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Effects of Radiation Exposure

5. Effects of Radiation Exposure. Objectives. Define the key words. Explain the difference between the direct and indirect theories of biological damage. Determine the relative radiosensitivity or radioresistance of various kinds of cells in the body.

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Effects of Radiation Exposure

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  1. 5 Effects of Radiation Exposure

  2. Objectives • Define the key words. • Explain the difference between the direct and indirect theories of biological damage. • Determine the relative radiosensitivity or radioresistance of various kinds of cells in the body. • Explain the difference between somatic and genetic effects.

  3. Objectives • Explain the difference between a threshold dose–response curve and a non-threshold dose–response curve. • Identify the factors that determine radiation injuries. • List the sequence of events that may follow exposure to radiation.

  4. Objectives • Explain the difference between deterministic and stochastic effects. • List the possible short- and long-term effects of irradiation. • Identify critical tissues for dental radiography in the head and neck region

  5. Objectives • Discuss the risks versus benefits of dental radiographs. • Utilize effective dose equivalent to make radiation exposure comparisons. • Adopt an ethical responsibility to follow ALARA.

  6. Key Words • Acute radiation syndrome (ARS) • ALARA (as low as reasonably achievable) • Cumulative effect • Deterministic effect • Direct theory • Dose–response curve

  7. Key Words • Genetic cells • Genetic effect • Genetic mutations • Indirect theory • Ionization • Irradiation • Irreparable injury • Latent period

  8. Key Words • Law of B and T • Lethal dose (LD) • Non-threshold dose–response curve • Period of injury • Radiolysis of water • Radioresistant

  9. Key Words • Radiosensitive • Recovery period • Risk • Somatic cells • Somatic effect • Stochastic effect • Threshold dose–response curve

  10. Introduction • Patients are often concerned with the safety of dental x-ray procedures. • Oral health care professionals share the same concerns.

  11. Introduction • Because even the experts cannot always predict a specific outcome from an amount of radiation exposure, the radiation protection community conservatively assumes that any amount of radiation may pose a risk.

  12. Theories of Biological Effect Mechanisms • Ionization • Direct theory • Indirect theory (radiolysis of water)

  13. Figure 5-1 Direct theory and indirect theory. In the direct theory, x-ray photons collide with large molecules and break them apart by ionization. The indirect theory is based on the assumption that radiation can cause chemical damage to the cell by ionizing the water within it.

  14. Figure 5-2 Indirect theory. X-rays ionize water, resulting in the formation of free radicals, which recombine to form toxins.

  15. Cell Sensitivity to Radiation Exposure • Radiosensitive • Radioresistant • Law of B and T • Somatic effect • Genetic effect • Cumulative effect

  16. Cell Sensitivity to Radiation Exposure White blood cells (lymphocytes) Red blood cells (erythrocytes) Immature reproductive cells Epithelial cells Endothelial cells Connective tissue cells Bone cells Nerve cells Brain cells Muscle cells High sensitivity Low sensitivity

  17. The Dose-Response Curve • Response curve • Threshold dose-response curve • Non-threshold dose-response curve

  18. Figure 5-3 Diagram of dose–response curve. (A) A typical “threshold” curve. The point at which the curve intersects the base line (horizontal line) is the threshold dose that is the dose below which there is no response. If an easily observable radiation effect, such as erythema (reddening of the skin) is taken as “response,” then this type of curve is applicable. (B) A linear “non-threshold” curve, in which the curve intersects the base line at its origin. Here it is assumed that any dose, no matter how small, causes some response.

  19. The Dose-Response Curve ALARA “As Low As Reasonably Achievable”

  20. Factors that Determine Radiation Injury • Five outcomes: • Nothing, the cell is unaffected by the exposure • Cell is injured or damaged but repairs itself and functions at pre-exposure levels • Cell dies, but is replaced through normal biological processes

  21. Factors that Determine Radiation Injury • Five outcomes: • Cell is injured or damaged, repairs itself, but now functions at a reduced level • Cell is injured or damaged, and repairs itself incorrectly or abnormally, resulting in a biophysical change (tumor or malignancy)

  22. Factors that Determine Radiation Injury • Outcomes depend on: • Total dose • Dose rate • Area exposed • Variation in species • Individual sensitivity • Variation in cell sensitivity • Variation in tissue sensitivity • Age

  23. Sequence of Events Following Radiation Exposure • Latent period • Period of injury • Recovery period Assumption: dose received was non-lethal

  24. Figure 5-4 Concept of accumulated irreparable injury. After exposure to radiation cell recovery can take place. However, there may be a certain amount of damage from which no recovery occurs, and it is this irreparable injury that can give rise to later long-term effects.

  25. Radiation Effects on Tissues of the Body • Deterministic (non-stochastic) Effect — when the severity of the change is dependent on the dose • Stochastic Effect — when a biological response is based on the probability of occurrence rather then the severity of the change (i.e., cancer)

  26. Short- and Long-term Effects of Radiation • Short-term effects of radiation are those seen minutes, days, or months after exposure. • Acute Radiation Syndrome(ARS) symptoms include erythema, nausea, vomiting, diarrhea, hemorrhage, and hair loss.

  27. Short- and Long-term Effects of Radiation • Long-term effects of radiation are those that are seen years after the original exposure. • The long-term effects observed are somatic damage, which may result in an increased incidence of cancer, embryological defects, low birth weight, cataracts, and genetic mutations.

  28. Figure 5-5 Ulcerated lesion. Early carcinoma on the finger of a dentist who admitted holding films in the patient’s oral cavity during exposure.

  29. Figure 5-6 Radiation injuryon the finger of a dentist caused by holding films in the patient’s oral cavity during exposure. A lesion of this type would be likely to result in squamous cell carcinoma (cancer).

  30. Risk Estimates • A risk may be defined as the likelihood of injury or death from some hazard. • The primary risk from dental radiography is radiation-induced cancer and, possibly, the potential to affect pregnancy outcomes. • Risk estimates vary, depending on several factors, such as speed of film, collimation, and the technique used.

  31. Risk Estimates • In dental radiography, the most critical tissues of the head and neck are the mandible (red bone marrow), the lens of the eye, the thyroid gland, and possibly the hypothalamus-pituitary-thyroid combination.

  32. Table 5-1 Critical Organs and Doses for Dental Radiograpy

  33. Table 5-2 One in One Million Fatality Risk

  34. Table 5-3 Effective Dose Equivalent

  35. Review: Chapter Summary • Ionizing radiation has the potential to produce biological damage. • There are two generally accepted theories on how radiation may cause damage to cellular tissues: direct theory and indirect theory.

  36. Review: Chapter Summary • The terms radiosensitive and radioresistant are used to describe the degree of susceptibility of various cells and body tissues to radiation. • Biological changes or damage that occur in somatic cells will affect the irradiated individual but will not passed down.

  37. Review: Chapter Summary • Biological changes or damage that do not affect the irradiated individual but are passed to future generations are called genetic effects.

  38. Review: Chapter Summary • The dose–response curve is a method used to plot the dosage of radiation administered with the response produced to establish responsible levels of radiation exposure. • ALARA — as low as reasonably achievable. Every dose of radiation should be kept to a minimum.

  39. Review: Chapter Summary • Factors that influence a biological response to irradiation: dose amount, dose rate, area exposed, species exposed, individual sensitivity, cell sensitivity, tissue sensitivity, and age. • Sequence of events following radiation: latent period, a period of injury, and recovery period.

  40. Review: Chapter Summary • Deterministic-tissue response that is directly related to the radiation amount. Stochastic effect is tissue response that is based on the probability of occurrence rather than severity.

  41. Review: Chapter Summary • Short- or long-term effects: • Short — erythema and general discomfort • Long — an increased incidence of cancer, embryological defects, poor pregnancy outcomes, cataracts, and genetic mutations. • The potential benefits of dental radiographs outweigh the risk.

  42. Recall: Study Questions • General • Chapter Review

  43. Reflect: Case Study • Retaking a radiograph because of a technique or processing error causes an increase in radiation exposure for the patient. Discuss ways a retake radiograph affects the factors that determine radiation injury.

  44. Relate: Laboratory Application • Proceed to Chapter 5, Laboratory Application, to complete this activity.

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