Very rapid lactate measurement in ischemic perfused hearts using1H MRS continuous negative echo acquisition during steady-state frequency selective excitation

Abstract

Using ¹H MRS continuous negative echo acquisition during steady-state frequency selective excitation (CASTLE) myocardial lactate accumulation was followed in a globally ischemic perfused rat heart model. ¹H MRS CASTLE derived lactate determinations were verified biochemically and were measured during ischemia and reperfusion (both in the absence and in the presence of a known inhibitor of glycolysis). In addition, using the Bloch equations modified for the effect of diffusion in the presence of a magnetic field gradient the theoretical dependency of measurements made with CASTLE upon T₁ T₂ and the flip angle α were demonstrated. It was found that ¹H MRS CASTLE allowed for rapid identification of the lactate -CH₃ resonance in an isolated perfused heart with little shimming required, and excellent water and lipid suppression. Measurements of lactate using this technique reflected a true difference in myocardial lactate as evidenced by biochemical analysis and the expected changes in tissue lactate that accompanied reperfusion and ischemia in the presence of a glycolytic inhibitor. Theoretical calculations demonstrated that the dependency of the relative signal intensity obtained with ¹H MRS CASTLE was a complex function of T₁ T₂, and α These calculations also demonstrated the theoretical feasibility of applying ¹H MRS CASTLE to localized spectroscopy using a surface coil. © 1988 Academic Press, Inc.