Myocardial Perfusion with Rubidium-82. I. Measurement of Extraction Fraction and Flow with External Detectors

Myocardial Perfusion with Rubidium-82. I. Measurement of Extraction Fraction and Flow with External Detectors

Nizar A. Mullani, Richard A. Goldstein, K. Lance Gould, Salma K. Marani, David J. Fisher, Harold A. O'Brien, Jr. and Michael D. Loberg

University of Texas Medical School, and Graduate School of Biomedical Sciences, Houston, Texas
Los Alamos National Laboratory, Los Alamos, New Mexico
E. R. Squibb and Sons

Correspondence: For reprints contact: Nizar A. Mullani, Div. of Cardiology, University of Texas Medical School, 6431 Fannin, Houston, TX 77025.

ABSTRACT

Accurate measurement of the regional extraction of a diffusibleradiopharmaceutical is essential for the quantifying of regionalblood flow, and may also provide an important physiologic ordiagnostic indicator of the cellular viability of an organ inman through external detection by positron emission tomography.However, extraction fraction of a diffusible tracer usuallydecreases as flow increases, and thus noninvasive methods formeasuring flow are nonlinear unless the extraction fractioncan be measured independently. This report describes the theoreticalbasis and documents the applicability of this theory for determining,with external detectors, the first-pass regional extractionfraction of rubidium-82 by the heart, following a single intravenousbolus injection of the tracer. Measurement of extraction fractionwas found to be independent of flow, thereby making it possibleto determine accurately with a single intravenous bolus injectionof rubidium-82, the regional blood flow in the myocardium atup to five times normal resting flow.

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