Energy-based compensation for nonuniform attenuation in Ga-67 SPECT imaging

Energy-based compensation for nonuniform attenuation in Ga-67 SPECT imaging

Describes a method to estimate unattenuated projection images directly from Ga-67 SPECT data acquired over 360/spl deg/ at 3 photopeak energies. The algorithm compensates to third order for the effects of nonuniform attenuation, thereby yielding unattenuated projections with <3% accuracy, provide...

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Bibliographic Details
Published in:IEEE transactions on nuclear science Vol. 47; no. 3; pp. 1149 - 1154
Main Authors: Moore, S.C., Muller, S.P., Kijewski, M.F.
Format: Journal Article
Language:English
Published: New York IEEE 01-06-2000
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
Acceleration
Algorithms
Attenuation
Attenuation measurement
Biomedical imaging
Collimators
Compensation
Electromagnetic scattering
Equations
Estimates
Hospitals
Imaging
Nonuniform
Particle scattering
Projection
Radiology
Scatter
Single photon emission computed tomography
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Summary:Describes a method to estimate unattenuated projection images directly from Ga-67 SPECT data acquired over 360/spl deg/ at 3 photopeak energies. The algorithm compensates to third order for the effects of nonuniform attenuation, thereby yielding unattenuated projections with <3% accuracy, provided that scattered photons have been successfully subtracted from each energy window. Previously, the authors demonstrated an approach for using prior information to control noise in the estimated projections. They describe here an accelerated, robust algorithm for implementing these constraints. They have also evaluated the accuracy of the method for a region-of-interest (ROI) activity estimation task as a function of the residual error following scatter subtraction, and under conditions of nonstationary spatial resolution. When the maximum residual scatter subtraction errors at 93, 185, and 300 keV, respectively, were assumed to be 8%, 4%, and 2%, all ROI estimates were biased less than /spl plusmn/7% after attenuation compensation. Projection inconsistencies arising from distance-dependent geometric response and energy-dependent collimator penetration increased the standard deviation of ROI estimates (over location) to /spl sim/10%; however, methods of correcting for distance-dependent collimator response can probably be adapted well to Ga-67 imaging. If scatter can be adequately removed from the 3 Ga-67 photopeak windows, this technique is expected to provide reliable compensation for nonuniform attenuation with no need for an independently measured attenuation map.
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ISSN:0018-9499
1558-1578
DOI:10.1109/23.856562