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Radiation Protection Omar Desouky Review article Submitted by:
Medical Biophysics Lab. Radiation Physics Department National Center for Radiation Research and Technology Atomic Energy Authority (AEA) 2010
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Natural 87% Manmade 13% Air 51% Misc. 0.3% Fallout 0.4% Medical 12%
Radon & Thoron Cosmic 10% Food 12% Terrestrial 14% Natural 87% Manmade 13% Misc. 0.3% Fallout 0.4% Occupational 0.2% Nuclear 0.1% Medical 12%
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Fundamental principles of radiation protection
Justification of practices Limitation of doses Optimization of protection and safety
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Justification No use of ionizing radiation is justified if there is no benefit All applications must be justified This implies: All, even the smallest exposures are potentially harmful and the risk must be offset by a benefit
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Optimization When radiation is to be used then the exposure should be optimized to minimize any possibility of detriment. Optimization is “doing the best you can under the prevailing conditions” Need to be familiar with techniques and options to optimize the application of ionizing radiation - this is really the main objective of the present course
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Risk/Benefit analysis
Need to evaluate the benefits of radiation - an easy task in the case of radiotherapy Radiation is the therapeutic agent Assessment of the risks requires the knowledge of the dose received by persons
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ALARA Concept As Low As Reasonably Achievable
GOAL: decrease exposure whenever possible does not eliminate radiation exposure provides guidelines to limit the risk of body injury
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Optimization principle
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Dose limitation No dose limitation for medical exposure of the patient - it is always assumed that the benefits for the patient outweigh the risks Limits need to be applied for public and occupational exposures.
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Basic radiation protection strategies
Radiation cannot be seen, heard or felt. Therefore it is essential to know about it. Can be accurately measured using appropriate instruments Need appropriately qualified expert
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Basic radiation protection strategies
Radiation cannot be seen, heard or felt. Therefore it is essential to know about it. Need signs and interlocks
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Basic radiation protection strategies
Time Distance Shielding
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Dose is proportional to
Time Dose is proportional to the time exposed Dose = Dose-rate x Time
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Distance Inverse square law (ISL): Dose-rate 1/(distance)2 dose-rate
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Shielding Barrier thickness incident radiation transmitted radiation
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Summary Humans must be protected from ionizing radiation at all dose levels Exposure can occur in three different categories: Occupational Medical Public
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Summary The basic principles of a system of radiation protection are:
Dose limits to individuals Optimization of protection Justification of practices Even simple measures such as reducing the time exposed to irradiation or keeping distance can be effective measures to reduce exposure
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Dose Severity Dose Probability
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Accidental external or internal exposure
In considering the use of radioprotectors or therapeutic agents, it is necessary to distinguish the potential application Accidental external or internal exposure Acute high-dose radiation injury, Environmental alpha-particle exposure to the lung, Low-dose occupational exposure over a long time period, Military scenarios Cosmic radiation exposures during space flight, Radiotherapy protocols where protection of normal tissues and killing of tumor cells is required. Uncontrolled exposures to radiation from nuclear accidents potential terrorist incidents
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Potential scenarios for human exposures may involve ingestion of radionuclides, such as isotopes of:
iodine, strontium, americium, cesium, plutonium, Internal exposures of specific organs from ingested radionuclides are best treated initially by blocking agents such as potassium iodide for iodine), chelating agents (Ca DTPA and Zn DTPA for plutonium and americium
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Alpha lipoic acid
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Alpha lipoic acid against different oxidative stresses
The ability of α-lipoic acid to protect the hemoglobin against β-thalassemic disease oxidative damage and exposure to Gamma radiation (150 Gy) Desouky et al, 2008
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Effect of lipoic acid on the oxidative stress of thalassemia
and gamma radiation
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Alpha lipoic acid against different doses of gamma radiation
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Alpha lipoic acid against different doses of gamma radiation
Changes in the EPR (S4) signal intensity for control, irradiated and irradiated & α- lipoic acid of RBC.
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Conclusion
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Applications of radiation in biophysics cover
many fields Radiation techniques are applied in diagnosis and treatment of many diseases. Biophysical measurements are applied for monitoring the effects of radiation exposure as they reflect the missing detailed of the biochemical and biological processes on a molecular level. Biophysical studies are involved in testing and developing radioprotective agents.
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Thanks for attention
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