Radiation biology

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Revision as of 11:33, 27 November 2023 by Nikolas (talk | contribs) (Created page with "* Radiation ** '''Absorbed radiation is measured by Gray (Gy)''' *** '''It does not take into account the biological effect of radiation''' ** '''Health effects of radiation is measured by Sievert (Sv)''' *** '''It does take into account the biological effect of radiation''' ** '''Types of radiation used for therapy''' *** Gamma rays (?) **** Used in stereotactic radiosurgery with gamma knife *** '''Alpha radiation''' **** Radium-223 **** For example for bone metastases...")
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  • Radiation
    • Absorbed radiation is measured by Gray (Gy)
      • It does not take into account the biological effect of radiation
    • Health effects of radiation is measured by Sievert (Sv)
      • It does take into account the biological effect of radiation
    • Types of radiation used for therapy
      • Gamma rays (?)
        • Used in stereotactic radiosurgery with gamma knife
      • Alpha radiation
        • Radium-223
        • For example for bone metastases or prostate cancer
      • Beta radiation
        • Iodine-131
        • For example for thyroid cancer
    • Types of radiation used in diagnostics
      • Positron
        • PET scan
      • Gamma
        • X-ray
        • CT
        • Many nuclear imaging studies
    • X-ray interactions with matter
      • Compton scattering
        • Makes x-rays scatter off the patient -> the patient becomes the source of scattered radiation
          • This scattered radiation can hit personell or equipment
          • Personell and equipment should be protected
        • Reduces image contrast
      • Photoelectric effect
        • It’s what makes contrast agents work
      • Coherent/Rayleigh scattering
      • Pair production does NOT occur
        • Only at energy levels much higher than medical x-ray
    • Biological effects of radiation
      • Deterministic effects (nonrandom)
        • Examples
          • Skin erythema
          • Hair loss (3 Gy)
          • Sterility
          • Death (3 – 5 Gy)
        • Occur when the radiation-induced cell damage exceeds the cell’s ability to repair the damage
      • Stochastic effects (random)
        • May occur at any level of exposure
        • Probability for occuring increases with increasing dose
        • Severity is independent of the dose
        • Due to DNA and free radical damage
        • May occur years after exposure
        • Examples
          • Cancer
            • 10 mSv increases risk for cancer (0,04 mSv per x-ray)
      • Most radiosensitive organs
        • Organs with rapidly dividing cells
        • Bone marrow
        • Colon
        • Lung
        • Breast
        • Stomach
    • Protection from radiation
      • Radiation protection involves 3 parts
        • ALARA
        • Justifiable exposure
        • Dose limits
      • ALARA principle – as low as reasonably achievable
        • High quality images should be obtained by using the lowest possible dose
        • Factors contributing to reducing radiation
          • Beam collimators
            • Decrease scattering
          • Lead apron
          • Careful indications
            • Asking yourself whether the benefits outweigh the risk, and whether a non-radiating modality could be used instead
          • Standing far away from the patient as possible
          • Accurately setting the field of examination
      • Three major safety practices
        • Time – limiting exposure duration
        • Distance
          • According to the inverse square law one can reduce their exposure to 25% by standing twice as far away from the source
        • Shielding
          • Using lead to limit the amount of radiation exposure
      • Yearly occupational limit – < 20 mSv
      • Personal monitoring = dosimetry
        • Every person can carry a dosimeter which measures the radiation dose received