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AAPM Task Group 108: PET and PET/CT Shielding Requirements
Author(s) -
Madsen Mark T.,
Anderson Jon A.,
Halama James R.,
Kleck Jeff,
Simpkin Douglas J.,
Votaw John R.,
Wendt Richard E.,
Williams Lawrence E.,
Yester Michael V.
Publication year - 2006
Publication title -
medical physics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.473
H-Index - 180
eISSN - 2473-4209
pISSN - 0094-2405
DOI - 10.1118/1.2135911
Subject(s) - positron emission tomography , electromagnetic shielding , task group , medical physics , nuclear medicine , dosimetry , nuclear engineering , computer science , medicine , physics , engineering , engineering management , quantum mechanics
The shielding of positron emission tomography (PET) and PET/CT (computed tomography) facilities presents special challenges. The 0.511 MeV annihilation photons associated with positron decay are much higher energy than other diagnostic radiations. As a result, barrier shielding may be required in floors and ceilings as well as adjacent walls. Since the patient becomes the radioactive source after the radiopharmaceutical has been administered, one has to consider the entire time that the subject remains in the clinic. In this report we present methods for estimating the shielding requirements for PET and PET/CT facilities. Information about the physical properties of the most commonly used clinical PET radionuclides is summarized, although the report primarily refers to fluorine‐18. Typical PET imaging protocols are reviewed and exposure rates from patients are estimated including self‐attenuation by body tissues and physical decay of the radionuclide. Examples of barrier calculations are presented for controlled and noncontrolled areas. Shielding for adjacent rooms with scintillation cameras is also discussed. Tables and graphs of estimated transmission factors for lead, steel, and concrete at 0.511 MeV are also included. Meeting the regulatory limits for uncontrolled areas can be an expensive proposition. Careful planning with the equipment vendor, facility architect, and a qualified medical physicist is necessary to produce a cost effective design while maintaining radiation safety standards