FATTY-ACID OXIDATION AND CARDIAC-FUNCTION IN THE SODIUM PIVALATE MODEL OF SECONDARY CARNITINE DEFICIENCY

Carnitine-deficiency syndromes are often associated with alterations in lipid metabolism and cardiac function. The present study was designed to determine whether this is also seen in an experimental model of carnitine deficiency. Carnitine deficiency was induced in male Sprague-Dawley rats supplemented with sodium pivalate for 26 to 28 weeks. This treatment resulted in nearly a 60% depletion of myocardial total carnitine content as compared with control hearts. When isolated working hearts from these animals were perfused with 5.5 mmol/L glucose and 1.2 mmol/L palmitate and subjected to incremental increases in left-atrial filling pressures, cardiac function remained dramatically depressed. The effects of carnitine deficiency on glucose and palmitate utilization were also assessed in hearts perfused at increased workload conditions. At this workload, function was depressed in carnitine-deficient hearts, as were rates of 1.2-mmol/L [U-C-14]-palmitate oxidation, when compared with control hearts (544 +/- 37 v 882 +/- 87 nmol/g dry weight min, P < .05). However, glucose oxidation rates from 5.5 mmol/L [U-C-14] glucose were slightly increased in carnitine-deficient hearts. To determine whether the depressed fatty acid oxidation rates were a result of reduced mechanical function in carnitine-deficient hearts, the workload of hearts was reduced. Under these conditions, mechanical function was similar among control and carnitine-deficient hearts. Palmitate oxidation rates were also similar in these hearts (526 +/- 69 v 404 +/- 47 nmol/g dry weight min for control and carnitine-deficient hearts, respectively). Our results show that work performed by hearts from carnitine-deficient animals is rate-limiting in the oxidation of palmitate. Despite this, our findings suggest that the sodium pivalate model of carnitine deficiency may prove to be useful for the investigation of functional and metabolic aspects of carnitine deficiency. Copyright (C) 1995 by W.B. Saunders Company