Spatial heterogeneity of energy turnover in the heart

Local myocardial blood flow varies substantially in spite of a;ather homogeneous morphology. To further elucidate this paradox, the spatial heterogeneity of tricarboxylic acid cycle turnover (J(TCA), mu mol min(-1) g(-1)) and coronary flow was assessed at a high spatial resolution (6x6x6 mm(3)) in the open chest dog. Local flow differed more than 2.5-fold between individual samples in each heart (n=7). Out of 1500 myocardial samples, 1/10 received less than 60% and another 1/10 more than 138% of the normalized mean. In low- and high-flow samples, pyruvate uptake and metabolism were analyzed by C-13 NMR spectroscopy. Following [3-C-13]pyruvate infusion (2 mM, 12 min), glutamate [4-C-13]/[3-13C] was significantly greater in low-flow (2.21+/-0.75, 40 samples) than in high-flow (1.6+/-0.49, 39 samples) areas. This suggests that there are major differences in J(TCA) Glutamate, citrate and lactate content positively correlated with flow. Anaplerotic pathways contributed a fraction similar to J(TCA) in low- and high flow areas, as demonstrated by isotopomer analysis after 60 min of [3-C-13]pyruvate application. Mathematical model analysis of NMR data and relevant pool sizes revealed that J(TCA) and thus myocardial oxygen consumption (MVO2) in high-flow areas exceed values in low-flow areas at least threefold, Thus low and high metabolic states normally coexist within the well perfused heart, suggesting that there is considerable spatial heterogeneity of cardiac energy generation and work.