DocumentCode
1531561
Title
Absolute quantitation of myocardial activity in phantoms
Author
Da Silva, Angela J. ; Tang, H. Roger ; Wu, Max C. ; Hasegawa, Bruce H.
Author_Institution
Dept. of Radiol., California Univ., San Francisco, CA, USA
Volume
46
Issue
3
fYear
1999
fDate
6/1/1999 12:00:00 AM
Firstpage
659
Lastpage
666
Abstract
We have developed a new technique for compensating myocardial SPECT images for partial volume errors using co-registered X-ray CT images. The CT-derived myocardial mass defines a template that can be assigned a unit activity and mathematically projected with a realistic physical model of the radionuclide imaging process, including non-ideal collimation and incorporating an object-specific attenuation map from CT. The template projections then are reconstructed using a SPECT reconstruction algorithm to obtain a pixel-by-pixel partial-volume correction for the myocardial SPECT image. Experiments in phantoms demonstrate that this technique substantially improves the absolute quantitation of myocardial radionuclide concentration, reducing the accuracy error from approximately 50% to less than 8%. This method also can by used for correcting background effects such as “spill-in” of background counts from uptake in the liver
Keywords
cardiology; error compensation; image reconstruction; liver; medical image processing; muscle; single photon emission computed tomography; SPECT reconstruction algorithm; absolute quantitation; accuracy error; background count spill-in; background effect correction; co-registered X-ray computed tomographic images; liver uptake; mathematical projection; myocardial SPECT image compensation; myocardial activity quantification; myocardial mass; myocardial radionuclide concentration; nonideal collimation; object-specific attenuation map; partial volume errors; phantoms; pixel-by-pixel partial-volume correction; radionuclide imaging process; template projection reconstruction; unit activity; Attenuation; Collimators; Computed tomography; Image reconstruction; Imaging phantoms; Mathematical model; Myocardium; Optical imaging; Reconstruction algorithms; X-ray imaging;
fLanguage
English
Journal_Title
Nuclear Science, IEEE Transactions on
Publisher
ieee
ISSN
0018-9499
Type
jour
DOI
10.1109/23.775595
Filename
775595
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