EVALUATION OF COPPER(II)-PYRUVALDEHYDE BIS (N-4-METHYLTHIOSEMICARBAZONE) FOR TISSUE BLOOD-FLOW MEASUREMENT USING A TRAPPED TRACER MODEL

Copper(II)-pyruvaldehyde bis (N-4-methylthiosemicarbazone) (Cu-PTSM) l abelled with Cu-62,Cu-64 is a promising radiotracer for the study of b lood flow using positron emission tomography (PET). We have investigat ed the application of a simple trapped tracer model to measurements of tissue Cu-64-PTSM uptake combined with continuous arterial sampling. A dual-tracer method was used to compare blood flow estimated by Cu-64 -PTSM with values derived from measurements using cobalt-57 microspher es in the rat. Prolonged retention of Cu-64-PTSM following intravenous administration was initially confirmed in both normal tissues and tum ours. After intraventricular Cu-64-PTSM infusion, cumulative arterial (CU)-C-64 activity increased progressively, and after extraction in 12 -octanol was found to plateau to levels corresponding with those reach ed following administration of Co-57 microspheres. Rapid and species-d ependent rates of Cu-64-PTSM decomposition to non-extractable (CU)-C-6 4 complexes were found in rat and human blood in vitro (70%+/-6% and 4 3%+/-5% respectively at 16 min), demonstrating the need for immediate processing of arterial samples. Close agreement was found between bloo d flow estimated by Cu-64-PTSM and Co-57 microsphere methods in tissue s of low to moderate flow: muscle (0.01, 0.08, 0.07 ml/min per gram; m ean difference, mean (CU)-C-64, mean Co-57), brain (0.09, 0.52, 0.43 m l/min per gram) and kidney (-0.16, 2.29, 2.45 ml/min per gram). Estima tes of cardiac output also compared favourably between the two methods (5.7, 59.8, 54.1 ml/min). We conclude that a simple tissue trapping m odel may be suitable for the derivation of blood flow estimates using (CU)-C-62,64-PTSM, PET imaging and continuous arterial blood sampling.