RADIATION PROTECTION OF WORKERS Radiotherapy · radiotherapy are capable of delivering such doses....
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! DO DO Radiotherapy DO NOT DO NOT DOSE AND EFFECTS þ þ þ þ þ Wear your personal dosimeter if you have been issued with one. Ensure, for high dose rate sources, that the scattered radiation detector is operational. Use local shielding, gloves and long forceps when handling brachytherapy sources. Monitor the patient and the treatment area after each patient has been treated. Use a survey meter to check that the source is fully shielded or the exposure has terminated. Manipulating sources Radioactive brachytherapy sources are unsafe to handle directly with the fingers. Long-handled tongs or tweezers must be used. Care of sources Radioactive sources must be: Stored in a secure, shielded and labelled storage facility. Labelled with the radionuclide name, activity and serial number. Checked each day, and whenever a source is moved; a record of these checks must be kept. þ þ þ Brachytherapy Brachytherapy treatments may involve placing the source directly against the diseased tissue (direct loading) or placing a source into applicators or tubes for a prescribed time (after loading). Brachytherapy using high dose rate sources must be carried out in a controlled environment where: Staff must remain outside the room during the treatments. The treatment room must be fitted with interlocked doors and warning signs. The patient must be supervised via a shielded window or a closed circuit TV (CCTV). A radiation monitor of scattered radiation must be present inside the room to show when the source is in use. The requirements for using low dose rate sources are not as stringent as those listed above. þ þ þ þ þ þ þ Check the operation of safety features daily. Service interlocks and warning systems as recommended by the manufacturer. Always wear a dosimeter if you have been given one. ’Defence in depth’ Defence in depth means safety in many layers so that if a single safety feature fails, protection will still be provided. In external beam therapy, this means: A treatment room that offers good shielding. A maze entrance to the treatment room. Interlocked access points. Signals in the room and at the entrance when dose rates are high. Emergency off switches in the room. The safety features must be designed such that a component failure will cause the device to attain rest in a safe condition. The safety features must be regularly serviced. þ þ þ þ þ þ Leave a source unattended at any time. Discharge a patient who has not been monitored, or who has implanted radioisotopes above the activity discharge limits. þ þ þ þ Enter the room if the “radiation on” warning light is illuminated. Use the room if any of the safety features are damaged. Use the room unless you are sure that it is safe. Radiation doses to staff must be kept: As Low As Reasonably Achievable: ALARA safety features are installed and maintained staff are trained to follow procedures staff doses will be low, typically 1 mSv per year or less doses can be very high if there are accidents. if and then but BRACHYTHERAPY EXTERNAL BEAM THERAPY EXTERNAL BEAM THERAPY BRACHYTHERAPY Radiotherapy is the use of ionizing radiation to kill diseased tissue. Radiation sources used for radiotherapy may be external to the tissue (external beam therapy) or in contact with the tissue (brachytherapy). Radiotherapy sources are designed to deliver very high radiation doses to the treatment area. However, from an occupational exposure point of view: External beam therapy treatment requires very high dose rates which may be delivered by radioactive sources (e.g. cobalt-60) or radiation generators (e.g. linear accelerators). Radioactive sources emit radiation all the time, but are shielded when not in use. Radiation generators do not emit radiation when they are switched off. However, generators can sometimes induce activity that will normally take a very short time to decay. Brachytherapy patients must be monitored immediately after treatment and before being discharged. Dosimeters: If dosimeter badges are provided, they should be worn between the shoulders and the hips. Small dosimeters, worn on a finger, can monitor the dose to the hand. Dosimeters must be returned to the provider so that the dose information can be read. Dosimeters must not be shared. Dosimeters do not provide protection from exposure to ionizing radiation, they are a means of assessing the dose that the wearer has received. tweezers RADIATION PROTECTION OF WORKERS Units of dose Dose rate Health effects of radiation exposure The unit of absorbed dose is the gray (Gy). The unit used to quantify the dose in radiation protection is the sievert . One millisievert (mSv) is 1/1000 of a sievert. One microsievert ( Sv) is 1/1000 of a millisievert. Dose rate is the dose received in a given time. The unit used is microsieverts per hour ( Sv/h). If a person spends two hours in an area where the dose rate is 10 μSv/h, then they will receive a dose of 20 μSv. (Sv) If radiation doses are very high, the effect on the body will appear relatively soon after the exposure. These acute injuries will occur if the absorbed dose is higher than a threshold value; the sources and equipment used in radiotherapy are capable of delivering such doses. It is therefore essential that procedures for work are followed. Even if the dose is not high enough to cause serious injury, there is still the possibility of incurring other health effects. These effects, e.g. radiation induced cancer, are risk based, i.e. the higher the dose received, the greater the chance of developing the effect. To reduce the possibility of developing late effects, radiation doses must be kept: Annual doses from natural background radiation vary on average between 1 mSv and 5 mSv worldwide. μ The typical dose from a chest X ray is 20 μSv. μ AS LOW AS REASONABLY ACHIEVABLE (ALARA) RADIATION PROTECTION FROM EXTERNAL EXPOSURE Time To reduce radiation doses, the time spent in radiation areas must be kept as short as possible. The longer the time spent in an area, the higher the dose received. In an area where the dose rate is 100 Sv/h, the dose received will be: μ Distance 1 cm of plastic will totally shield all beta radiation. Lead and concrete can be used to shield against gamma and X radiations. Shielding material must be appropriate for the type of radiation. For example: 0 minutes 15 minutes 30 minutes 1 hour 2 hours 0 μSv 25 μSv 50 μSv 100 μSv 100 μSv/h 200 μSv Shielding plastic lead concrete 1 m 2 m 25 μSv/h If the dose rate at 1 m from a source is 100 /h. μ μ Sv/h, the dose rate at 2 m will be 25 Sv Exposure to gamma and X rays can be controlled by consideration of time, distance and shielding:
Transcript of RADIATION PROTECTION OF WORKERS Radiotherapy · radiotherapy are capable of delivering such doses....
!
DODO
Radiotherapy
DO NOT
DO NOT
DOSE AND EFFECTS
þ
þ
þ
þ
þ
Wear your personal dosimeter if you have been issued withone.
Ensure, for high dose rate sources, that the scatteredradiation detector is operational.
Use local shielding, gloves and long forceps when handlingbrachytherapy sources.
Monitor the patient and the treatment area after each patienthas been treated.
Use a survey meter to check that the source is fully shieldedor the exposure has terminated.
Manipulating sources
Radioactive brachytherapy sources are unsafe tohandle directly with the fingers. Long-handled tongsor tweezers must be used.
Care of sources
Radioactive sources must be:
Stored in a secure, shielded and labelled storage facility.
Labelled with the radionuclide name, activity and serial number.
Checked each day, and whenever a source is moved; a record of these checks must be kept.
þ
þ
þ
Brachytherapy
Brachytherapy treatments may involve placing the source directly againstthe diseased tissue (direct loading) or placing a source into applicators ortubes for a prescribed time (after loading). Brachytherapy using high doserate sources must be carried out in a controlled environment where:
Staff must remain outside the room during the treatments.
The treatment room must be fitted with interlocked doors and warningsigns.
The patient must be supervised via a shielded window or a closedcircuit TV (CCTV).
A radiation monitor of scattered radiation must be present inside theroom to show when the source is in use.
The requirements for using low dose rate sources are not as stringentas those listed above.
þ
þ
þ
þ
þ
þ
þ
Check the operation of safety features daily.
Service interlocks and warning systems asrecommended by the manufacturer.
Always wear a dosimeter if you have been givenone.
’Defence in depth’
Defence in depth means safety in many layers so that if asingle safety feature fails, protection will still be provided.
In external beam therapy, this means:
A treatment room that offers good shielding.
A maze entrance to the treatment room.
Interlocked access points.
Signals in the room and at the entrance when dose ratesare high.
Emergency off switches in the room.
The safety features must be designed such that acomponent failure will cause the device to attain rest in asafe condition.
The safety features must be regularly serviced.
þ
þ
þ
þ
þ
þ Leave a source unattended at any time.
Discharge a patient who has not been monitored, or who hasimplanted radioisotopes above the activity discharge limits.
þ
þ
þ
þ
Enter the room if the “radiation on” warning light isilluminated.
Use the room if any of the safety features aredamaged.
Use the room unless you are sure that it is safe.
Radiation doses to staff must be kept: As Low As Reasonably Achievable: ALARA
safety features are installed and maintained
staff are trained to follow procedures
staff doses will be low, typically 1 mSv per yearor less
doses can be very high if there are accidents.
if
and
then
but
BRACHYTHERAPY EXTERNAL BEAM THERAPY
EXTERNAL BEAM THERAPYBRACHYTHERAPY
Radiotherapy is the use of ionizing radiation tokill diseased tissue. Radiation sources used forradiotherapy may be external to the tissue(external beam therapy) or in contact with thetissue (brachytherapy). Radiotherapy sourcesare designed to deliver very high radiation dosesto the treatment area. However, from anoccupational exposure point of view:
External beam therapy treatment requires very high doserates which may be delivered by radioactive sources (e.g.cobalt-60) or radiation generators (e.g. linearaccelerators).
Radioactive sources emit radiation all the time, but areshielded when not in use.
Radiation generators do not emit radiation when theyare switched off. However, generators can sometimesinduce activity that will normally take a very short timeto decay.
Brachytherapy patients must be monitored immediatelyafter treatment and before being discharged.
Dosimeters: If dosimeter badges are provided, they should beworn between the shoulders and the hips. Small dosimeters,worn on a finger, can monitor the dose to the hand. Dosimetersmust be returned to the provider so that the dose informationcan be read. Dosimeters must not be shared.Dosimeters do not provide protection from exposure toionizing radiation, they are a means of assessing the dosethat the wearer has received.
tweezers
RADIATION PROTECTION OF WORKERS
Units of dose
Dose rate
Health effects of radiation exposure
The unit of absorbed dose is the gray (Gy).
The unit used to quantify the dose in radiationprotection is the sievert .
One millisievert (mSv) is 1/1000 of a sievert.
One microsievert ( Sv) is 1/1000 of a millisievert.
Dose rate is the dose received in a given time.The unit used is microsieverts per hour ( Sv/h).
If a person spends two hours in an area where thedose rate is 10 µSv/h, then they will receive a dose of20 µSv.
(Sv)
If radiation doses are very high, the effect on the body willappear relatively soon after the exposure. These acuteinjuries will occur if the absorbed dose is higher than athreshold value; the sources and equipment used inradiotherapy are capable of delivering such doses. It istherefore essential that procedures for work arefollowed.
Even if the dose is not high enough to cause seriousinjury, there is still the possibility of incurring other healtheffects. These effects, e.g. radiation induced cancer, arerisk based, i.e. the higher the dose received, the greaterthe chance of developing the effect. To reduce thepossibility of developing late effects, radiation dosesmust be kept:
Annual doses from natural background radiation varyon average between 1 mSv and 5 mSv worldwide.
µThe typical dose from a chest X ray is 20 µSv.
µ
AS LOW AS REASONABLY ACHIEVABLE (ALARA)
RADIATION PROTECTION FROM EXTERNAL EXPOSURE
Time
To reduce radiation doses, the time spent inradiation areas must be kept as short aspossible. The longer the time spent in an area,the higher the dose received.
In an area where the dose rate is 100 Sv/h,the dose received will be:
µ
Distance
1 cm of plastic willtotally shield all betaradiation.
Lead and concrete canbe used to shieldagainst gamma andX radiations.
Shielding material must be appropriate for the
type of radiation. For example:
0 minutes 15 minutes 30 minutes 1 hour 2 hours
0 µSv 25 µSv 50 µSv 100 µSv
100 µSv/h
200 µSv
Shielding
plastic lead concrete
1 m
2 m
25 µSv/h
If the dose rate at 1 m from a source is 100/h.
µµ
Sv/h,the dose rate at 2 m will be 25 Sv
Exposure to gamma and X rayscan be controlled by considerationof time, distance and shielding:
