below for some common radionuclides. Table 8 identifies the Action Limits in controlled areas (i.e. areas where radioactive materials are normally used or stored) for levels of contamination levels. Those levels which exceed the Action Limits will require decontamination. The limits for other areas (other areas in the lab outside of radiation work zone and public spaces) are ten times lower (i.e., 0.3, 3, and 30). The Permit Holder must report contamination in excess of the Action Limits to the Radiation Safety Officer. The RSO will conduct an investigation to establish the cause for reaching this action level, identify, and take action to help prevent such contamination situations and potential for exposures. Table 8. Action Levels for Removable Surface Contamination in Controlled Areas for Selected Radioactive materials CNSC Contamination Limit for controlled areas 2 Contamination Action Level Radionuclide (Bq/cm ) (Bq/cm2) Carbon-14 300 150 Chromium-51 300 150 Iodine-125 300 150 Iodine-131 30 15 Phosphorus-32 300 150 Phosphorus-33 300 150 Sodium-22 3 1.5 Sulphur-35 300 150 Tritium (H-3) 300 150 RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 32 of 50 Integrated Risk Management For other radioactive materials, please contact the Radiation Safety Officer Removable Contamination The readings from radiation detection instruments can be related to regulatory criteria if the efficiency of the instrument for a specific radioisotope is known. For mixtures of radionuclides, do all the calculations using the radioisotope for which the instrument has the lowest detection efficiency. NOTE: Calculation below is only valid if the removable activity is greater than the instrument’s MDA (Minimum Detectable Activity) for that radionuclide. Removable Activity (Bq/cm2) = Where: (𝑵−𝑵𝒃 ) 𝑬×𝟔𝟎×𝑨×𝑭 N = is the total count rate in counts per minute (CPM) measured directly or on the wipe. Nb = is the count rate of the blank (in CPM) E = instrument efficiency for specific isotope (e.g. for 26% efficiency, E = 0.26) 60 = sec/min (because values entered in CPM) A = area in cm2 (for swipes, wipe an area of 100 cm2, for direct measurements use detector area) F = is the collection factor for the wipe. Use a value of F = 0.1 (i.e., 10%). Do not use for direct measurement (or use a value of 1, i.e. 100%). RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 33 of 50 Integrated Risk Management SAMPLE CALCULATION 2 A tritium contamination occurred on a laboratory bench. A wipe of 100 cm was taken and counted in the liquid scintillation counter for 1 minute with a result of 750 cpm for the sample and 40 cpm for the 2 blank. Determine the result of the measurement of the sample in Bq/cm Assumptions: wipe efficiency is 10% and detector efficiency for tritium is 55% SOLUTION: LLD = 3 + 4.65 * Background × Counting Time Counting Time LLD = 3+(4.65*√40)= 32.4 cpm Net counts = 750- 40 = 710 > LLD, therefore: Removable Activity = (𝑵−𝑵𝒃 ) 𝑬×𝟔𝟎×𝑨×𝑭 = (𝟕𝟓𝟎−𝟒𝟎) 𝟎.𝟓𝟓×𝟔𝟎×𝟏𝟎𝟎×𝟎.𝟏 = 2.15 Bq/cm2 2 Comparing to Table 8 action levels in a controlled area for tritium of 150 Bq/cm , the sample is not contaminated and no further action is required. When the removable activity has been calculated, the figure should be compared to the contamination action levels outlined in Table 8. If the limits have been exceeded, then the next step of decontamination is required (refer to Table 9 for decontamination methods). Fixed (Non removable) Contamination Fixed contamination on a surface can only be assessed using the direct method. That is, calculation without the correction for the efficiency of the wipe (no F value or use F = 1) and using the detector’s area instead of the 100 cm2 for wipes. The dose rate due to fixed contamination should not exceed 2.5 µSv/h at 30 cm from the surface. If so, the area must be shielded with appropriate shielding material to bring the dose rate below 2.5 µSv/h at 30 cm. 3.13.2.2. Decontamination Procedures for Areas and Equipment Should contamination in a work area or on equipment be discovered through routine monitoring, decontamination methods to clean surfaces are outlined in Table 9. The following decontamination procedures are to be followed: a) If contamination is detected on the floor, it must be cleaned immediately. RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 34 of 50 Integrated Risk Management b) If contamination is detected on the bench covering, remove it to solid radioactive waste container and monitor the surface underneath. If contamination is still present, clean the surface. c) If using a portable contamination meter and contamination is noted in the active work area, it may be due to radiation sources and not due to contamination. If it is not feasible to remove the sources, then wipes must be taken (i.e., indirect measurements). d) Clean all areas where contamination is detected until no contamination is detectable or further cleaning does not reduce the contamination (i.e., fixed contamination). e) Radioisotope work areas in the vicinity where maintenance work is to be carried out must be decontaminated prior to the start of such work. Table 9. Decontamination Methods for Removable Surface Contamination Contaminated Surface Dry, porous surface Method HEPA vacuum Spills (small) Hot water and detergent Instructions • Avoid water reactions • All dust must be filtered out using only HEPA filters • Vacuum is considered contaminated • Blot up liquid and rinse with hot water & detergent • May be used on glassware and clothing • Highly effective if immediately applied to non porous surface • Not for large areas of decon • Not effective for areas of long term contamination • make a solution of 3% complexing agent with water • spray surface with solution • keep moist for 30 minutes • remove solution and rinse • smaller objects can be immersed in solution • can be dissolved by immersion or applying solvent to the surface, blotting up the liquid and wiping clean • good ventilation required for flammable toxic vapours • Immerse smaller objects or brush on in a 1-2 N acid solution then flush with water • material must be scrubbed with detergent water mixture and rinsed • Acids may cause excessive corrosion and are hazardous to skin and eyes • Apply abrasive to surface, rub & rinse with water Non porous Non porous surface Organic material Metal and porous surface Non porous surface Decon 75 or Alconox Organic solvent Inorganic acid Abrasion (Steel wool) RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 35 of 50 Integrated Risk Management Non Removable (Fixed) Contamination Monitoring is required after decontamination attempts, to ensure the levels are below the contamination action levels set out in Table 8. If contamination cannot be removed, the contaminated area can be covered, marked with radiation warning tape and shielded if required. The level of fixed contamination (i.e. the amount of contamination remaining in Bq/cm2) should be determined and posted and noted in the Contamination Monitoring Form. 3.14. Record Keeping Requirements All records maintained by the Radiation Safety Officer in the Integrated Risk Management offices will be kept in compliance with CNSC regulations. Records, in respect of any radioactive materials in the Permit Holder’s possession, shall be kept of the following: 3.14.1. Inventory Records Inventory records must be kept. One Radioisotope Inventory Control Form for Unsealed Radioactive materials is required for each vial. The form is available for download at: http://www.ryerson.ca/irm/programs_policies/radiation.html under Laboratory Forms. Copies of the purchase order (if available), packing slips and any Transportation of Dangerous Goods documents must be attached to the form. 3.14.2. Contamination Monitoring Contamination monitoring must be done at least weekly when isotopes are being used. Following completion of a contamination survey, all results must be recorded in the log book containing the Radioisotope Contamination Monitoring Form: http://www.ryerson.ca/irm/programs_policies/radiation.html under Standard Operating Procedures. During those periods when there is no isotope use, this inactivity must be indicated on the forms. Keep the results of the monitoring in a log book, stored in a location accessible for inspection. The Contamination Monitoring Forms are to be completed and available at all times for inspection by the RSO and CNSC. Printouts from scintillation/gamma counters must be attached to the Radioisotope Contamination Monitoring Form. Records of all contamination measurements shall be maintained and available for inspection. 3.14.3. Waste Records Waste logs must be kept to detail all wastes disposed. The Radioisotope Inventory Control Form can also be used to track waste disposal. 3.14.4. Training Records A list of authorized users, working under the permit that use or handle radioactive materials must be available and kept up to date. Maintain records of the training received by a worker for 3 years after termination of the worker’s employment at which point permission to dispose of records must be obtained by the CNSC. RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 36 of 50 Integrated Risk Management 3.14.5. Inspection Records Record of every inspection, measurement, and test or servicing in accordance with permit conditions. Records must be kept for 3 years after the expiry date of the last permit that was issued to the Permit Holder at which point permission to dispose of records must be obtained by the CNSC. 3.14.6. Sealed Source records Record the model, serial number of a sealed source and device containing a radioactive source. Also keep copies of any manuals that accompanied the source or device. If feasible, another copy of the manual should be sent to the Radiation Safety Officer. 3.14.7. Calibration Records All annual calibration records for radiation detection equipment must be kept for three years after the expiry of the permit. Permission to dispose of records must be obtained by the CNSC. Note: Approval from the CNSC is required before disposing of any records. Please contact the Radiation Safety Officer if you wish to dispose of records that are more than 3 years old. 3.15. Work Practices for Specific Radionuclides The Canadian Nuclear Safety Commission has issued Radiation Safety Data Sheets for several isotopes, including H-3, P-32, S-35, I-125, I-131 and others. The Radiation Data Sheets may be found at the CNSC website: http://www.nuclearsafety.gc.ca/eng/resources/radiation/radiation-safety-data-sheets/index.cfm The Data Sheets refer to monitoring, emergency procedures and some radiological physical properties. In addition to the CNSC Radiation Safety Data Sheets, listed below are additional work practices for beta and gamma emitters. 3.15.1. Low Energy Beta Emitters Low energy beta radiation, such as tritium (H-3) is blocked readily by the dead layer of skin cells. Thus it poses no radiation hazard unless it is ingested and enters the body where it can exert its effects on cells at very short distances. It is important to take precautions to prevent ingestion or inhalation. • • • Exposure Monitoring: Dosimeter badges are not needed or required Contamination Monitoring: Wipe tests in Liquid Scintillation Counter Shielding: Not required Specific concerns with individual radioisotopes include: TRITIUM (H-3) - Radiolytic breakdown of labelled compounds is common. The consequent release of either tritium gas or tritiated water vapour can pose a hazard in poorly ventilated areas. Tritiated borohydride is quite unstable and must always be opened and handled inside a fume hood. RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 37 of 50 Integrated Risk Management CARBON-14 - Most compounds are quite stable and need only to be protected from bacterial breakdown. The common exceptions are bicarbonate and carbonate compounds. These compounds must be stored in a well ventilated area and must always be opened and handled inside a fume hood. SULPHUR-35 - All compounds in common use are stable and need only be protected from bacterial breakdown. When labelling cells in culture with S-35 methionine, S-35 contaminated gases are often produced. Therefore, the culture should be placed in a plastic bag with activated charcoal and the incubator monitored for contamination. CALCIUM-45 - All compounds in common use are very stable. Cleaning of contaminated surfaces is difficult and is best accomplished with mild acid (acetic) and chelators. 3.15.2. High Energy Beta Emitters High energy beta radiation emitters such as P-32 penetrate skin readily. As well, the high velocity electrons displace orbital electrons from molecules and cause the emission of low-energy X-rays called bremsstrahlung. This displacement effect is more efficient in dense materials. Thus it is necessary to shield high energy beta radiation with low density shielding such as plastic. Substantial irradiation of the hands can occur when moderate activities of these radioisotopes are handled. Due to the potentially high dose rates encountered, work should never be carried out above an open container of a high energy beta emitter. Good work habits are essential to prevent accidental ingestion. • • • Exposure Monitoring: Whole body dosimeter badges must be worn Contamination Monitoring: GM pancake Shielding: Plexiglas PHOSPOHROUS-32 - It is mandatory to wear ring dosimeters if more than 50 MBq (1.35 mCi) of Phosphorus-32 is handled. 3.15.3. Gamma Emitters • • • Exposure Monitoring: Whole body dosimeter badges must be worn Contamination Monitoring: Sodium Iodide detector Shielding: Lead RADIOACTIVE IODINE (IODINE 125 and IODINE 131) It is very important to prevent ingestion or inhalation of radioactive iodine. Iodine vaporizes readily and can be inhaled when it is in the I2 state. All reactions which are employed to label organic molecules with radioactive iodine require the iodine to be in the volatile I2 state. Great care must be taken to prevent the escape of radioactive iodine vapours during these reactions. It is mandatory that: i. ii. all reactions be carried out in an approved fume hood double gloves must be worn and the outer pair must be discarded between steps RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 38 of 50 Integrated Risk Management The toxicity of Iodine-125 is compensated by its very low energy gamma radiation. Thus the external radiation hazard from Iodine-125 is easily eliminated by only 1 mm of lead (for quantities typically used in university research labs). However, it remains an internal hazard, concentrating in the thyroid gland. Accidental ingestion can be prevented by good work habits and by frequent checks for surface contamination. A Geiger-Muller detector will detect Iodine-131 (because of the medium energy beta) but Iodine-125 can only be detected with a thin crystal sodium-iodide detector. Wipe tests are the easiest way to detect whether surfaces are contaminated with radio-Iodine. 3.16. Sealed Sources Sealed sources are radioactive materials where the radioisotope is encapsulated to prevent direct manipulation of the material. They are usually small sources used for instrument calibration. However, sealed sources also include any radioactive material incorporated into a device such as a liquid scintillation counter, gas chromatograph or other such unit. Sealed sources may also exist in an irradiator, but special permission is required to possess such units. An inventory of all sealed sources held under an internal permit is listed on the permit itself. This will constitute the inventory record provided that it is accurate. It is the responsibility of the permit holder to ensure that the record of sealed sources on the permit is accurate. Sealed sources and devices containing sealed sources must be durably and clearly labelled with a radiation warning sign indicating the type and quantity of radioactive material present. A permit holder is required to notify the Radiation Safety Officer prior to the receipt of any sealed source or device containing a sealed source. Information on the radionuclide, its activity and the device in which it is located must be submitted in writing. The RSO will arrange for the permit amendment. A permit holder must also notify the Radiation Safety Officer prior to the disposal or transfer of any sealed source or a device containing a sealed source. Information on the device and its intended disposition must be submitted to the RSO. In the case of disposal, the RSO will make the appropriate arrangements for removal of the source and the revision of the permit. In the case of a transfer, the RSO will arrange for the permit revision and the leak testing of the source. 3.16.1. Leak testing for sealed sources of 50 MBq (1.35 mCi) or more Leak testing of sealed sources is required under CNSC regulations to ensure that a sealed source has not developed defects, has been damaged or has degraded so as to present an unrecognized radiological risk to persons using or working near the source. Such sources must be leak tested according to the following: Source Type/Condition Frequency of Leak testing Sealed source in storage Sealed source inside an instrument "Free" sealed source 24 months (2 years) 12 months (1 year) 6 months RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 39 of 50 Integrated Risk Management The leak testing procedures must meet certain strict criteria and thus be performed under a CNSC approved protocol. Please contact the Radiation Safety Officer who will arrange for leak testing to be performed by a company that has a CNSC approved protocol. 3.17. Decommissioning Rooms The Permit Holder shall ensure that all areas/laboratories identified on the permit are decommissioned upon termination of the Permit. Decommissioning would include: a) b) c) d) e) f) g) Removal of all radioactive materials or devices to an approved site. Appropriate disposal of all radioactive waste. Removal of all radioactive warning signs and labels. Monitor all areas and decontaminate to meet the CNSC limits (Table 10). Complete Decommissioning Report and forward to Radiation Safety Officer. Update all records. Records must be retained for the period ending 3 years after the expiry date of the last Internal Permit issued. Refer to Section 3.14 – Record Keeping Requirements – for more details. For supervised public areas and for decommissioning, removable surface contamination (i.e., non fixed contamination) limit criteria averaged over an area not exceeding 100 cm2 are outlined in Table 10: Table 10. Classification of Selected Radioactive materials for Removable Surface Contamination Levels in Decommissioned or Public Areas Nuclear Substance CNSC Contamination Limit for Public Area (Bq/cm2) Carbon-14 30 Chlorine-36 30 Calcium-45 30 Chromium-51 30 Sodium-22 0.3 Sulphur-35 30 Tritium (H-3) 30 Phosphorus-32 30 Phosphorus-33 30 Iodine-125 30 Iodine-131 3 RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 40 of 50 Integrated Risk Management In the case of abandoned facilities, the Radiation Safety Officer will immediately arrange for the decommissioning of the facilities and the disposal of all radioactive material in those facilities. If significant costs are involved in this procedure, all costs will be charged to the department with the abandoned facility. A facility may be declared to be abandoned when the Permit Holder is no longer at a Ryerson University facility on a regular basis, takes a sabbatical or leave and has not notified the Radiation Safety Officer of any alternative arrangements, or is no longer in the employ of Ryerson University. 3.18. Ryerson Radiation Permit Revisions 3.18.1. Amendments Permit modifications, additions and/or deletions may be performed at any time via the on-line permit system. The Radiation Safety Officer will be responsible for approving all permit requests. Note that increases in possession limits may change the laboratory designation level to the next level of containment (e.g. from basic to intermediate). Depending on the isotope, this may require additional precautions to be taken or even changes in the design of the laboratory. Any designation above basic containment level also requires approval from the CNSC. The new/updated permit will not be approved until all requirements have been met. 3.18.2. Renewals A permit renewal notice is automatically sent from the permit system at one month prior to the official expiry date, and reminders are also sent subsequently every week until expiry. A permit may also be cancelled at the time of permit renewal. It is recommended, if the permit holder is not currently using radioisotopes and has no immediate plans to resume such work, that the permit be cancelled. If the work with radioisotopes resumes, the permit may be reactivated. 3.18.3. Sabbatical/Extended Leave A permit is granted on the grounds that the permit holder is aware and responsible for the activities in the radioisotope facilities. If a Permit Holder is taking a sabbatical or other type of leave where he or she will not be able to administer this responsibility, arrangements must be made prior to taking the leave. Permit Holders leaving for an extended period of time (sabbatical or longer than a 4 week period) shall advise the Radiation Safety Officer in writing, prior to leaving. The Permit Holder must arrange for another Permit Holder to assume the permit responsibilities during his/her absence. The Radiation Safety Officer will confirm acceptance with the newly appointed Permit Holder and his/her Departmental Chair. If no permit holder can be found, the Permit may be reclassified as an Inactive Permit. A temporary interruption of the permit may be arranged or the responsibility for the work may be assumed by another current permit holder. The latter arrangement must be confirmed in writing by both parties stipulating the effective time period. Any permit holder acting on behalf of another permit holder is responsible for all activities under both permits and subject to all policies. If a permit holder does not advise the Radiation Safety Officer prior to taking leave, the facilities may be considered to be abandoned. RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 41 of 50 Integrated Risk Management 3.18.4. Inactive Status Occasionally when the research with radioactive materials stops for longer periods of time (1 year or longer) the Internal Permit may be designated as “inactive” within the permit’s validity period. No inventory (stocks, aliquots, or waste) or waste shall be on hand. The laboratories that were used for radioactive work must be decommissioned by the Permit Holder. The Permit Holder may contact the Radiation Safety Officer at any time to re-activate the Permit if it has not expired (within validity period). 3.18.5. Suspension/Revocation A permit suspension or revocation may result when the CNSC Regulations or permit conditions are violated. Suspension or revocation of permits will be at the discretion of the Vice President Administration & Finance under the Enforcement Policy for Radiation Safety (in Appendix A). The Radiation Safety Officer will make all necessary arrangements including the decommissioning of any facilities no longer required for radioisotope work. 3.18.6. Expiry/Termination The Permit Holder must request termination of the Permit when his/her employment is terminated or when there are no further plans to continue with radioactive work. Notice must be given at least 4 weeks prior to leaving the University to ensure that the laboratories are decommissioned and all the records are released to the Radiation Safety Officer. Records must be kept 3 years past employment/ termination/expiry of the Permit (refer to Section 3.14). The Department Chair will be held responsible in the absence of the Permit Holder. A permit may also be terminated at the time of permit renewal. It is recommended, if the Permit Holder is not currently using radioisotopes and has no immediate plans to resume such work, that the permit be terminated. If the work with radioisotopes resumes, the permit may be reactivated. 3.19. Self-Audit Checklist – Top 10 Things to Remember 1. No food or drink is consumed in the lab and there is no evidence of food consumption such as wrappers, cups and utensils. 2. Valid Ryerson Radiation Permit is posted in each laboratory listed on the permit. 3. Work is conducted according to Permit conditions and only in the locations listed on the Permit. 4. All personnel working with radioactive materials have successfully received training. 5. Personnel wear the appropriate dosimetry, if applicable. 6. All radioactive sources and containers of radioactive material are labelled with the Isotope, Activity, and the Reference Date. 7. Contamination monitoring is performed at least weekly, and records are maintained. 8. An accurate inventory of all radioactive material within the lab is maintained. 9. Radioactive waste containers are used appropriately. 10. Security of unsealed radioactive materials being maintained. For more information, please contact the Radiation Safety Officer. RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 42 of 50 Integrated Risk Management 4. SECURITY It is required by the Canadian Nuclear Safety Commission (CNSC) that security of radioactive materials must be in place at all times. It is the permit holder’s responsibility to ensure that all radioactive material is kept secure at all times. The level of assessed risk determines the security measures required to protect the radioactive material. The risk is based on the type of isotope, the amount of activity, location, the type of storage and proposed use. Securing access from unauthorized persons such as untrained persons will also prevent accidental exposure. 4.1. Authorized Access a) Only Authorized Users and the Radiation Safety Officer may have access to radioactive materials and all radioactive materials must be secured at all times from unauthorized personnel. b) Persons unknown to the occupants of an area where radioactive materials are used or stored should not be permitted into the area without proper identification and a legitimate reason for entry. 4.2. Maintaining Security When an authorized user is not present in a room containing radioactive materials, that material must be locked within a storage unit (cabinet, refrigerator or freezer, wherever applicable). Unattended radioactive materials must be secured by locking the laboratory door when not attended. To ensure that the security of these materials is maintained, the Radiation Safety Officer or Ryerson Security will lock laboratory doors if the area is found to be unoccupied and radioactive materials not secured. 4.3. Bringing Radioactive materials on Campus Only authorized users may acquire (through purchases, transfers from other institutions, loans, gifts) radioactive materials. All acquisitions must be first approved by the Radiation Safety Officer prior to arrival on campus. Advance notice of incoming radioactive materials, allows the Radiation Safety Officer to determine if sufficient controls measures (such security, training, storage, dose control, permit amendments) are in place for the incoming material. 4.4. Missing Radioactive materials Any suspicion of missing radioactive materials such as loss or theft, misuse or suspicious activities must be reported immediately to the Radiation Safety Officer at extension 4212. After-hours please contact Ryerson Security at 979-5040 who will contact the Radiation Safety Officer. 5. EMERGENCY PROCEDURES In the event of any spill of radioactive material it is important that the correct steps be taken promptly to avoid spread of contamination and unnecessary exposure. PREVENT ACCESS - to contaminated area by marking the area with warning signs, close the laboratory doors, etc. RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 43 of 50 Integrated Risk Management MONITOR - all persons, shoes, clothing, etc., who may be contaminated. Perform simple decontamination as soon as possible. REPORT - spill to supervisor. RECORD - after decontamination, adjust inventory/waste records. Follow Spill Procedures outlined in CNSC INFO-0743 “SPILL PROCEDURES” which must be posted in your lab Notification The Radiation Safety Officer must be notified in the event of a spill involving any one or more of the following situations: • • • • • When a spill is greater than a minor spill quantity as defined in Table 11 When inaccessible areas are suspected to be contaminated When contamination of unknown origin is detected When all reasonable efforts to decontaminate are unsuccessful in reducing the level of contamination to regulatory limits outlined in Table 9 When contamination of personnel has occurred (refer to Table 12) Table 11. Classification of Minor Spills for Selected Radionuclides Radionuclide Exemption Quantity (EQ) Minor Spill Quantity(<100 EQ) (MBq) (MBq) (mCi) Carbon-14 10 1000 27 Phosphorus-32 0.1 10 0.27 Phosphorus-33 100 10000 270 Sulphur-35 100 10000 270 Tritium (H-3) 1000 100,000 2700 Exemption quantities for other radionuclides may be obtained from the Radiation Safety Officer. EMERGENCY TELEPHONE NUMBERS: Radiation Safety Officer: ext 4212 After hours: Dial 80 (Campus Security) 24 hours RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 44 of 50 Integrated Risk Management Contaminated Personnel (Skin or clothing) Personnel working with radioactive material should understand its chemical and radioactive properties such that a prompt response to a suspected intake of material can be carried out. If the material is chemically toxic as well as radioactive, treat for chemical toxicity first. Prompt medical attention is the best procedure. Table 12. Procedures for Decontamination of Contaminated Personnel Emergency Decontamination Steps Contaminated clothing • Ensure that the victim cannot be further contaminated by radioactive material or any responding emergency personnel • Remove any contaminated clothing, place in plastic bag, labelled as to contents, tape shut with radioactive tape • Immediately monitor if any skin contamination has occurred and determine location and extent of contaminated body areas using appropriate survey instrument Ingestion • Obtain medical assistance immediately No visible open wound (skin intact) • Flush contaminated area with copious amounts of warm water • Wet hands and apply mild soap or detergent, lather well with plenty of water • Wash gently for 2 to 3 minutes and rinse thoroughly, keeping rinse water confined to the contaminated area as much as possible • Monitor decontamination using appropriate survey techniques • Repeat wash/rinse procedure if necessary • If further washing does not remove the contamination, contact the RSO. RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 45 of 50 Integrated Risk Management Visible wound (cuts, abrasions, or open wounds • Obtain medical assistance • Advise emergency personnel of the radioactive material, extent of contamination, nature of the injuries and other relevant information • Contact Security, requesting emergency medical assistance (advise of the radiation hazard, the amount and chemical form of the material, any other pertinent information) • Provide first aid to injured personnel immediately, regardless of contamination • Dry clean the affected area with suction and swabs • If skin is contaminated in the area of cuts, abrasions, or open wounds, use wet swabs in a direction away from the area, taking care not to spread contamination over body or into wound • In the case of facial wounds, protect the mouth, ears, eyes and nose from contamination • Notify the permit holder, Radiation Safety Officer will be notified by Security. 6. REFERENCES 6.1. Regulatory Agencies The Canadian Nuclear Safety Commission http://www.nuclearsafety.gc.ca/ The CNSC website contains all regulatory documents and guidelines to control radioactive materials in Canada (these documents can also be found in the Radiation Safety Officer’s office). International Atomic Energy Agency (IAEA) http://www.iaea.org/ The IAEA is an international regulatory body. Transport of radioactive materials between countries is regulated by the IAEA, as well as non proliferation of nuclear weapons. International Commission on Radiological Protection (ICRP) http://www.icrp.org/ This organization reviews scientific publications on the effects of ionizing radiation and publishes recommendations, which are often incorporated into regulations by different countries all over the world. Health Canada’s Radiation Protection Branch http://www.hc-sc.gc.ca/ewh-semt/radiation/measur-mesur/index-eng.php RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 46 of 50 Integrated Risk Management Health Canada’s workplace radiation website has publications on ionizing radiation and also contains links to the National Dosimetry Services for occupational radiation monitoring. 6.2.Professional Radiation Safety Associations Canadian Radiation Protection Association http://crpa-acrp.org/home/ Health Physics Society (USA) http://www.hps.org/ International Radiation Protection Association http://www.irpa.net/ RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 47 of 50 Integrated Risk Management APPENDIX A ENFORCEMENT POLICY for RADIATION SAFETY Introduction The Enforcement Policy for Radiation Safety establishes a series of procedures for the internal verification and enforcement of licensed activities authorized by the Canadian Nuclear Safety Commission (CNSC) and University internal Radiation Permit system. The policy outlines the mechanism for a graduated level of enforcement of the regulatory and University requirements within the University’s radiation safety program. Definitions CNSC – Canadian Nuclear Safety Commission regulates the possession and use of radioactive materials through a licensing process. Consolidated Licence – a licence issued to Ryerson University by the Canadian Nuclear Safety Commission for the possession and use of prescribed radioactive materials and devices High Risk – immediate health, safety, environment or security risk Internal Radiation Permit – issued to qualified individuals that outlines the conditions, amounts and locations where specified radioactive materials may be used Major Offence – a violation that poses an immediate moderate to significant risk to safety, health, environment, security and/or places the CNSC Consolidated Licence in jeopardy. Examples include but are not limited to: • • • • • • • • • • • food/drink in radioisotope area contamination inadequate monitoring substantial dose to workers lack of training unauthorized possession of radioactive materials inadequate storage improper waste disposal incomplete records security breaches multiple minor offences Minor Offence – a breach in procedures that poses no immediate risk to safety, health, environment, security and/or does not jeopardize the University’s CNSC Consolidated Licence. The contravention requires corrective action. Examples include but are not limited to: • • • inadequate posting of required permits or warning signs inappropriate use of radiation warning labels inappropriate segregation/identification of radioactive waste RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 48 of 50 Integrated Risk Management Permit Holder – an individual who has successfully applied and received a Ryerson University Internal Radiation Permit LEVELS OF ENFORCEMENT A progressive scale of enforcement has been adopted based on the level of risk and degree of repetition of incidents. Each separate violation will be reported as a level in the progressive enforcement policy. If corrective actions have not been completed by established timelines, the enforcement is escalated to the next level. If multiple infractions are noted during an inspection by the Radiation Safety Officer, then the sequence in the progressive enforcement will begin with the most serious infraction. Notwithstanding any of the outlined sequence of enforcement, the Radiation Safety Officer reserves the right to bypass any level in the enforcement policy if a serious violation occurs. Failure to comply with a policy or procedure will result in the following actions: LEVEL A: HIGH RISK The Radiation Safety Officer will take immediate action when there is an actual or perceived high risk to health, safety, environment or security. The Radiation Safety Officer has the authority to temporarily stop any work, process, or close any laboratory considered to be in violation of University procedures or CNSC regulations. The use of radioactive materials or radiation devices at the University may be temporarily suspended. The Faculty Dean and/or Assistant Director Risk Management & Prevention will be informed directly of any such action. LEVEL B: MAJOR OFFENCE Stage 1: Radiation safety infraction is observed and recorded by the University Radiation Safety Officer. A copy of the inspection report is forwarded to the Permit Holder and a deadline for corrective action and reporting is specified by the Radiation Safety Officer. Stage 2: The Permit Holder has not replied by the deadline or the same infraction is observed upon a subsequent inspection. Correction action deadline is revised and the Faculty Dean is informed and the notice is also copied to the Departmental Chair. Stage 3: Radiation Safety Officer observes the same infraction in a follow up inspection. The Radiation Safety Officer advises the Vice President Administration & Finance and the Assistant Director Risk Management & Prevention, and the matter is pending formal sanctions. In the meantime, the RSO may impose temporary work stoppage. Sanction options include: suspension of purchasing privileges for radioactive materials, suspension of internal permit and confiscation of radioactive materials by Radiation Safety Officer, or revocation of internal permit. Appeal: Permit holders may appeal any of the sanctions imposed to the Assistant Director Risk Management & Prevention and/or the Vice President Administration & Finance. RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 49 of 50 Integrated Risk Management LEVEL C: MINOR OFFENCE Step 1: Upon first infraction, the Permit Holder is given a verbal warning and a deadline for recommended corrective action by the Radiation Safety Officer. Step 2: Upon a second same infraction, the Radiation Safety Officer issues a written notice of the infraction to the Permit Holder. Corrective action, deadline, and the consequences of further infractions are outlined. The Department Chair and/or Faculty Dean are notified. Step 3: Upon the third occurrence of same infraction, the internal permit is temporarily transferred by the Radiation Safety Officer to another qualified Permit Holder or Chair of the Department. Further work under this permit is only allowed under the direct control of the Departmental Chair or another senior Permit Holder. All purchase requisitions require their approval. Step 4: Upon a fourth occurrence, the Permit Holder must show grounds as to why the internal permit should not be revoked. A special meeting is conducted with the Permit Holder, the Radiation Safety Officer, Chair of the Department and Faculty Dean. The RSO, Chair and Dean will make a formal recommendation to the Assistant Director Risk Management & Prevention and Vice President Administration & Finance who may choose to reinstate the permit. Appeal: Permit holders may appeal any of the sanctions imposed to the Assistant Director Risk Management & Prevention and/or the Vice President Administration & Finance. Any violations greater than one year old will not be considered in further actions. RYERSON UNIVERSITY – Radiation Safety Manual Rev7 2014 Page 50 of 50
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