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Circulation, Vol 79, 134-142, Copyright © 1989 by American Heart Association
DB Buxton, CA Nienaber, A Luxen, O Ratib, H Hansen, ME Phelps and HR Schelbert
The usefulness of [1-11C]acetate as a tracer of overall myocardial
oxidative metabolism for use with positron emission tomography has been
investigated in 12 closed-chest dogs. Myocardial 11C activity clearance
kinetics after intravenous administration of [1-11C]acetate in dogs have
been determined noninvasively by positron emission tomography.
Biexponential fitting of regional myocardial 11C time-activity curves was
performed to give clearance half-times and fractional distribution. The
rate constant k1 for the early rapid phase of 11C activity clearance was
found to correlate linearly with myocardial oxygen consumption (y = 0.0156x
+ 0.039; SEE = 0.023; r = 0.95). k1 was approximately 7% lower in septal
sectors compared with the left ventricular free wall, suggesting that
regional oxygen consumption in the septum was lower; a concomitant regional
attenuation of blood flow in the septum relative to the left ventricular
free wall was also observed. In dogs using carbohydrates as the predominant
fuel, k1 oxygen consumption was somewhat more than in dogs using
predominantly free fatty acids (0.021 +/- 0.002 compared with 0.018 +/-
0.002, p less than 0.01), indicating that increased carbohydrate
consumption is associated with a small increase in k1 at constant oxygen
consumption. It is concluded that measurement of myocardial [1-11C]acetate
kinetics allows noninvasive determination of cardiac oxygen consumption by
positron emission tomography and that the technique is relatively
insensitive to myocardial fuel selection.
ARTICLES
Noninvasive quantitation of regional myocardial oxygen consumption in vivo with [1-11C]acetate and dynamic positron emission tomography
Department of Radiological Sciences, UCLA School of Medicine 90024.
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