Radioisotopes and Radiation Protection PDF

Summary

This document provides an overview of radioisotopes and radiation protection, focusing on their medical applications. It discusses topics such as radiation therapy, nuclear medicine, and different types of radioisotopes. The document also touches on radiation emergencies and safety precautions.

Full Transcript

Radioisotopes and Radiation
Protection

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Copyright © 2014 by Mosby, an imprint of Elsevier Inc.
 Isotopes
 Atoms that have the same number of protons
within the nucleus but have different numbers
of neutrons
 Most elements in the periodic table (see
Appendix C in textbook) have associated
isotopes.
 Not all the nuclei of these isotopes represent
stable configurations of protons and neutrons.

Copyright © 2014 by Mosby, an imprint of Elsevier Inc. 2
100% HL (0 days)
50% IHL 10 days Gamma
z0 days
25% ZHL Alpha

Radioisotopes
30 days
12 5% 3HL.

33 3 days
Beta particles
10 % 3 3HL
let out..

Th are

6 75 % 4HL.
40 days

 Isotopes of a particular element that are
unstable because of their neutron-proton
configuration (some have too many neutrons,
whereas others have too many protons)
 Isotopes that have too many neutrons or
those that have too many protons
spontaneously undergo changes or
transformations to rectify the unstable
arrangement.

Copyright © 2014 by Mosby, an imprint of Elsevier Inc. 3
 Medical Usage
 Radiation therapy
 Well-oxygenated, rapidly dividing cells are very sensitive
to damage by radiation.
 This causes cancerous growths or tumors to be either
eliminated or at least controlled by irradiation of the area
containing the growth.
 Radiation may be delivered internally to such regions by
infusion or implantation of certain radioisotopes.
 Therapeutic isotopes are characterized by relatively long
half-lives that are measured in terms of multiple days or
multiple years and, with the exception of a few of them,
by quite-high-energy radiation.
 Radiation may be in the form of gamma rays or fast
electrons (beta radiation).
Copyright © 2014 by Mosby, an imprint of Elsevier Inc. 4
 Medical Usage (Cont.)
 Radiation therapy (Cont.)
 Most important therapeutic radioisotopes
Iodine-125 (125I) has been used quite extensively since
2000 in the form of titanium-encapsulated cylindric seeds
to give a tumoricidal radiation equivalent dose (EqD) to
cancers that are confined within the prostate gland (see
- slide 5).
 Treatment goal is to deliver 145 Gy to at least 90% of

- the prostate’s volume while limiting radiation dose as
much as possible to adjacent structures such as the
o urethra, bladder, and anterior rectal wall.
 Decays by a process called electron capture
 Distance and time are best radiation safety practices.

Copyright © 2014 by Mosby, an imprint of Elsevier Inc. 5
 Medical Usage (Cont.)
 Radiation therapy (Cont.)
 Most important therapeutic radioisotopes (Cont.)
Iodine-125
&

Figure 14-01. A, Iodine-125 (125I)-titanium–encapsulated cylindric seed. B, 125I seeds before
encapsulation. (Implant Sciences Corporation)

Copyright © 2014 by Mosby, an imprint of Elsevier Inc. 6
 Medical Usage (Cont.)
 Radiation therapy (Cont.)
 Most important therapeutic radioisotopes (Cont.)
Iodine-131 (131I)
 Has a half-life of 8 days
 Can be joined chemically with sodium to form a radioactive
compound called sodium iodide 131I, which can be orally
administered in the form of tablets that are an efficient way
of delivering a destructive radiation dose to a specific
cancer site, such as the remainder of any residual thyroid
tissue after can cancer surgery
 Personnel radiation protection considerations and
measures while providing care for 131I therapy patients
 Radioactive decay process: beta decay

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 Medical Usage (Cont.)
 Nuclear medicine
 Employs radioisotopes to
Study organ function in a patient
Detect the spread of cancer into bone
Treat certain types of disease
 Diagnostic techniques in nuclear medicine
typically make use of short-lived radioisotopes as
radioactive tracers.
 Common radioisotopes used in nuclear medicine
-
Iodine-123 (123I): When chemically coupled with sodium,

e it forms the radiotracer compound sodium iodide 123I that
preferentially concentrates in the thyroid gland and

- achieves levels of concentration that can be directly
correlated with the thyroid gland’s performance status.
Average half life 13 3 hrs.

Copyright © 2014 by Mosby, an imprint of Elsevier Inc. 8
 Medical Usage (Cont.)
 Nuclear medicine (Cont.)
 Common radioisotopes used in nuclear medicine
(Cont.)
Technetium-99m (99mTc)
 Most commonly used radioisotope in nuclear medicine
 Produced from the radioactive decay of another unstable
isotope, molybdenum-99 (99Mo)
 Is an extremely versatile radioisotope because it can be
incorporated into a wide variety of different compounds
or biologically active substances, each with a specificity
for different tissues or organs of the body
 Has many uses

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 Medical Usage (Cont.)
 Positron emission tomography (PET) and computed
tomography (CT)
 Makes use of annihilation radiation events that are a
byproduct of pair production
 Annihilation radiation is initiated by the radioactive decay of
the nucleus of an unstable isotope having too many protons
within the nucleus.
 Excess proton transmuted into a neutron and positron
(antimatter)
 Emission of a neutrino
 Positron, when passing close to an electron, will interact
destructively. Both particles disappear, having annihilated
one another. Their respective masses will be converted into
energy that will be carried off by two photons emerging from
the annihilation site in opposite directions, each with a
kinetic energy of 511 keV.
Copyright © 2014 by Mosby, an imprint of Elsevier Inc. 10
 Medical Usage (Cont.)
 PET and CT (Cont.)
 Imaging
 Concept of PET scanning
 Importance as an imaging modality
 Fluorine- 18 (18F):
 Positron-emitter; most important isotope used in
PET scanning
It can be attached to a glucose molecule, yielding the
compound, fluorodeoxyglucose (FDG), a radioactive
tracer that will be taken up or metabolized by cancerous
cells. As such it reveals location of these cells through its
positron emission decay and subsequent generation of
oppositely traveling annihilation photons.
 Concept of a PET/CT scanner
Copyright © 2014 by Mosby, an imprint of Elsevier Inc. 11
 Medical Usage (Cont.)

Figure 14-02. Combined positron emission tomography/computed tomography (PET/CT) system. (Frank
ED, Long BW, Smith BS: Merrill’s Atlas of Radiographic Positioning & Procedures, ED 12, St. Louis,
2012, Mosby)

Copyright © 2014 by Mosby, an imprint of Elsevier Inc. 12
 Medical Usage (Cont.)
 Radiation protection (Cont.)
 Radiation safety shielding considerations for PET/CT
scanners
 Considerations
 Scattered radiation by the CT scanner portion
 High-energy annihilation photons
 Presence of a third high-energy source of radiation
 Patient “prep” time
 Necessary protection for technologist(s) and other personnel
 Necessary shielding
 Considerations
 Shielding in a well-designed facility
Copyright © 2014 by Mosby, an imprint of Elsevier Inc. 13
 Medical Usage (Cont.)

 Radiation
protection (Cont.)
 Radiation safety
shielding
considerations for
PET/CT scanners
(Cont.)
Figure 14-03. Layout diagram of a positron emission
tomography/computed tomography (PET/CT) imaging
facility.

Copyright © 2014 by Mosby, an imprint of Elsevier Inc. 14
Radiation Emergencies: Use Of
Radiation as a Terrorist Weapon
 Most hospitals have radiation emergency
plans for handling emergency situations
involving radioactive contamination.
 Radiologic technologists should become
aware of the radiation emergency plans that
exist in the facilities in which they work.

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Radiation Emergencies: Use Of
Radiation as a Terrorist Weapon
(Cont.)
 Contamination
 Radioactive dispersal device, or “dirty bomb”
 A radioactive source mixed with conventional
explosives
 Intended to contaminate an area with radioactive
material and thereby cause panic
 Use of Geiger-Műller (GM) detectors
 Long-term health effects

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 Radiation Emergencies: Use Of
Radiation as a Terrorist Weapon
(Cont.)
 Decontamination
 Removal of contaminated clothing
 Immersion in a shower
 Wound containing radioactive material
 Simple rinse of the area is usually sufficient
 Use of GM detectors
 Environmental protection agency (EPA) dose limit
recommendations
 For individuals engaged in non–life-saving activities
 For individuals engaged in life-saving activities

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Radiation Emergencies: Use Of
Radiation as a Terrorist Weapon
(Cont.)
 Cleanup of a contaminated urban area
 Risk limits for radioactive contamination set by the
EPA
 Considerations
 Medical management of people experiencing
radiation bioeffects
 Surface contamination procedures
 Dealing with patients with acute radiation
syndrome (ARS) (see next slide)
 Internal contamination procedures

Copyright © 2014 by Mosby, an imprint of Elsevier Inc. 18
Radiation Emergencies: Use Of
Radiation as a Terrorist Weapon
(Cont.)
 Medical management of people experiencing
radiation bioeffects (Cont.)

Copyright © 2014 by Mosby, an imprint of Elsevier Inc. 19