APS March Meeting 2014
Volume 59, Number 1
Monday–Friday, March 3–7, 2014;
Denver, Colorado
Session Y38: Invited Session: Quantitative Biomedical Imaging
8:00 AM–11:00 AM,
Friday, March 7, 2014
Room: 709/711
Sponsoring
Unit:
GIMS
Chair: Ron Goldfarb, National Institute of Standards and Technology, Boulder
Abstract ID: BAPS.2014.MAR.Y38.5
Abstract: Y38.00005 : Development of Traceable Phantoms for Improved Image Quantification in Positron Emission Tomography
10:24 AM–11:00 AM
Preview Abstract
Abstract
Author:
Brian Zimmerman
(National Institute of Standards and Technology)
Clinical trials for new drugs increasingly rely on imaging data to monitor
patient response to the therapy being studied. In the case of
radiopharmaceutical applications, imaging data are also used to estimate
organ and tumor doses in order to arrive at the optimal dosage for safe and
effective treatment. Positron Emission Tomography (PET) is one of the most
commonly used imaging modalities for these types of applications. In large,
multicenter trials it is crucial to minimize as much as possible the
variability that arises due to use of different types of scanners and other
instrumentation so that the biological response can be more readily
evaluated. This can be achieved by ensuring that all the instruments are
calibrated to a common standard and that their performance is continuously
monitored throughout the trial. Maintaining links to a single standard also
enables the comparability of data acquired on a heterogeneous collection of
instruments in different clinical settings. As the standards laboratory for
the United States, the National Institute of Standards and Technology (NIST)
has been developing a suite of phantoms having traceable activity content to
enable scanner calibration and performance testing. The configurations range
from small solid cylindrical sources having volumes from 1 mL to 23 mL to
large cylinders having a total volume of 9 L. The phantoms are constructed
with $^{\mathrm{68}}$Ge as a long-lived substitute for the more clinically
useful radionuclide $^{\mathrm{18}}$F. The contained activity values are
traceable to the national standard for $^{\mathrm{68}}$Ge and are also
linked to the standard for $^{\mathrm{18}}$F through a careful series of
comparisons. The techniques that have been developed are being applied to a
variety of new phantom configurations using different radionuclides.
Image-based additive manufacturing techniques are also being investigated to
create fillable phantoms having irregular shapes which can better mimic
actual organs and tumors while still maintaining traceability back to
primary standards for radioactivity. This talk will describe the methods
used to construct, calibrate, and characterize the phantoms, focusing on the
preservation of the traceability link to the primary standards of the
radionuclides used. The on-going development of specialized traceable
phantoms for specific organ dosimetry applications and imaging physics
studies will also be discussed.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2014.MAR.Y38.5