Wen Tung WangBenjamin M W TsuiDavid S. LalushChiraporn TocharoenchaiEric C. FreyIEEEUniversity of VirginiaJohns Hopkins Medical InstitutionsNorth Carolina State UniversityMahidol University2018-06-212018-06-212005-10-01IEEE Transactions on Nuclear Science. Vol.52, No.5 I (2005), 1227-1235001894992-s2.0-29144504393https://repository.li.mahidol.ac.th/handle/20.500.14594/16494In201Tl/99mTc dual-isotope simultaneous-acquisition (DISA) myocardial imaging, crosstalk due to Tc photons results in significant contamination of the Tl data. The objective of this work is to seek the acquisition parameters (i.e., energy window width and center) that have the optimal tradeoff between minimizing the crosstalk and maximizing the detection efficiency. The optimization criterion was based on maximizing an ideal observer signal-to-noise ratio (SNR) for the myocardial defect detection task using single-isotope and DISA projection images acquired from a torso phantom. For single-isotope images, the optimal energy windows (width/center: 26 keV/75 keV and 28 keV/165 keV for201Tl, 30 keV/142 keV for99mTc) are wider than typical windows. For DISA imaging, the optimal windows varied with the99mTc to201Tl activity ratio and are thus likely to depend on the uptake ratio in each patient. Using the optimal ratio 2.25-2.75 (148 MBq201Tl and 333-407 MBq99mTc) with the corresponding optimal windows (22 keV/72 keV, 24 keV/167 keV, and 24 keV/140 keV) gives201Tl images with substantially increased SNRs as well as99mTc images with SNRs same as those of 370 MBq99mTc-only images. However, without the addition of crosstalk compensation, the use of the optimal activity and energy windows alone is likely not sufficient to restore the DISA Tl SNR to that of Tl-only image. © 2005 IEEE.Mahidol UniversityEnergyEngineeringArticleSCOPUS10.1109/TNS.2005.851421