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(Circulation. 1996;93:135-142.)
© 1996 American Heart Association, Inc.

Articles

Ranolazine Stimulates Glucose Oxidation in Normoxic, Ischemic, and Reperfused Ischemic Rat Hearts

James G. McCormack, PhD, DSC; Rick L. Barr; Andrew A. Wolff, MD; Gary D. Lopaschuk, PhD

From the Departments of Pediatrics and Pharmacology, University of Alberta, Edmonton, Canada (R.L.B., G.D.L.), Syntex Medical Research, Palo Alto, Calif (A.A.W.), and the Department of Pharmacology, Syntex Research Centre, Heriot-Watt University Research Park, Edinburgh, Scotland (J.G.M.).

Correspondence to Prof G.D. Lopaschuk, Cardiovascular Disease Research Group, Departments of Pediatrics and Pharmacology, 423 Heritage Medical Research Bldg, University of Alberta, Edmonton, T6G 2S2, Canada. E-mail glopasch@gpu.srv.ualberta.ca.

Background Ranolazine is a novel antianginal agent that may reduce symptoms without affecting hemodynamics and has shown cardiac antiischemic effects in in vivo and in vitro models. In one study it increased active pyruvate dehydrogenase (PDHa). Other agents that increase PDHa and so increase glucose and decrease fatty acid (FA) oxidation are beneficial in ischemic-reperfused hearts. Effects of ranolazine on glucose and palmitate oxidation and glycolysis were assessed in isolated rat hearts.

Methods and Results Working hearts were perfused with Krebs-Henseleit buffer plus 3% albumin under normoxic conditions and on reperfusion after 30-minute no-flow ischemia and under conditions designed to give either low [low (Ca) (1.25 mmol/L), high [FA] (1.2 mmol/L palmitate); with/without insulin] or high (2.5 mmol/L Ca, 0.4 mmol/L palmitate; with/without pacing) glucose oxidation rates; Langendorff-perfused hearts (high Ca, low FA) were subjected to varying degrees of low-flow ischemia. Glycolysis and glucose oxidation were measured with the use of [5-³H/U-¹⁴C]-glucose and FA oxidation with the use of [1-¹⁴C]- or [9,10-³H]-palmitate. In working hearts, 10 µmol/L ranolazine significantly increased glucose oxidation 1.5-fold to 3-fold under conditions in which the contribution of glucose to overall ATP production was low (low Ca, high FA, with insulin), high (high Ca, low FA, with pacing), or intermediate. In some cases, reductions in FA oxidation were seen. No substantial changes in glycolysis were noted with/without ranolazine; rates were 10-fold glucose oxidation rates, suggesting that pyruvate supply was not limiting. Insulin increased basal glucose oxidation and glycolysis but did not alter ranolazine responses. In normoxic Langendorff hearts (high Ca, low FA; 15 mL/min), all basal rates were lower compared with working hearts, but 10 µmol/L ranolazine similarly increased glucose oxidation; ranolazine also significantly increased it during flow reduction to 7, 3, and 0.5 mL/min. Ranolazine did not affect baseline contractile or hemodynamic parameters or O₂ use. In reperfused ischemic working hearts, ranolazine significantly improved functional outcome, which was associated with significant increases in glucose oxidation, a reversal of the increased FA oxidation seen in control reperfusions (versus preischemic), and a smaller but significant increase in glycolysis.

Conclusions Beneficial effects of ranolazine in cardiac ischemia/reperfusion may be due, at least in part, to a stimulation of glucose oxidation and a reduction in FA oxidation, allowing improved ATP/O₂ and reduction in the buildup of H⁺, lactate, and harmful fatty acyl intermediates.

Key Words: glucose • glycolysis • ischemia • fatty acids • reperfusion

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