Acute in vivo administration of a fish oil-containing emulsion improves post-ischemic cardiac function in n-3-depleted rats.

A novel i.v. lipid preparation (MCT:FO) containing 80% medium chain-triacylglycerols and 20% fish oil was recently developed to rapidly replenish cell membrane phospholipids with omega 3 (n-3) polyunsaturated fatty acids (PUFA). In regard of this property, we investigated the effect of a single i.v. administration of MCT:FO on the recovery of cardiac function after ischemia in control and n-3-depleted rats. Results were compared with those obtained either with a control preparation, where FO was replaced by triolein (MCT:OO), or with saline. Saline (1 ml) or lipid preparation (also 1 ml) was injected as a bolus via the left saphenous vein. After 60 min the heart was removed and perfused for 20 min in normoxic conditions according to Langendorff. Thereafter, the heart was subjected to a 20 min zero-flow normothermic ischemia, followed by 40 min reperfusion. Cardiac mechanical and metabolic functions were monitored. In control rats, the previous administration of a lipid preparation (MCT:FO or MCT:OO) versus saline improved cardiac function during aerobic reperfusion post-ischemia. N-3-depleted rats showed decreased basal cardiac function and impaired recovery following ischemia. However, the bolus injection of MCT:FO opposed the deleterious effect of long-term n-3-deficiency and, in this respect, was superior to MCT:OO over the first 20 min of reperfusion. This novel approach to rapidly correct n-3 PUFA-deficiency might be clinically relevant and offer interesting perspectives in the management of acute ischemic accidents.

Influence of the phospholipid n-6/n-3 polyunsaturated fatty acid ratio on the mitochondrial oxidative metabolism before and after myocardial ischemia.

The influence of dietary n-6 and n-3 polyunsaturated fatty acids (PUFA) on heart pump function and mitochondrial energy metabolism was investigated before and after ischemia. Weanling male Wistar rats were fed for 8 weeks a diet containing either 10% of sunflower seed oil (SSO group) or 10% of a 1:1 (w/w) mixture of fish oil and sunflower seed oil (FO group). The hearts were perfused according to the working mode for 15 min with a Krebs-Henseleit medium containing glucose (11 mM), insulin (10 IU/L) and caprylic acid (25 microM). They were then either maintained in normoxic conditions (70 min) or subjected to a global no-flow normothermic ischemia (20 min) followed by reperfusion (50 min). The aortic and coronary flows were monitored at 5-min intervals. The lactate dehydrogenase (LDH) release in the coronary effluent was evaluated in the control hearts and during ischemia/reperfusion. At the end of the perfusion, two subpopulations of mitochondria were prepared from each heart, by either mechanical or enzyme extraction (ME and EE mitochondria, respectively). The succinate dehydrogenase (SDH) activity was evaluated. Furthermore, the respiration parameters were assessed with either glutamate (20 mM) or palmitoylcarnitine (25 microM) as substrate. Substituting sunflower seed oil by fish oil in the diet provoked a large decrease in the n-6/n-3 PUFA ratio of cardiac phospholipids. The n-3 PUFA enrichment did not alter the coronary and aortic flows nor the LDH release in physiological conditions. Conversely, during post-ischemic reperfusion, the increased amount of n-3 PUFA improved the recovery of aortic flow and decreased the LDH release, without affecting significantly the coronary flow. In ME and EE mitochondria, the phospholipid n-6/n-3 PUFA ratio was similarly modified by the dietary manipulations. The analysis of total cardiac SDH activity suggested an ischemia-induced oedema, of similar magnitude in the two dietary groups. However, neither dietary manipulations nor ischemia influenced the mitochondrial extraction. Similarly, the parameters of glutamate oxidation were also unaffected. Conversely, with palmitoylcarnitine, post-ischemic reperfusion induced a decrease in both state III respiration rate and energy production which were more important in the EE mitochondria of the SSO group. These results suggest that the recovery of mitochondrial energy metabolism and myocardial pump function during reperfusion may be improved in n-3 PUFA-rich hearts. This could be related to a lower injury in n-3 PUFA-rich membranes. Since cardiac function in physiological conditions was not affected by the diet, fish oil could be considered as a beneficial factor to limit heart injury during ischemia and reperfusion.

Calcium overload increases oxidative stress in old rat gastrocnemius muscle.

In order to challenge in vivo muscle Ca2+ homeostasis and analyze consequences on mitochondrial H2O2 release (MHR) and sarcopenia, we injected Ca2+ ionophore A23187 (200 microg/kg, ip) in adult and old rats and measured gastrocnemius mass and mitochondrial Ca2+ content (MCC) using radioactive Ca2+ 48 h after injection. In a second experiment performed in old rats, we measured isocitrate dehydrogenase (ICDH) activity as an index of MCC, MHR, mitochondrial respiration, citrate synthase, COX and antioxydant enzyme activities 24 h after a 150 microg/kg injection. In adult rats, muscle mass and MCC were unchanged by A23187. In old rats, MCC increased 24 h after injection as reflected by a significant increase in ICDH activity; measured MCC tended to increase at 48 h. MHR and Mn-SOD activity were significantly increased at 24 h, and GPX activity was reduced. Muscle mass was unchanged but was negatively correlated with MCC in control and treated old rats. In conclusion, in old rats, A23187 probably induced a mitochondrial Ca2+ overload responsible for the observed increase in MHR without leading to muscle atrophy on a short term basis.

Myocardial metabolism of radioiodinated methyl-branched fatty acids.

Methylated fatty acids labeled with radioactive iodine have been proposed as a means of studying regional myocardial uptake of fatty acids in man. To investigate the methylated fatty acid that is best adapted for an assessment of uptake, we have studied the influence of the number and the position of the methyl groups of IFA intracellular metabolism; 16-iodo-2-methyl-hexadecanoic (mono-alpha), 16-iodo-2,2-methyl hexadecanoic (di-alpha), 16-iodo-3-methyl-hexadecanoic (mono-beta), and 16-iodo-3,3-methyl-hexadecanoic (di-beta) acids were injected into the coronary arteries of isolated rat hearts. Intracellular analysis shows that the degradation of mono-alpha was always lower than that of IHA and the storage was always much higher. The differences between mono-beta and IHA were similar to those observed with mono-alpha, but were much more pronounced. With the two dimethylated IFAs there was an inhibition of both oxidation and esterification which led to an accumulation of free FAs in myocardial cells. In conclusion, mono-beta, di-alpha, and di-beta are potentially suitable for studying the cellular uptake of IFA since all of them, and particularly the dimethylated IFAs, have a low oxidation rate.

Trimetazidine: in vitro influence on heart mitochondrial function.

The mechanism of action of the antianginal trimetazidine (TMZ) remains largely unknown. In cultured rat ventricular myocytes in physiologic conditions, TMZ (5 x 10(-4) M) reduced the plateau potential level, the upstroke velocity, and the spontaneous action potential rate. When the cardiomyocytes were submitted to hypoxia (150 or 240 minutes) in a glucose-free medium, treatment with TMZ largely prevented the hypoxia-induced electromechanical alterations, i.e., the decrease in plateau amplitude, in resting membrane potential, in action potential duration, in rate, and in contractility. No hypoxia-induced arrhythmia was observed in the TMZ-treated cells. Moreover, the lactate dehydrogenase leakage was significantly reduced in the TMZ-treated cardiomyocytes (-58% and -36%, after 150 and 240 minutes of hypoxia, respectively). The drug was not efficient in reducing the hypoxia-induced decrease in adenosine triphosphate (ATP) content. The cellular ATP content was slightly lower in the TMZ-treated cells in normoxic conditions and in hypoxic conditions, but only in the glucose-free medium. To investigate further the relation between TMZ and energy metabolism, the respiration parameters were measured in heart mitochondria isolated from control and TMZ-treated rats (6 mg/kg/day, 7 days) with different substrates. This treatment resulted in a slight alteration of pyruvate oxidation, which was observed in the absence and in the presence of TMZ (10(-4) M) in the respiration medium. Conversely, a potent inhibition of palmitoylcarnitine oxidation was measured when TMZ was added to the respiration medium. Neither pretreatment of the rats, nor addition of TMZ to the medium affected the oxidation of glutamate or citrate.(ABSTRACT TRUNCATED AT 250 WORDS)

Protective effects of trimetazidine on hypoxic cardiac myocytes from the rat.

The electrophysiological effects of the antianginal drug trimetazidine (TMZ) were investigated in cultured rat ventricular myocytes using a substrate-free hypoxia model of ischemia. The transmembrane potentials were recorded with glass microelectrodes and the contractions were simultaneously monitored with a video motion detector. The cardiomyocytes were treated with TMZ (1-5.10(-4) M final concentration) in the bath. The untreated and the drug-treated cells were submitted either to 150 min normoxia or to 150 min hypoxia followed by 90 min reoxygenation in the absence of oxidizable substrate. In normoxic conditions, TMZ did not affect the maximal diastolic potential (MDP) but significantly lowered the plateau potential level (OS) and decreased the upstroke velocity (Vmax) and the spontaneous action potential rate (APR). Conversely, TMZ significantly increased action potential duration at 80% repolarization (APD80). Under substrate-free hypoxia, the untreated cells displayed a progressive contractile failure and an important decrease in OS and APD. In parallel, early postdepolarizations triggering high rate spikes were observed. Prolonging oxygen depletion led to the cessation of the spontaneous electrical activity and thereafter to a gradual decrease in MDP. Near normal rhythmic action potentials and contractions resumed after reoxygenation. Comparatively, the treatment by 5.10(-4) M TMZ almost completely prevented the decrease in plateau amplitude, resting membrane potential, Vmax, APD80, and rate caused by substrate-free hypoxia. Moreover, the hypoxia-induced arrhythmias and the cessation of spontaneous electromechanical activities did not occur in the presence of TMZ (5.10(-4) M). After reoxygenation, the TMZ-treated cells exhibited a higher action potential amplitude than that of the untreated cells, although the TMZ-induced depressive effects on the spontaneous frequency and the Vmax persisted. In conclusion, this study shows that TMZ (5.10(-4) M) is efficient in protecting the isolated cardiac myocytes against the functional alterations induced by substrate-free hypoxia and led thus to a better recovery upon reoxygenation. The cytoprotective action may be linked, at least in part, to apparent ion channel blocking effects of the drug, which appeared in basal conditions at concentrations used in this study.

An increase in the redox state during reperfusion contributes to the cardioprotective effect of GIK solution.

This study aimed at determining whether glucose-insulin-potassium (GIK) solutions modify the NADH/NAD(+) ratio during postischemic reperfusion and whether their cardioprotective effect can be attributed to this change in part through reduction of the mitochondrial reactive oxygen species (ROS) production. The hearts of 72 rats were perfused with a buffer containing glucose (5.5 mM) and hexanoate (0.5 mM). They were maintained in normoxia for 30 min and then subjected to low-flow ischemia (0.5% of the preischemic coronary flow for 20 min) followed by reperfusion (45 min). From the beginning of ischemia, the perfusate was subjected to various changes: enrichment with GIK solution, enrichment with lactate (2 mM), enrichment with pyruvate (2 mM), enrichment with pyruvate (2 mM) plus ethanol (2 mM), or no change for the control group. Left ventricular developed pressure, heart rate, coronary flow, and oxygen consumption were monitored throughout. The lactate/pyruvate ratio of the coronary effluent, known to reflect the cytosolic NADH/NAD(+) ratio and the fructose-6-phosphate/dihydroxyacetone-phosphate (F6P/DHAP) ratio of the reperfused myocardium, were evaluated. Mitochondrial ROS production was also estimated. The GIK solution improved the recovery of mechanical function during reperfusion. This was associated with an enhanced cytosolic NADH/NAD(+) ratio and reduced mitochondrial ROS production. The cardioprotection was also observed when the hearts were perfused with fluids known to increase the cytosolic NADH/NAD(+) ratio (lactate, pyruvate plus ethanol) compared with the other fluids (control and pyruvate groups). The hearts with a high mechanical recovery also displayed a low F6P/DHAP ratio, suggesting that an accelerated glycolysis rate may be responsible for increased cytosolic NADH production. In conclusion, the cardioprotection induced by GIK solutions could occur through an increase in the cytosolic NADH/NAD(+) ratio, leading to a decrease in mitochondrial ROS production.

High dietary sucrose triggers hyperinsulinemia, increases myocardial beta-oxidation, reduces glycolytic flux and delays post-ischemic contractile recovery.

Although the causal relationship between insulin resistance (IR) and hypertension is not fully resolved, the importance of IR in cardiovascular dysfunction is recognized. As IR may follow excess sucrose or fructose diet, the aim of this study was to test whether dietary starch substitution with sucrose results in myocardial dysfunction in energy substrate utilization and contractility during normoxic and post-ischemic conditions. Forty-eight male Wistar rats were randomly allocated to three diets, differing only in their starch to sucrose (S) ratio (13, 2 and 0 for the Low S, Middle S and High S groups, respectively), for 3 weeks. Developed pressure and rate x pressure product (RPP) were determined in Langendorff mode-perfused hearts. After 30 min stabilization, hearts were subjected to 25 min of total normothermic global ischemia, followed by 45-min reperfusion. Oxygen consumption, beta-oxidation rate (using 1-13C hexanoate and Isotopic Ratio Mass Spectrometry of CO2 produced in the coronary effluent) and flux of non-oxidative glycolysis were also evaluated. Although fasting plasma glucose levels were not affected by increased dietary sucrose, high sucrose intake resulted in increased plasma insulin levels, without significant rise in plasma triglyceride and free fatty acid concentrations. Sucrose-rich diet reduced pre-ischemic baseline measures of heart rate, RPP and non-oxidative glycolysis. During reperfusion, post-ischemic recovery of RPP was impaired in the Middle S and High S groups, as compared to Low S, mainly due to delayed recovery of developed pressure, which by 45 min of reperfusion eventually resumed levels matching Low S. At the start of reperfusion, delayed post-ischemic recovery of contractile function was accompanied by: (i) reduced lactate production; (ii) decreased lactate to pyruvate ratio; (iii) increased beta-oxidation; and (iv) depressed metabolic efficiency. In conclusion, sucrose rich-diet increased plasma insulin levels, in intact rat, and increased cardiac beta-oxidation and coronary flow-rate, but reduced glycolytic flux and contractility during normoxic baseline function of isolated perfused hearts. Sucrose rich-diet impaired early post-ischemic recovery of isolated heart cardiac mechanical function and further augmented cardiac beta-oxidation but reduced glycolytic and lactate flux.

Effect of exogenous adenosine and monensin on glycolytic flux in isolated perfused normoxic rat hearts: role of pyruvate kinase.

We studied the effect of exogenous adenosine in isolated perfused normoxic rat hearts on glycolytic flux through pyruvate kinase (PK). We compared its effect with that of myxothiazol, an inhibitor of mitochondrial ATP production. Moreover, we tested whether an increase of membrane ionic flux with monensin is linked to a stimulation of glycolytic flux through PK. After a 20-min stabilization period adenosine, myxothiazol or monensin were administrated to the perfusate continuously at various concentrations during 10 min. The contraction was monitored and the lactate production in coronary effluents evaluated. The amount of adenine nucleotides and phosphoenolpyruvate was measured in the frozen hearts. Myxothiazol induced a decrease of the left ventricular developed pressure (LVDP : -40%) together with a stimulation of glycolytic flux secondary to PK activation. In contrast, adenosine primarily reduced heart rate (HR: -30%) with only marginal effects on LVDP. This was associated with an inhibition of glycolysis at the level of PK. The Na+ ionophore monensin affected HR (+14%) and LVDP (+25%). This effect was associated with a stimulation of glycolysis secondary to the stimulation of PK. These results provide new information of action of adenosine in the heart and support the concept of a direct coupling between glycolysis and process regulating sarcolemmal ionic fluxes.

Cellular and mitochondrial energy metabolism in the stunned myocardium.

The influence of cardiac stunning on the oxidation of fatty acids and the oxidative phosphorylation in mitochondria was investigated. Rat hearts were perfused for 15 min according to the working mode with a Krebs-Henseleit buffer containing glucose (11 mM). The hearts were then maintained in normoxic conditions (C group) or subjected to a 15-min global no-flow normothermic ischemia followed by a 30-min reperfusion (R group). Throughout the perfusion, the aortic and coronary flows, and the heart rate and oxygen consumption were monitored. At the end of the perfusion procedure, a bolus of 1-14C palmitate was injected in the coronary arterial bed to evaluate the fatty acid oxidation. Two sub-populations of mitochondria were isolated from each heart by either mechanical (ME mitochondria) or enzymic (EE mitochondria) extraction and their respiration properties were evaluated. Furthermore, the mitochondrial energy production (ATP and creatine phosphate) was assessed. During ischemia, the aortic flow was suppressed and recovered only to approximately 50% of the preischemic value during reperfusion. This mechanical stunning was associated with an important reduction of the stroke volume (-37%, p < 0.01) and a slight decrease in heart rate (-20%, p < 0.001). At the end of reperfusion, the beta-oxidation rate constituted 55 +/- 1.7% of the cell palmitate and was similar to that assessed in the C group. The oxygen consumption was decreased to 216 +/- 31.0 microL O2/min/gww and the venous O2 concentration increased to 5.1 +/- 0.572 microL O2/mL (instead of 2.9 +/- 0.342 microL O2/mL in the C group), although due to large SD, only the latter was statistically significant. A decrease in metabolic efficiency (42 +/- 14.4 vs 106 +/- 16.8 mL/microL O2 in the C group) and an increase in palmitate oxidation to oxygen consumption ratio (77 +/- 10.1 vs 47.6 +/- 4.25% beta-oxidized palmitate/microL O2 in the C group) were observed. This increased fatty acid contribution in the oxidation metabolism could be responsible for some oxygen wasting and could contribute to decrease the energy available for the contraction despite the normal cardiac oxygen uptake. Furthermore, the respiration parameters of the mitochondria were similar in the C and R groups when glutamate (20 mM) or palmitoylcarnitine (25 microM) were used as substrate. ME mitochondria of R group displayed a reduced rate of ATP production (118 +/- 29.5 vs 180 +/- 14.5 nmoles/min/mg proteins in the C group) without altered creatine phosphate production. The presence of calcium in the medium (10(-5) M) provoked a decrease in ATP production.(ABSTRACT TRUNCATED AT 400 WORDS)

Dietary n-3 polyunsaturated fatty acids and coronary heart disease-related mortality: a possible mechanism of action.

Epidemiological and interventional studies indicate that dietary n-3 PUFA reduces mortality due to coronary heart disease (CHD). They act at a low dose, since one or two meals with fatty fish per week is sufficient to provide protection when compared with no fish intake. These fatty acids are effective in providing primary prevention in low- and high-risk subjects and secondary prevention. At high doses, dietary n-3 PUFAs have several beneficial properties. First, they act favourably on blood characteristics: they are hypocholesterolemic and hypotriglyceridemic; they reduce platelet aggregation; they exhibit antithrombotic and fibrinolytic activities; they reduce blood viscosity and they exhibit antiinflammatory action. Second, they reduce ischemia/reperfusion-induced cellular damage. This effect is apparently due to the incorporation of eicosapentaenoic acid in membrane phospholipids. Third, they reduce ischemia and reperfusion arrhythmias. All the effects exerted by n-3 PUFAs at high doses are incompatible with the beneficial action on CHD mortality in humans observed at low doses, where their main properties are related to circulation in the form of free fatty acids. Numerous experimental studies have indicated that low concentrations of exogenous n-3 PUFAs reduce the severity of cardiac arrhythmias. This effect is probably responsible for the protective action of n-3 PUFA on CHD mortality. Further studies are necessary to confirm this assumption in animals. Such studies should take account of the fact that only a low dose of n-3 PUFA (20 mg/kg/day) is necessary to afford protection. Furthermore, since the beneficial effect of n-3 PUFAs on CHD mortality is observed in fish eaters versus no-fish eaters, and since populations in industrialised countries consume excess n-6 PUFAs, control animals in long-term dietary experiments should be fed a diet with only n-6 fatty acids as a source of PUFAs.

Influence of dietary linseed oil and sunflower seed oil on some mechanical and metabolic parameters of isolated working rat hearts.

The role played by membrane lipid environment on cardiac function remains poorly defined. The polyunsaturated fatty acid profile of myocardial phospholipids could be of utmost importance in the regulation of key-enzyme activities. This study was undertaken to determine whether selective incorporation of n-6 or n-3 fatty acids in membrane phospholipids might influence cardiac mechanical performances and metabolism. For 8 wk, male weaning Wistar rats were fed a semi-purified diet containing either 10% sunflower seed oil (72% C18:2 n-6) or 10% linseed oil (54% C18:3 n-3) as the sole source of lipids. The hearts were then removed and perfused according to working mode with a Krebs-Henseleit buffer containing glucose (11 mM) and insulin (10 Ul/l). Cardiac rate, coronary and aortic flows and ejection fraction were monitored after 30 min of perfusion. Myocardial metabolism was estimated by evaluating the intracellular fate of 1-14C palmitate. Sunflower seed oil and linseed oil feeding did not modify either coronary or aortic flow, which suggests that cardiac mechanical work was not affected by the diets. Conversely, cardiac rate was significantly decreased (-18%; P less than 0.01) when rats were fed the n-3 polyunsaturated fatty acid rich diet. Radioanalysis of the myocardial metabolism suggested that replacing n-6 polyunsaturated fatty acids by n-3 polyunsaturated fatty acids: i) did not alter palmitate uptake; ii) prolonged palmitate incorporation into cardiac triglycerides; iii) reduced beta-oxidation of palmitic acid. These results support the assumption that dietary fatty acids, particularly n-6 and n-3 fatty acids, play an important role in the regulation of cardiac mechanical and metabolic activity.

Fatty acid oxidation in the heart.

The heart is known for its ability to produce energy from fatty acids (FA) because of its important beta-oxidation equipment, but it can also derive energy from several other substrates including glucose, pyruvate, and lactate. The cardiac ATP store is limited and can assure only a few seconds of beating. For this reason the cardiac muscle can adapt quickly to the energy demand and may shift from a 100% FA-derived energy production (after a lipid-rich food intake) or any balanced situation (e.g., diabetes, fasting, exercise). These situations are not similar for the heart in terms of oxygen requirement because ATP production from glucose is less oxygen-consuming than from FA. The regulation pathways for these shifts, which occur in physiologic as well as pathologic conditions (ischemia-reperfusion), are not yet known, although both insulin and pyruvate dehydrogenase activation are clearly involved. It becomes of strategic importance to clarify the pathways that control these shifts to influence the oxygen requirement of the heart. Excess FA oxidation is closely related to myocardial contraction disorders characterized by increased oxygen consumption for cardiac work. Such an increased oxygen cost of cardiac contraction was observed in stunned myocardium when the contribution of FA oxidation to oxygen consumption was increased. In rats, an increase in n-3 polyunsaturated FA in heart phospholipids achieved by a fish-oil diet improved the recovery of pump activity during postischemic reperfusion. This was associated with a moderation of the ischemia-induced decrease in mitochondrial palmitoylcarnitine oxidation. In isolated mitochondria at calcium concentrations close to that reported in ischemic cardiomyocytes, a futile cycle of oxygen wastage was reported, associated with energy wasting (constant AMP production). This occurs with palmitoylcarnitine as substrate but not with pyruvate or citrate. The energy wasting can be abolished by CoA-SH and other compounds, but not the oxygen wasting. Again, the calcium-induced decrease in mitochondrial ADP/O ratio was reduced by increasing the n-3 polyunsaturated FA in the mitochondrial phospholipids. These data suggest that in addition to the amount of circulating lipids, the quality of FA intake may contribute to heart energy regulation through the phospholipid composition. On the other hand, other intervention strategies can be considered. Several studies have focused on palmitoylcarnitine transferase I to achieve a reduction in beta-oxidation. In a different context, trimetazidine was suggested to exert its anti-ischemic effect on the heart by interfering with the metabolic shift, either at the pyruvate dehydrogenase level or by reducing the beta-oxidation. Further studies will be required to elucidate the complex system of heart energy regulation and the mechanism of action of potentially efficient molecules.

Effects of L-propionylcarnitine on mechanical recovery during reflow in intact hearts.

We tested the influence of L-propionylcarnitine (LPC) in modifying mechanical stunning during reflow. Nineteen adolescent anesthetized swine were extracorporeally perfused at control coronary flows for 20 min, supplemented with excess fatty acids (average values 1.1 +/- 0.1 mumol/ml), and subjected to 45 min regional ischemia (-60 delta % decrease in anterior descending flow) followed by 35 min reperfusion. Responses in 10 placebo hearts were compared with those obtained from 9 animals treated with 50 mg/kg LPC at 0 min perfusion and 40 mg/kg at 40 min perfusion. Ischemia in placebo hearts caused a 62.6 delta % decrease in active shortening in anterior descending bed, which failed to recover (-41.4 delta % from control values) during reflow. Conversely, in LPC-treated hearts, decreases in active shortening (-38.6 and -11.6 delta %) during ischemia and reflow, respectively, were significantly smaller (P less than or equal to 0.05). This improved motion was associated with greater rates of myocardial oxygen consumption but similar levels of fatty acid oxidation and fatty acid intermediates. Thus LPC significantly reversed mechanical stunning in myocardial ischemia/reperfusion protocols, presumably because of its positive inotropic properties. This derivative, otherwise innocuous in nature, could represent an attractive new treatment choice for future clinical use.

Influence of phospholipid polyunsatured fatty acid composition on some metabolic disorders induced in rat cardiomyocytes by hypoxia and reoxygenation.

The influence of membrane polyunsaturated fatty acid (PUFA) composition on lactate production, energy status, enzyme leakage and cell defences against oxygen free radical production was studied in cultured rat ventricular myocytes during hypoxia and reoxygenation. After 4 days in a conventional serum-supplemented medium, the cardiomyocytes were incubated for 24 h in synthetic media containing either linoleate and arachidonate (SM6 Medium) or linolenate and eicosapentaenoate (SM3 Medium) as unique source of PUFA. The fatty acid n-6/n-3 ratio of phospholipid was 13.1 in SM6 cells and 0.9 in SM3 cells. Hypoxia induced an increase in lactate production, severe decreases in ATP and ADP, leakage of cellular lactate dehydrogenase and reduction of superoxide dismutase and glutathione peroxidase activities. Reoxygenation of hypoxic cells reduced lactate production to normal aerobic values and allowed slight resynthesis of ATP from AMP. However, lactate dehydrogenase release was not stopped by reoxygenation, and decreases in superoxide dismutase and glutathione peroxidase activities were not avoided. The majority of the biochemical parameters measured during normoxia, hypoxia and reoxygenation were not significantly affected by changes in the fatty acid composition of membrane phospholipids, except for reduced superoxide dismutase activity which appeared earlier in SM3 cells during hypoxia. We conclude that the sarcolemmal PUFA composition of cultured rat ventricular myocytes does not significantly influence altered cell metabolism elicited by hypoxia and reoxygenation.

Some biochemical aspects of the protective effect of trimetazidine on rat cardiomyocytes during hypoxia and reoxygenation.

This study was undertaken to evaluate the direct cardioprotective effect of trimetazidine (TMZ), an anti-anginal drug devoid of haemodynamic action, on isolated myocytes. Cultured rat ventricular myocytes were treated with the drug 16 h and 1 h before the experiments. The drug-treated cells and control cells were placed in a substrate free medium and submitted in a specially designed device to either normoxia (N4), or hypoxia (150 min, H2.5, or 240 min, H4), or 150 min hypoxia followed by 90 min reoxygenation (HR). The treatment of the cells with TMZ (5 x 10(-4) M) resulted in a significant decrease of lactate dehydrogenase (LDH) leakage (-58% in H2.5, -36% in H4 and -37% in HR). The LDH release provoked by oxidizing agents. H2O2 and 13-s-HpOTrE (13(S)-hydroperoxyoctadecatrienoic acid) during post-hypoxic reoxygenation was also lowered by TMZ. However, this effect reflected the beneficial action of TMZ during hypoxia since the drug was not efficient in altering the LDH leakage induced by the oxidizing agents in normal conditions. Moreover, the hypoxia-induced decrease of ATP content was not affected by TMZ, and resynthesis of ATP during substrate-free reoxygenation was similar in TMZ-treated and control cells. The respiration parameters have been studied in rat heart mitochondria isolated from control and TMZ-treated rats, in the presence or absence of TMZ in the respiration medium (10(-4) M). The main result was a rapid and potent inhibition of palmitoylcarnitine oxidation, when TMZ was added to the respiration medium. The chronic treatment only resulted in a slight alteration of pyruvate oxidation. In conclusion, a pre-treatment of ventricular myocytes with TMZ resulted in an increased cell resistance to hypoxic stress, as evidenced by LDH leakage. This cytoprotective effect of TMZ should not be mediated through an antioxidant activity, but could be related to a modification of lipid metabolism.

Changes in substrate metabolism and effects of excess fatty acids in reperfused myocardium.

The purpose of these studies was to characterize the rates of fatty acid oxidation in reperfused myocardium and test the influence of excess fatty acids (FA) on mechanical function in the extracorporeally perfused, working swine heart model. Seventeen animals were prepared. Eight were untreated (LOW FA group; serum FA averaged 0.55 +/- 0.07 mumol/ml) and nine received a constant infusion of 10% Intralipid with heparin to raise serum FA to about 1.4 +/- 0.21 mumol/ml (HIGH FA group). Coronary flow in both groups was held at aerobic levels for an equilibrium period of 40 minutes, acutely reduced regionally in the anterior descending circulation by 60% for 45 minutes, and acutely restored to aerobic levels for 60-minute reflow. Appreciable mechanical depression (-47 delta% from aerobic values; p less than 0.01) during reperfusion was noted in both groups. This was associated with modest reductions in myocardial oxygen consumption (p less than 0.05) and losses of total tissue carnitine stores (p at least less than 0.02). Reperfused myocardium showed a strong preference for and aerobic use of FA during reflow such that 14CO2 production from labeled palmitate exceeded preischemic levels (+89 delta% in LOW FA hearts; +111 delta% in HIGH FA hearts). This suggested relative preservation of restoration of certain elements in mitochondrial function during reflow. The findings argue for uncoupling between substrate metabolism and energy production, accelerated but useless energy drainage, or some impairment between energy transfer and function of contractile proteins as possible explanations for the persistent depression of mechanical function (stunning) during reperfusion.(ABSTRACT TRUNCATED AT 250 WORDS)

Myocardial ischemia and in vitro mitochondrial metabolic efficiency.

The purpose of this study was to evaluate the oxidative capacities and the rate of energy synthesis in isolated mitochondria extracted from normal and post-ischemic myocardium. Isolated rat hearts were perfused according to the working mode with a Krebs Heinseleit buffer containing glucose (11 mM), insulin (10 IU/l) and caprylic acid (25 microM). After a 15 min perfusion in normoxic conditions, the hearts were subjected to a 20 min local zero-flow ischemia followed by a 20 min reperfusion. During the perfusion, the aortic and coronary flows, the aortic pressure and the electrocardiogram were monitored. At the end of the reperfusion period, the non-ischemic and ischemic zones (NIZ and IZ, respectively) were separated and the mitochondria were harvested from each zone. The oxygen uptake and the rate of energy production of the NIZ and IZ mitochondria were then assessed with palmitoylcarnitine as substrate in 2 buffers differing in their free calcium concentration (0.041 and 0.150 microM). Ischemia provoked a 50% reduction of coronary and aortic flows. The reperfusion of the IZ allowed the partial recovery of coronary flow, but the aortic flow decreased beneath its ischemic value because of the occurrence of severe arrhythmias, stunning and probably hibernation. The IZ mitochondria displayed a lower rate of oxygen consumption, whatever the buffer free calcium concentration. Conversely, their rate of energy production was increased, indicating that their metabolic efficiency was improved as compared to NIZ mitochondria. This might be due to the mitochondrial calcium overload persisting during reperfusion, to the activation of the inner membrane Na+/Ca2+ exchange and to a significant mitochondrial swelling. On the other hand, the presence of an elevated free calcium concentration in the respiration buffer provoked some energy wasting characterized by a constant AMP production. This was attributed to some accumulation of acetate and the activation of the energy-consuming acetylCoA synthetase. In conclusion, ischemia and reperfusion did not alter the membrane integrity of the mitochondria but improved their metabolic efficiency. Nevertheless, these in vitro results can not reflect the mitochondrial function in the reperfused myocardium. The mitochondrial calcium overload reported to last during reperfusion in the cardiomyocytes might mimic the free calcium-induced reduction of metabolic efficiency observed in vitro in the present study. The resulting energy wasting might be responsible for the contractile abnormalities noticed in the reperfused myocardium.

Effect of dietary polyunsaturated fatty acids on contractile function of hearts isolated from sedentary and trained rats.

Moderate physical training induced a decrease in arterial blood pressure in fish oil-fed rats as compared to sunflower seed oil-fed rats. The purpose of this study was to determine if these changes were due to modifications of the left ventricular function of the heart. Forty rats were fed a semi-purified diet containing either 10% sunflower seed oil or 10% fish oil (EPAX 3000TG, Pronova). Each dietary group was assigned to two sub-groups, one being constituted by sedentary animals and the other by trained animals. Training was achieved by daily running for 60 minutes at moderate intensity for three weeks. At the end of the training period, the animals were sacrificed and their hearts were immediately perfused according to the working mode. The phospholipid fatty acid composition and parameters of the left ventricular function were determined. Feeding fish oil markedly reduced the proportion of n-6 polyunsaturated fatty acids (PUFA, 18:2 n-6, 20:4 n-6, 22:4 n-6 and 22:5 n-6) in cardiac phospholipids. The n-6 PUFA were replaced by n-3 PUFA (mainly docosahexaenoic acid). In sedentary animals, the fluid dynamic (aortic and coronary flow, cardiac output) was not modified by the diet. The heart rate was reduced (-10%) in n-3 PUFA-rich hearts. Physical training did not markedly alter the polyunsaturated fatty acid profile of cardiac phospholipids. Conversely, it reduced the heart rate, aortic flow and cardiac output (-11, -21 and -14%, respectively) at a similar extent in the two dietary groups. In a second set of experiments, the training period was repeated in animals fed a commercially available diet (A103, UAR) which simultaneously provided n-6 and n-3 fatty acids. In these dietary conditions, neither the aortic flow nor the heart rate was decreased by physical exercise. These results suggest that both n-6 and n-3 PUFA in the diet are necessary to ensure a good cardiac adaptation to moderate physical training. Furthermore, the fish oil-induced decrease in arterial blood pressure in trained animals was not related to changes in cardiac contractility, but to a decrease in vascular resistances. Moderate physical training + dietary n-3 PUFA might be used to prevent hypertension and cardiovascular diseases.

Individual effects of dietary EPA and DHA on the functioning of the isolated working rat heart.

The aim of this study was to evaluate the effects of dietary pure eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA) on the physiology of the heart in normoxic conditions and during postischemic reperfusion. These effects were compared with those of dietary n-6 polyunsaturated fatty acids (PUFA). Rats were fed a diet containing either sunflower seed oil (75 g x kg(-1), SSO group), or a mixture of EPA (20:5 n-3) ethyl ester and SSO (10:90, EPA group), or a mixture of DHA (22:6 n-3) ethyl ester and SSO (10:90, DHA group), or a mixture of EPA + DHA ethyl esters and SSO (4.2:5.8:90, e+D group) for 6 weeks. The hearts were then perfused according to the working mode. The perfusion was maintained either in normoxic conditions or stopped for 17 min (global zero-flow ischemia) and restored for 33 min (reperfusion). The aortic and coronary flows, aortic developed pressure, and electrocardiogram were continuously monitored. When rats were fed a diet containing either EPA and (or) DHA, the n-6/n-3 PUFA ratio of cardiac phospholipids decreased. The proportion of arachidonic acid was reduced more with DHA than dietary EPA. In the EPA group, the percentage of DHA was lower than in the DHA group, but the percentage of EPA and docosapentaenoic acid (22:5 n-3) was higher. These changes in membrane fatty acid composition altered the cardiac function. In normoxic conditions, the coronary flow was higher in the SSO group than in the DHA and EPA groups. The heart rate was lower in the DHA and e+D groups than in the EPA and SSO groups. The aortic flow, cardiac output, and aortic developed pressure were not affected. During postischemic reperfusion, the recovery of aortic flow, coronary flow, and aortic developed pressure was similar in the four groups. A slightly improved recovery of cardiac function was noticed in the EPA group, but the difference was not significant. Feeding rats 5% fish oil + 5% SSO instead of 10% SSO for 8 weeks increased the incorporation of EPA in cardiac phospholipids and favored the recovery (+120%) of aortic flow during postischemic reperfusion. In conclusion, the beneficial effect of dietary fish oil on the recovery of cardiac pump activity during reperfusion was not observed with DHA or EPA alone. It appears to be positively related to the accumulation of EPA in membrane phospholipids. The dietary conditions favouring EPA accumulation remain to be determined.