Radiology and Imaging, Oncology Nursing & Cancer Care

Biography

Biography: Gregory G Passmore

Abstract

Gamma camera imaging of myocardium perfusion with either Tl-201 or Tc-99 m is dependent upon maintaining usable geometry between the detector and the view of the patient through the use of an attached lead (Pb) collimator. Both radioisotopes can indicate the perfusion characteristics of the myocardium. However, only Tl-201 has the capability to indicate if the cardiac tissue retains its viability, or if it is scarred. Current dual-isotope myocardial single-photon emission computed tomography (SPECT) imaging protocols require two scans. Simultaneous imaging of Tl-201 and Tc-99m would have the benefits of optimal perfusion imaging and tissue viability signaling, eliminating potential errors caused by position misalignment between scans, and significantly reducing study time. This would further enhance the diagnostic ability of the modality, especially for those patients contraindicated for other functional imaging. However, the 99mTc Compton down-scatter components and K-shell X-rays from the Pb collimator interfere with imaging the ~70-80 keV 201Tl photons. This cross-talk reduces image resolution and obscures 201Tl defects, falsely indicating viable myocardium. This project suggested replacing the Pb collimator with one of higher density tungsten (W) to reduce the 99mTc cross-talk photons in the 201Tl photo peak range by decreasing the down-scatter component through increased absorption and shifting the k-shell x-ray out of the 201Tl photo peak. The aim of the project was to test the ability of a W pinhole attenuator in reducing the detrimental effects of Pb generated cross-talk during simultaneous dual-isotope201Tl/99mTc imaging. Outcomes indicate a significant reduction in down-scatter cross-talk using W attenuators compared to Pb attenuators.