Microdialysis-based analysis of interstitial NO in situ: NO synthase-independent NO formation during myocardial ischemia.

OBJECTIVES: Nitric oxide (NO) synthesis by NO synthases (NOS) requires oxygen. However, although counterintuitive, NO synthesis is increased in ischemic myocardium. Accordingly, mechanisms independent of the NOS pathway have been suggested to contribute to NO synthesis during ischemia. NO initiates detrimental as well as protective mechanisms in a concentration-dependent manner, thus aggravating or improving the outcome of ischemia. The aim of this study was to measure in situ interstitial NO concentrations in parallel to infarct size in anaesthetized pigs subjected to myocardial ischemia/reperfusion. The contribution of NOS-independent pathways to NO synthesis was studied using NOS blockade. METHODS: Interstitial NO measurements, based on microdialysis combined with the oxyhemoglobin method, were made during 90 min of moderate or severe ischemia and subsequent reperfusion. To examine the effect of NOS inhibition, an initial 30-min ischemic period was followed 60 min later by a second 30-min ischemic period with intracoronary infusion of S-ethyl-isothiourea. RESULTS: During ischemia, the interstitial NO concentration increased for about 30 min and then remained constant at this elevated level. The increase in NO concentration by 253+/-82 nmol/L during moderate and 565+/-169 nmol/L during severe ischemia correlated inversely with subendocardial blood flow (r=-0.76). NOS inhibition increased coronary arterial pressure and decreased the interstitial basal NO concentration and tissue nitrite content. However, it did not diminish the increase in interstitial NO concentration during ischemia. CONCLUSION: NOS-independent pathways are significantly involved in NO synthesis during myocardial ischemia.

Inhibition of Na+/H+-exchanger with sabiporide attenuates the downregulation and uncoupling of the myocardial beta-adrenoceptor system in failing rabbit hearts.

Chronic heart failure (HF) is characterized by left ventricular (LV) structural remodeling, impaired function, increased circulating noradrenaline (NA) levels and impaired responsiveness of the myocardial beta-adrenoceptor (betaAR)-adenylyl cyclase (AC) system. In failing hearts, inhibition of the sodium/proton-exchanger (NHE)-1 attenuates LV remodeling and improves LV function. The mechanism(s) involved in these cardioprotective effects remain(s) unclear, but might involve effects on the impaired betaAR-AC system. Therefore, we investigated whether NHE-1 inhibition with sabiporide (SABI; 30 mg kg(-1) day(-1) p.o.) might affect myocardial betaAR density and AC activity in relation to changes in LV end-diastolic diameter (LVEDD) and LV systolic fractional shortening (LVS-FS) after 3 weeks of rapid LV pacing in rabbits. After 3 weeks of rapid LV pacing LVEDD was significantly increased (Shams 17+/-0.2 mm, n=9 vs 3 wksHF 20+/-0.5 mm, n=8; P<0.05) and LVS-FS decreased (Shams 31+/-1%, n=9 vs 3 wksHF 10+/-1%, n=8; P<0.05). SABI treatment significantly improved LV function independent of whether rabbits were treated after 1 week of pacing (3 wksHF+2 wksSABI (n=7): LVEDD 18+/-1 mm; LVS-FS 16+/-4%) or before pacing (3 wksHF+3wksSABI (n=9): LVEDD 18+/-1 mm; LVS-FS 18+/-6%). After 3 weeks of rapid LV pacing, SABI treatment significantly attenuated increases in serum NA content (Shams 0.83+/-0.19, 3 wksHF 2.68+/-0.38, 3 wksHF+2 wksSABI 1.22+/-0.32, 3 wksHF+3wksSABI 1.38+/-0.33 ng ml(-1)). Moreover, betaAR density (Shams 64+/-5, 3 wksHF 38+/-3, 3 wksHF+2 wksSABI 48+/-4, 3 wksHF+3 wksSABI 55+/-3 fmol mg(-1) protein) and responsiveness (isoprenaline-stimulated AC activity. (Shams 57.6+/-4.9, 3 wksHF 36.3+/-6.0, 3 wksHF+2 wksSABI 56.9+/-6.0, 3 wksHF+3 wksSABI 54.5+/-4.8 pmol cyclic AMP mg(-1) protein(-1) min(-1)) were significantly improved in SABI-treated rabbits. From the present data we cannot address whether the improved betaAR-AC system permitted improved LV function and/or whether the improved LV function resulted in less activation of the sympathetic nervous system and by this in a reduced stimulation of the betaAR-AC system. Accordingly, additional studies are needed to fully establish the cause-and-effect relationship between NHE-1 inhibition and the restoration of the myocardial betaAR system.

Preinfarction angina: no interference of coronary microembolization with acute ischemic preconditioning.

Transient episodes of angina preceding acute myocardial infarction may both, protect the myocardium by ischemic preconditioning or damage it when associated with coronary microembolization. We now studied the potential loss of ischemic preconditioning with coronary microembolization. Anesthetized pigs (group 1; n=8) were subjected to 90 min sustained low-flow ischemia. Group 2 (n=8) was subjected to coronary microembolization (i.e. microspheres; 42 microm slashed circle; 3000 per ml min-1 inflow) 35 min before sustained ischemia. In group 3, coronary microembolization was followed 10 min later by one cycle of ischemic preconditioning (10 min ischemia/15 min reperfusion) before subsequent sustained ischemia. Infarct size was determined after 2 h reperfusion by triphenyl tetrazolium chloride staining. Infarct size after sustained ischemia alone (group 1) was 19.4+/-3.4% of the area at risk (mean+/-S.E.M.). With coronary microembolization before sustained ischemia (group 2) infarct size was only slightly larger (23.6+/-4.6%, ns). In group 3 with microembolization followed by ischemic preconditioning, infarct size was reduced to 12.7+/-3.0% (P<0.05 vs. group 2). The relationships between infarct size and transmural blood flow in groups 1 and 3 were not different, giving the impression that ischemic preconditioning failed to protect microembolized myocardium. However, additional coronary microembolization shifted the relationship between infarct size and blood flow upwards to a larger infarct size at any given blood flow. Thus when comparing the relationship of group 3 to its true control (group 2), it was shifted downwards (P<0.05; analysis of covariance (ANCOVA)) indicating persistent protection of microembolized myocardium by ischemic preconditioning. Coronary microembolization induces additional infarction when superimposed on sustained ischemia but does not interfere with the endogenous protection by ischemic preconditioning.

Coronary microembolization does not induce acute preconditioning against infarction in pigs-the role of adenosine.

OBJECTIVE: After coronary microembolization (ME) adenosine is released from ischemic areas of the microembolized myocardium. This adenosine dilates vessels in adjacent nonembolized myocardium and increases coronary blood flow. For ischemic preconditioning (IP) to protect the myocardium against infarction, an increase in the interstitial adenosine concentration (iADO) prior to the subsequent ischemia/reperfusion is necessary. We hypothesized that the adenosine release after ME is sufficient to increase iADO and protect the myocardium against infarction from subsequent ischemia/reperfusion. We have therefore compared myocardial protection by either coronary microembolization or ischemic preconditioning prior to ischemia/reperfusion. METHODS: In anesthetized pigs, the left anterior descending (LAD) was cannulated and perfused from an extracorporeal circuit. In 11 pigs, sustained ischemia was induced by 85% inflow reduction for 90 min (controls). Two other groups of pigs were subjected either to IP (n = 8; 10-min ischemia/15-min reperfusion) or coronary ME (n = 9; i.c. microspheres; 42 microm Ø; 3000 x ml(-1) x min inflow) prior to sustained ischemia. Coronary venous adenosine concentration (vADO) and iADO (microdialysis) were measured. Infarct size was determined after 2-h reperfusion by triphenyl tetrazolium chloride staining. RESULTS: In pigs subjected to IP, infarct size was reduced to 2.6 +/- 1.1% (mean +/- S.E.M.) vs. 17.0 +/- 3.2% in controls. iADO was increased from 2.4 +/- 1.3 to 13.1 +/- 5.8 micromol x l(-1) during the reperfusion following IP. In pigs subjected to ME, at 10 min after ME, coronary blood flow (38.6 +/- 3.6 to 53.6 +/- 4.3 ml x min(-1)) and vADO (0.25 +/- 0.04 to 0.48 +/- 0.07 micromol x l(-1)) were increased. However, iADO (2.0 +/- 0.5 at baseline vs. 2.3 +/- 0.6 micromol x l(-1) at 10 min after ME) did not increase. Infarct size induced by sustained ischemia following ME (22.5 +/- 5.2%) was above that of controls for any given subendocardial blood flow. CONCLUSION: ME released adenosine into the vasculature and increased coronary blood flow. The failure of iADO to increase with ME possibly explains the lack of protection against infarction after ME.

Serum but not myocardial TNF-alpha concentration is increased in pacing-induced heart failure in rabbits.

In animals and patients with severe heart failure (HF), the serum tumor necrosis factor-alpha (TNF-alpha) concentration is increased. It is, however, still controversial whether or not such increased serum TNF-alpha originates from the heart itself or is of peripheral origin secondary to gastrointestinal congestion and increased endotoxin concentration. We therefore now examined TNF-alpha in serum, myocardium, and liver of sham-operated and HF rabbits. In nine rabbits in which HF was induced by left ventricular (LV) pacing at 400 beats/min for 3 wk, LV end-diastolic diameter was increased and systolic shortening fraction (9.4 +/- 1.0 vs. 28.5 +/- 1.3%, echocardiography, P < 0.05) was reduced. Serum TNF-alpha was higher in HF than in sham-operated rabbits (240 +/- 24 vs. 150 +/- 22 U/ml, WEHI-cell assay, P < 0.05). In the heart, TNF-alpha was located mainly in the vascular endothelium (immunohistochemistry), and TNF-alpha protein (920 +/- 160 vs. 900 +/- 95 U/g) did not differ between groups. In the liver of HF rabbits, hepatocytes expressed TNF-alpha, and TNF-alpha protein was increased compared with sham-operated rabbits (2,390 +/- 310 vs. 1,220 +/- 135 U/g, P < 0.05) and correlated to the number of hepatic leukocytes (r = 0.85) and serum TNF-alpha (r = 0.69). The intestinal endotoxin concentration was 24.5 +/- 1.2 vs. 17.0 +/- 3.1 endotoxin units/g wet wt (P < 0.05) in HF compared with sham-operated rabbits. In this HF model, serum but not myocardial TNF-alpha is increased. The increased serum TNF-alpha originates from peripheral sources.

Effect of NO synthase inhibition on myocardial metabolism during moderate ischemia.

Nitric oxide (NO) is involved in the control of myocardial metabolism. In normoperfused myocardium, NO synthase inhibition shifts myocardial metabolism from free fatty acid (FFA) toward carbohydrate utilization. Ischemic myocardium is characterized by a similar shift toward preferential carbohydrate utilization, although NO synthesis is increased. The importance of NO for myocardial metabolism during ischemia has not been analyzed in detail. We therefore assessed the influence of NO synthase inhibition with N(G)-nitro-l-arginine (l-NNA) on myocardial metabolism during moderate ischemia in anesthetized pigs. In control animals, the increase in left ventricular pressure with l-NNA was mimicked by aortic constriction. Before ischemia, l-NNA decreased myocardial FFA consumption (MV(FFA); P < 0.05), while consumption of carbohydrate and O(2) (MVo(2)) remained constant. ATP equivalents [calculated with the assumption of complete oxidative substrate decomposition (ATP(eq))] decreased with l-NNA (P < 0.05), associated with a decrease of regional myocardial function (P < 0.05). In contrast, aortic constriction had no effect on MV(FFA), while MVo(2) increased (P < 0.05) and ATP(eq) and regional myocardial function remained constant. During ischemia, alterations in myocardial metabolism were similar in control and l-NNA-treated animals: MV(FFA) decreased (P < 0.05) and net lactate consumption was reversed to net lactate production (P < 0.05). Regional myocardial function was decreased (P < 0.05), although more markedly in animals receiving l-NNA (P < 0.05). We conclude that the efficiency of oxidative metabolism was impaired by l-NNA per se, paralleled by impaired regional myocardial function. During ischemia, l-NNA had no effect on myocardial substrate consumption, indicating that NO synthases were no longer effectively involved in the control of myocardial metabolism.

B-type natriuretic peptide limits infarct size in rat isolated hearts via KATP channel opening.

B-type natriuretic peptide (BNP) has been reported to be released from the myocardium during ischemia. We hypothesized that BNP mediates cardioprotection during ischemia-reperfusion and examined whether exogenous BNP limits myocardial infarction and the potential role of ATP-sensitive potassium (K(ATP)) channel opening. Langendorff-perfused rat hearts underwent 35 min of left coronary artery occlusion and 120 min of reperfusion. The control infarct-to-risk ratio was 44.8 +/- 4.4% (means +/- SE). BNP perfused 10 min before ischemia limited infarct size in a concentration-dependent manner, with maximal protection observed at 10(-8) M (infarct-to-risk ratio: 20.1 +/- 5.2%, P < 0.01 vs. control), associated with a 2.5-fold elevation of myocardial cGMP above the control value. To examine the role of K(ATP) channel opening, glibenclamide (10(-6) M), 5-hydroxydecanoate (5-HD; 10(-4) M), or HMR-1098 (10(-5) M) was coperfused with BNP (10(-8) M). Protection afforded by BNP was abolished by glibenclamide or 5-HD but not by HMR-1098, suggesting the involvement of putative mitochondrial but not sarcolemmal K(ATP) channel opening. We conclude that natriuretic peptide/cGMP/K(ATP) channel signaling may constitute an important injury-limiting mechanism in myocardium.

Myocardial dysfunction with coronary microembolization: signal transduction through a sequence of nitric oxide, tumor necrosis factor-alpha, and sphingosine.

Coronary microembolization results in progressive myocardial dysfunction, with causal involvement of tumor necrosis factor-alpha (TNF-alpha). TNF-alpha uses a signal transduction involving nitric oxide (NO) and/or sphingosine. Therefore, we induced coronary microembolization in anesthetized dogs and studied the role and sequence of NO, TNF-alpha, and sphingosine for the evolving contractile dysfunction. Four sham-operated dogs served as controls (group 1). Eleven dogs received placebo (group 2), 6 dogs received the NO synthase inhibitor N(G)-nitro-L-arginine methyl ester (L-NAME, group 3), and 6 dogs received the ceramidase inhibitor N-oleoylethanolamine (NOE, group 4) before microembolization was induced by infusion of 3000 microspheres (42-microm diameter) per milliliter inflow into the left circumflex coronary artery. Posterior systolic wall thickening (PWT) remained unchanged in group 1 but decreased progressively in group 2 from 20.6+/-4.9% (mean+/-SD) at baseline to 4.1+/-3.7% at 8 hours after microembolization. Leukocyte count, TNF-alpha, and sphingosine contents were increased in the microembolized posterior myocardium. In group 3, PWT remained unchanged (20.3+/-2.6% at baseline) with intracoronary administration of L-NAME (20.8+/-3.4%) and 17.7+/-2.3% at 8 hours after microembolization; TNF-alpha and sphingosine contents were not increased. In group 4, PWT also remained unchanged (20.7+/-4.6% at baseline) with intravenous administration of NOE (19.5+/-5.7%) and 16.4+/-6.3% at 8 hours after microembolization; TNF-alpha, but not sphingosine content, was increased. In all groups, systemic hemodynamics, anterior systolic wall thickening, and regional myocardial blood flow remained unchanged throughout the protocols. A signal transduction cascade of NO, TNF-alpha, and sphingosine is causally involved in the coronary microembolization-induced progressive contractile dysfunction.