Alpha adrenergic contributions to dysrhythmia during myocardial ischemia and reperfusion in cats.

Alpha compared to beta adrenergic contributions to dysrhythmias induced by left anterior descending coronary occlusion and by reperfusion were assessed in chloralose-anesthetized cats (n = 96). Alpha receptor blockade with either phentolamine or prazosin significantly reduced the number of premature ventricular complexes during coronary reperfusion (321 +/- 62-14 +/- 10 premature ventricular complexes, P less than 0.001), abolished early ventricular fibrillation (from 25% in controls to 0%), and prevented the increase in idioventricular rate seen with coronary reperfusion. However, beta-receptor blockade was without effect. Ventricular dysrhythmias induced by coronary occlusion alone (without reperfusion) were attenuated markedly by alpha-receptor blockade under conditions in which perfusion (measured with radiolabeled microspheres) within ischemic zones was not affected. Alternative sympatholytic interventions including pretreatment with 6-hydroxydopamine to deplete myocardial norepinephrine from 8.8 +/- 1.4 to 0.83 +/- 0.2 ng/mg protein and render the heart unresponsive to tyramine (120 microgram/kg) attenuated dysrhythmias induced by both coronary occlusion and reperfusion in a fashion identical to that seen with alpha-receptor blockade. Although efferent sympathetic activation induced by left stellate nerve stimulation increased idioventricular rate from 66 +/- 6 to 144+/- 7 beats/min (P less than 0.01) before coronary occlusion, this response was blocked by propranolol but not by phentolamine. In contrast, during reperfusion the increase in idioventricular rate induced by left stellate nerve stimulation (to 203 +/- 14) was not inhibited by propranolol but was abolished by phentolamine (79 +/- 10). Intracoronary methoxamine (0.1 microM) in animals depleted of myocardial catecholamines by 6-hydroxydopamine pretreatment did not affect idioventricular rate before coronary occlusion. However, early after coronary reperfusion, methoxamine increased idioventricular rate from 33 +/- 7 to 123 +/- 21 beats/min (P less than 0.01). Thus, enhanced alpha-adrenergic responsiveness occurs during myocardial ischemia and appears to be primary mediator of the electrophysiological derangements and resulting malignant dysrhythmias induced by catecholamines during myocardial ischemia and reperfusion.     

Effect of Calcium Entry Blocking Agents (Nifedipine and Verapamil) on Myocardial Recovery during Reperfusion

A comparative study on isolated guinea pig hearts was carried out to determine the effect of calcium entry blocking agents: nifedipine- and verapamil-added reperfusion solutions on myocardial recovery after global ischemia. After 20 min of normothermic ischemia, three groups of solutions were used for reperfusion (10 animals each): (1) Nifedipine-added (10--8 mmol L(minus sign1)) Krebs--Henseleit solution; (2) verapamil-added (10--8 mmol L(minus sign)) Krebs-Henseleit solution; (3) Krebs--Henseleit solution. Postischemic myocardial functions (ventricular contractile force and heart work) and enzyme activities were compared with their preischemic values. The addition of calcium entry blocking agents does not have any significant advantage over control solutions in myocardial recovery.     

Oxygen at physiological concentrations. A potential, paradoxical mediator of reperfusion injury to mitochondria induced by phosphate

Cellular injury induced by reperfusion after myocardial ischemia is manifested by striking mitochondrial damage as well as other hallmarks such as contraction band necrosis. Calcium has been implicated as a mediator of irreversible cellular injury in several systems. To identify other potential mediators of the mitochondrial injury associated with reperfusion, interactions between inorganic phosphate, oxygen, and mitochondria harvested from rabbit hearts were evaluated in vitro. Mitochondria exhibited rapid inactivation of oxidative phosphorylation after preincubation at 25 degrees C when phosphate and oxygen were present. Inactivation was partially but not completely precluded by EDTA, EGTA, magnesium, diltiazem, or ruthenium red, results in concert with findings of others suggesting involvement of a deleterious influx of calcium into mitochondria; exogenous calcium enhanced inactivation. However, the present data indicate that inactivation is prevented by incubation of mitochondria in the absence of oxygen, and demonstrate for the first time that injury elicited by phosphate is dependent on oxygen at physiological concentrations either because calcium and/or phosphate influx is linked to aerobic metabolism or because oxygen exerts deleterious effects on mitochondria, which may render them particularly susceptible to calcium influx. Since intracellular inorganic phosphate concentration increases markedly with ischemia, reperfusion with oxygenated medium may paradoxically augment mitochondrial injury in this setting. Thus, in the presence of increased intracellular concentrations of calcium and phosphate induced by ischemia, subsequent reestablishment of physiological levels of intracellular oxygen tension may promote mitochondrial damage, which is known to increase with reperfusion.     

Effects of physical exercise on serum calcium and parathyroid hormone

The effects of physical exercise on plasma ionized calcium, total serum calcium and parathyroid hormone (PTH) concentrations were evaluated in healthy subjects submitted to work on an ergometer bicycle. When the workload was increased stepwise there was a significant increase (P less than 0.001) in the calcium concentrations (ionized calcium from 1.13 +/- 0.03 (SD) to 1.24 +/- 0.03 mmol 1(-1) and total calcium from 2.35 +/- 0.07 to 2.48 +/- 0.07 mmol 1(-1] when the workload exceeded approximately 65% of the estimated maximum--i.e. a load that caused accumulation in blood of lactic acid. The rise in plasma ionized calcium was, therefore, presumably largely attributed to the acidosis but reduction of plasma volume and influx from extracellular sources might also have contributed. Beta blockade (with oral intake of propranolol) reduced physical capacity, shortened the duration of work and caused less acidosis. These factors were probably responsible for a smaller rise in ionized calcium during beta blockade (7 +/- 4%) than in control studies (21 +/- 5%) without medication in subjects examined during short-term maximal exercise. Long-term (1 h) steady-state work which caused fatigue without producing lactic acidosis did not affect the calcium concentrations. Despite the effects of work on calcium levels there was no discernible suppression of the PTH concentrations. This might have been due to a concomitant stimulation of PTH secretion by work.     

Reversible blockade of electron transport during ischemia protects mitochondria and decreases myocardial injury following reperfusion

Cardiac mitochondria sustain damage during ischemia and reperfusion, contributing to cell death. The reversible blockade of electron transport during ischemia with amobarbital, an inhibitor at the rotenone site of complex I, protects mitochondria against ischemic damage. Amobarbital treatment immediately before ischemia was used to test the hypothesis that damage to mitochondrial respiration occurs mainly during ischemia and that protection of mitochondria during ischemia leads to decreased cardiac injury with reperfusion. Langendorff-perfused Fischer-344 rat hearts were treated with amobarbital (2.5 mM) or vehicle for 1 min immediately before 25 min of global ischemia. Both groups were reperfused for 30 min without additional treatment. Subsarcolemmal (SSM) and interfibrillar (IFM) populations of mitochondria were isolated after reperfusion. Ischemia and reperfusion decreased state 3 and increased state 4 respiration rate in both SSM and IFM. Amobarbital treatment protected oxidative phosphorylation measured following reperfusion and improved the coupling of respiration. Cytochrome c content measured in SSM and IFM following reperfusion decreased in untreated, but not in amobarbital-treated, hearts. H(2)O(2) release from SSM and IFM isolated from amobarbital-treated hearts during reperfusion was markedly decreased. Amobarbital treatment before ischemia improved recovery of contractile function (percentage of preischemic developed pressure: untreated 51 +/- 4%, n = 12; amobarbital 70 +/- 4%, n = 11, p < 0.01) and substantially reduced infarct size (untreated 32 +/- 2%, n = 7; amobarbital 13 +/- 2%, n = 7, p < 0.01). Thus, mitochondrial damage occurs mainly during ischemia rather than during reperfusion. Reperfusion in the setting of preserved mitochondrial respiratory function attenuates the mitochondrial release of reactive oxygen species, enhances contractile recovery, and decreases myocardial infarct size.     

Acidosis during early reperfusion prevents myocardial stunning in perfused ferret hearts.

Cellular calcium overload figures prominently in the pathogenesis of the contractile dysfunction observed after brief periods of ischemia (myocardial stunning). Because acidosis is known to antagonize Ca influx and the intracellular binding of Ca, we reasoned that acidosis during reperfusion might prevent Ca overload and ameliorate functional recovery. We measured developed pressure (DP) and 31P-nuclear magnetic resonance spectra in 26 isovolumic Langendorff-perfused ferret hearts. After 15 min of global ischemia, hearts were reperfused either with normal solution (2 mM [Ca]o, Hepes-buffered, pH 7.4 bubbled with 100% O2; n = 6) or with acidic solutions (pH 6.6 during 0-3 min, pH 7.0 during 4-6 min) before returning to the normal perfusate (n = 7). Ventricular function after 30 min of reperfusion was much greater in the acidic group (105 +/- 5 mmHg at 2 mM [Ca]o) than in the unmodified reperfusion group (79 +/- 7 mmHg, P less than 0.001); similar differences in DP were found over a broad range of [Ca]o (0.5-5 mM, P less than 0.001) and during maximal Ca2+ activation (P less than 0.001). Intramyocardial pH (pHi) was lower in the acidic group than in the unmodified group during early reperfusion, but not at steady state. Phosphate compounds were comparable in both groups. To clarify whether the protective effect of acidosis is due to intracellular or extracellular pH, we produced selective intracellular acidosis during early reperfusion by exposure to 10 mM NH4Cl for 6 min just before ischemia (n = 6). For the first 12 min of reperfusion with NH4Cl-free solution (pH = 7.4), pHi was decreased relative to the unmodified group. Recovery of DP was practically complete, and maximal Ca2+-activated pressure was comparable to that in a nonischemic control group (n = 5). These results indicate that transient intracellular acidosis can prevent myocardial stunning, presumably owing to a reduction of Ca influx into cells and/or competition of H+ for intracellular Ca2+ binding sites during early reperfusion.     

Effects of Felodipine on the dog kidney: a lithium clearance study.

This study was performed in order to investigate the possible influence of sympathetic nerve activity on the effects of the dihydropyridine calcium antagonist felodipine on absolute and fractional reabsorption rates of sodium and water in proximal and distal tubular segments in the dog kidney. Clearance of 51Cr-EDTA was used as a measure of glomerular filtration rate (GFR). GFR, urinary excretion rates of sodium and water, and lithium clearance (C-Li) were used for assessing the absolute and fractional tubular reabsorption rates. Felodipine infusion into the right renal artery increased renal vascular conductance (renal blood flow divided by renal arteriovenous pressure gradient) significantly (by 9%) while GFR remained unchanged. Calculated absolute proximal reabsorption rates remained unchanged while distal sodium reabsorption rate increased significantly from 2.1 +/- 0.3 to 2.7 +/- 0.4 mmol min-1. Sodium clearance (C-Na) increased from 0.22 +/- 0.08 to 0.40 +/- 0.07 ml min-1. The alpha-adrenergic blockade with phentolamine did not affect renal haemodynamic or excretory variables, nor did it influence the haemodynamic response to felodipine. After alpha-adrenergic blockade felodipine caused an increase in C-Na from 0.28 +/- 0.06 ml min-1 to 0.63 +/- 0.04 ml min-1, which was significantly greater than that measured after felodipine alone. The distal load (C-Li) was not significantly different from that obtained after felodipine alone, but distal sodium reabsorption rate increased less significantly after alpha-adrenergic blockade. The results suggest that felodipine, by its effect on tubular flow and/or composition, activates local alpha-adrenergic reflex mechanism(s), which stimulates distal sodium reabsorption, thereby attenuating the natriuretic effect.     

Increased alpha-adrenergic receptors in ischemic cat myocardium. A potential mediator of electrophysiological derangements.

We have recently demonstrated enhanced alpha-adrenergic responsiveness assessed electrophysiologically in ischemic and reperfused myocardium. This study was performed to determine whether ischemia alters alpha 1-adrenergic receptor number (Bmax) of affinity (KD) based on [3H]prazosin binding. Within 30 min after occlusion, Bmax increased in ischemic regions to 207% of control to 27 +/- 2 fmol/mg protein, with the increase persisting (+ 141% of control) during early reperfusion (2 min), before returning to control base-line values (13 +/- 1.6) after 15 min of reperfusion. KD was not altered at any interval studied. Beta receptor number of ([3H]dihydroalprenolol) and Na+-K+ ATPase activity were comparable in control compared to ischemic myocardium although beta-receptor Bmax and KD in both regions decreased during early reperfusion. Thus, the enhanced alpha-adrenergic responsivity previously recognized with ischemia and reperfusion is correlated with an increase in alpha 1-adrenergic receptors.     

Sustained reduction in myocardial reperfusion injury with an adenosine receptor antagonist: possible role of the neutrophil chemoattractant response

Recent studies have demonstrated that three membrane-permeant A(1) receptor antagonists reduced infarct size in a model of ischemia followed by brief reperfusion. However, it was not determined whether cardioprotection was mediated by nonspecific intracellular effects of these highly lipophilic drugs and whether the antagonists only delayed myocardial necrosis without affecting the ultimate infarct size. In the present study, closed-chest dogs were subjected to 90 min of left anterior descending coronary artery occlusion and 72 h of reperfusion and received either a nonmembrane-permeant adenosine receptor blocker that is devoid of direct intracellular effects and is 6-fold selective for the A(1) receptor [1, 3-dipropyl-8-p-sulfophenylxanthine (DPSPX); n = 11] or vehicle (n = 12). DPSPX was administered as three 200-mg boluses 60 min before and 30 and 120 min after reperfusion. The area of necrosis was determined histologically and expressed as a percentage of the area at risk. Baseline predictors of infarct size were similar in the two groups. The ratio of the area of necrosis to the area at risk was less in the DPSPX group (17.8 +/- 4.3% versus 35.0 +/- 1.9%; P =. 012), and DPSPX improved regional ventricular function. Under both basal and stimulated (formyl-Met-Leu-Phe) conditions, suspensions of human neutrophils generated extracellular adenosine levels (approximately 50 nM) sufficient to activate A(1) receptors. Moreover, both DPSPX and 1,3-dipropyl-8-cyclopentylxanthine, a selective A(1) receptor antagonist, significantly reduced the chemoattractant response of neutrophils to formyl-Met-Leu-Phe. We conclude that blockade of A(1) adenosine receptors attenuates myocardial ischemic/reperfusion injury, possibly in part by decreasing the chemoattractant response of neutrophils.     

The effects of calcium entry blockade on the vulnerability of infarcted canine myocardium toward ventricular fibrillation

The effects of the calcium entry blockers diltiazem, KB-944 [diethyl 4-(benzothiazol-2-yl)benzylphosphonate] and bepridil on the vulnerability of ischemically injured myocardium toward fibrillation were determined in urethane-anesthetized dogs 4 to 7 days after anterior myocardial infarction. Diltiazem (3.0-30.0 micrograms/kg/min X 30 min), KB-944 (0.3-3.0 mg/kg) and bepridil (1.0-10.0 mg/kg) were administered i.v. to produce equivalent increases in atrioventricular nodal effective and functional refractory periods as a measure of slow calcium channel blockade. At dosages producing equivalent increases in atrioventricular nodal refractoriness, diltiazem and KB-944 failed to increase the electrical current threshold required to produce ventricular fibrillation, whereas bepridil elevated the fibrillation threshold from 4.2 +/- 0.5 mA predrug to 14.7 +/- 2.2 mA postdrug (P less than .01). Increases in atrial (128 +/- 6-185 +/- 29 msec, P less than .01) and ventricular (156 +/- 4-175 +/- 6 msec, P less than .05) refractory periods accompanied the increase in fibrillation threshold with bepridil. These findings suggest that calcium entry blockade per se does not reduce ventricular vulnerability toward fibrillation in the setting of recent myocardial infarction.     

A mechanism for the potential proarrhythmic effect of acidosis, bradycardia, and hypokalemia on the blockade of human ether-a-go-go-related gene (HERG) channels

Many drugs are proarrhythmic by inhibiting the cardiac rapid delayed rectifier potassium channel (IKr). In this study, we use quinidine as an example of highly proarrhythmic agent to investigate the risk factors that may facilitate the proarrhythmic effects of drugs. We studied the influence of pacing, extracellular potassium, and pH on quinidine's IKr blocking effect, all potential factors influencing quinidine's cardiac toxicity. Since the HERG gene encodes IKr, we studied quinidine's effect on HERG expressed in Xenopus oocytes by the 2-electrode voltage clamp technique. When extracellular K+ was 5 mmol/L, quinidine blocked the HERG current dose dependently, with an IC50 of 6.3 +/- 0.2 micromol/L. The blockade was much more prominent at more positive membrane potentials. The inhibition of HERG by quinidine was not use dependent. There was no significant difference between block with or without pacing. When extracellular K+ was lowered to 2.5 mmol/L, the current inhibition by quinidine was enhanced, and IC50 decreased to 4.6 +/- 0.5 micromol/L. At 10 mmol/L extracellular K+, there was less inhibition by quinidine and the IC50 was 11.2 +/- 3.1 micromol/L. Extracellular acidification decreased both steady state and tail currents of HERG. We conclude that the inhibitory effect of quinidine on IKr was decreased with extracellular acidification, which may produce heterogeneity in the repolarization between normal and ischemic cardiac tissue. Thus, the use-independent blockade of IKr by QT-prolonging agents such as quinidine may contribute to cardiac toxicity with bradycardia, hypokalemia, and acidosis further exaggerating the proarrhythmic potential of these agents.     

Improved left ventricular function and reduced necrosis after myocardial ischemia/reperfusion in rabbits treated with ranolazine, an inhibitor of the late sodium channel

Ranolazine is an inhibitor of the late sodium current and, via this mechanism, decreases sodium-dependent intracellular calcium overload during ischemia and reperfusion. Ranolazine reduces angina, but there is little information on its effects in acute myocardial infarction. The aim of this study was to test the effects of ranolazine on left ventricular (LV) function and myocardial infarct size after ischemia/reperfusion in rabbits. Ten minutes before coronary artery occlusion (CAO), anesthetized rabbits were assigned to vehicle (n=15) or ranolazine (2 mg/kg i.v. bolus plus 60 microg/kg/min i.v. infusion; n=15). Hearts received 60 min of CAO and 3 h of reperfusion. CAO caused LV dysfunction associated with necrosis. However, at the end of reperfusion, rabbits treated with ranolazine had better global LV ejection fraction (0.42+/-0.02 versus 0.33+/-0.02; p<0.007) and stroke volume (1.05+/-0.08 versus 0.78+/-0.07 ml; p<0.01) compared with vehicle. The fraction of the LV wall that was akinetic or dyskinetic was significantly less in the ranolazine group at 0.23+/-0.03 versus 0.34+/-0.03 in vehicle-treated group; p<0.02. The ischemic risk region was similar in both groups; however, infarct size was significantly smaller in the treated group (44+/-5 versus 57+/-4% vehicle; p<0.04). There were no significant differences among groups in heart rate, arterial pressure, LV end-diastolic pressure, or maximum-positive or -negative first time derivative of LV pressure (dP/dt). In conclusion, the results of this study show that ranolazine provides protection during acute myocardial infarction in this rabbit model of ischemia/reperfusion. Ranolazine treatment led to better ejection fraction, stroke volume and less wall motion abnormality after reperfusion, and less myocardial necrosis.     

Calcium oscillations index the extent of calcium loading and predict functional recovery during reperfusion in rat myocardium.

Delayed recovery of contractile function after myocardial ischemia may be due to prolonged recovery of high-energy phosphates, persistent acidosis, increased inorganic phosphate, and/or calcium loading. To examine these potential mechanisms, metabolic parameters measured by 31P nuclear magnetic resonance spectroscopy, and spontaneous diastolic myofilament motion caused by sarcoplasmic reticulum-myofilament calcium cycling indexed by the scattered light intensity fluctuations (SLIF) it produces in laser beam reflected from the heart, were studied in isolated atrioventricularly blocked rat hearts (n = 10) after 65 min of ischemia at 30 degrees C. All metabolic parameters recovered to their full extent 5 min after reperfusion. Developed pressure evidenced a small recovery but then fell abruptly. This was accompanied by an increase in end diastolic pressure to 37 +/- 5 mm Hg and a fourfold increase in SLIF, to 252 +/- 58% of baseline. In another series of hearts initial reperfusion with calcium of 0.08 mM prevented the SLIF rise and resulted in improved developed pressure (74 +/- 3% vs. 39 +/- 13% of control), and lower cell calcium (5.9 +/- 3 vs. 10.3 +/- 1.4 mumol/g dry wt). Thus, during reperfusion, delayed contractile recovery is not associated with delayed recovery of pH, inorganic phosphate, or high-energy phosphates and can be attributed, in part, to an adverse effect of calcium loading which can be indexed by increased SLIF occurring at that time.     

Early postoperative function of the heart after coronary artery bypass grafting is not predicted by myocardial necrosis and glutathione-associated oxidative stress

BACKGROUND: To investigate whether cardioplegia-related myocardial necrosis, lactate and glutathione release are predictive for early postoperative cardiac function after coronary artery bypass grafting (CABG). METHODS: Twelve patients with stabile angina scheduled for elective CABG were included. Myocardial release of troponin I (Tn I), creatine kinase MB isoenzyme mass (CK-MB), oxidized glutathione (GSSG) and lactate in blood were measured before cardioplegia, and up to 20 min thereafter. Cardiac function was assessed for 12 postoperative hours. RESULTS: Release of Tn I and CK-MB peaked at 20 min (-14.5+/-24.1 ng/ml and -23.9+/-30.6 ng/ml, respectively) and lactate at 1 min of reperfusion (-1.5+/-0.6 mmol/l). Significant GSSG release occurred at 5 min, with concomitant increase of glutathione redox ratio. The changes were not correlated to ischemic time. Cardiac index was increased after CPB and remained higher than preoperative value until the first postoperative morning. No correlations between postcardioplegic heart function and markers of tissue injury were found. CONCLUSIONS: The extent of myocardial reversible and irreversible injury does not predict early postoperative contractile function of the heart.     

Hemodynamic effects of dobutamine in an intact animal model.

BACKGROUND AND METHODS: Actions of dobutamine at the beta 1, beta 2, and alpha 1 adrenoreceptors were studied in anesthetized dogs. Six animals received dobutamine (at infusion rates of 0 to 160 micrograms/kg/min) with and without beta-adrenergic receptor blockade. Five animals received phenylephrine (0 to 16 micrograms/kg/min), with and without concurrent dobutamine (20 micrograms/kg/min); this procedure was repeated in five animals after beta-blockade. RESULTS: Dobutamine (10 to 160 micrograms/kg/min) increased heart rate (HR), cardiac output, and left ventricular change in pressure over time, and decreased systemic vascular resistance. beta-blockade prevented only dobutamine-induced changes in HR. Mean arterial pressure (MAP), unaffected by dobutamine alone, decreased with concurrent beta-blockade. Phenylephrine (1 to 16 micrograms/kg/min)-induced increases in MAP were unaffected by dobutamine; with beta-blockade, phenylephrine reduced MAP. Dobutamine prevented a phenylephrine-induced increase in systemic vascular resistance, an effect eliminated by beta-adrenergic receptor blockade. CONCLUSIONS: Dobutamine appeared to be an agonist at the beta 1- and beta 2-adrenoreceptors and at the myocardial alpha-adrenoreceptor. Dobutamine appeared to be an alpha-adrenergic receptor antagonist in the peripheral vasculature.     

Reactive oxygen species during ischemia-reflow injury in isolated perfused rat liver.

The hypothesis that intracellular generation of reactive oxygen species in hepatocytes or reticuloendothelial cells may cause ischemia-reperfusion injury was tested in isolated perfused livers of male Fischer rats. GSSG was measured in perfusate, bile, and tissue as a sensitive index of oxidative stress. After a preperfusion phase of 30 min, the perfusion was stopped (global ischemia) for various times (30, 120 min) and the liver was reperfused for another 60 min. The bile flow (1.48 +/- 0.17 microliters/min X gram liver weight), the biliary efflux of total glutathione (6.54 +/- 0.94 nmol GSH eq/min X g), and GSSG (1.59 +/- 0.23 nmol GSH eq/min X g) recovered to 69-86% after short-term ischemia and to 36-72% after 2 h of ischemia when compared with values obtained from control livers perfused for the same period of time. During reperfusion, the sinusoidal efflux of total glutathione (16.4 +/- 2.1 nmol GSH eq/min X g) and GSSG (0.13 +/- 0.05 nmol GSH eq/min X g) did not change except for an initial 10-30-s increase during reperfusion washout. No increased GSSG secretion into bile was detectable at any time during reperfusion. The liver content of total glutathione (32.5 +/- 3.5 nmol GSH eq/mg protein) and GSSG (0.27 +/- 0.09 nmol GSH eq/mg protein) did not change significantly during any period of ischemia or reperfusion. We conclude, therefore, that at most only a minor amount of reactive oxygen species were generated during reperfusion. Thus, reactive oxygen species are unlikely to cause ischemia/reperfusion injury in rat liver by lipid peroxidation or tissue thiol oxidation.     

Evidence for a significant myocardial contribution to total metabolic burden during hypothermic cardiopulmonary bypass: a study of continuously measured oxygen consumption and arterial lactate levels in pigs

OBJECTIVE: We assessed the causes of imbalance of oxygen transport by continuously measuring oxygen consumption (VO2) during hypothermic cardiopulmonary bypass (CPB) in pigs. METHODS: Six pigs (17.2+/-1.6 kg) underwent hypothermic (32 degrees C) CPB for 180 min with 120 min of aortic crossclamping (ACC). An AMIS 2000 mass spectrometer was adapted for the on-line measurement of VO2. Arterial lactate was measured at the beginning of CPB, the end of hypothermia, before and 10 min after ACC release, 20 min later, and at the end of CPB. RESULTS: Arterial lactate increased from 1.8+/-0.7 to 5.1+/-1.8 mmol/L during CPB. Hypothermia reduced VO2 by 0.63+/-0.29 mlmin/kg per degrees C, but lactate increased to 4.2+/-1.5 mmol/L (p <0.05). The most rapid rise of VO2 and lactate occurred during the first 10 min after ACC removal, accounting for 26% and 68%, respectively, of the total rise during rewarming. CONCLUSIONS: Inadequate tissue oxygenation persists throughout hypothermic CPB. The rise in systemic VO2 and lactate immediately after ACC release may reflect inadequate oxygen transport within the myocardium during ischemia and manifest on reperfusion. This simple technique may be used to provide important information regarding the dynamic balance of systemic and myocardial oxygen transport during ischemia-reperfusion.     

Tissue protection by allopurinol in the myocardial calcium paradox

The aim of the present study was to evaluate the protective properties of the xanthine oxidase inhibitor allopurinol in the myocardial calcium paradox. Two injury levels, minimal and total calcium paradox, caused by different volumes (5 ml and 45 ml) of calcium-free perfusion (5 min) prior to calcium repletion (15 min) were examined +/- allopurinol (0.15 mmol/l) in the normothermic isolated rat heart model. Allopurinol supplementation (5 min prior to, during and 5 min following Ca2+-free perfusion) had no effect upon tissue injury in the total calcium paradox, but afforded considerable protection as assessed by enzymatic, physiologic, and metabolic parameters in the minimal calcium paradox. When allopurinol was omitted during calcium repletion, tissue protection was less apparent. The presence of verapamil (2 mumol/l) in addition to allopurinol (5 min prior to, during, and 5 min following calcium depletion) afforded only a marginal further protection in the minimal calcium paradox. It is concluded from the present study that tissue protection by allopurinol in the calcium paradox is limited to minimal or less severe calcium paradox models and that the protective action of allopurinol may indicate an inhibition of the xanthine oxidase reaction and the generation of free oxygen radicals.     

Determination of alpha-adrenergic blocking potency.

Determination of the alpha-adrenergic blocking potency of drugs in humans is usually done by measuring the shift in the blood pressure versus logarithm of intravenous phenylephrine dose-response relationship. Change in blood pressure activates homeostatic reflexes that may change this relationship. This study examines the effect of autonomic (beta 1- and beta 2-adrenergic, parasympathetic, and alpha-adrenergic) blockade on the dose versus blood pressure response relationship to sequential doses of phenylephrine in humans. Phenylephrine dose responses were conducted under controlled conditions, during propranolol and atropine infusion, during prazosin-induced alpha 1-adrenergic blockade, and during prazosin, propranolol, and atropine administration. Propranolol-atropine infusion decreased the threshold dose of phenylephrine required to increase mean blood pressure (p less than 0.00001), increased the slope of the phenylephrine dose versus increase in mean blood pressure relationship (p = 0.019), and and decreased the dose of phenylephrine required to increase mean blood pressure by 20 mm Hg (p less than 0.00001). Determination of the alpha-adrenergic blocking potency of prazosin was not affected by autonomic blockade with propranolol and atropine (dose ratio 5.2 before and 5.0 after autonomic blockade; p = 0.465). We conclude that beta 1- and beta 2-adrenergic and muscarinic blockade increase sensitivity to phenylephrine by increasing the slope and decreasing the threshold dose of the phenylephrine dose-response curve, and that alpha-adrenergic-blocking potency of prazosin may be determined with or without blocking homeostatic blood pressure regulatory mechanisms in humans.     

Myocardial tissue oxygen supply and utilization during coronary artery bypass surgery: evidence of microvascular no-reflow

The supply and utilization of oxygen by the myocardium reflect the dynamic efficiency of the microcirculation. The present study examines these parameters during coronary artery bypass surgery. We used a voltammetric microelectrode technique to assess regional variations in myocardial tissue partial pressure of oxygen (PO(2)) and myocardial tissue perfusion (MTP) in patients undergoing coronary artery bypass surgery. A total of 29 myocardial regions were studied in 17 patients to assay tissue PO(2), and 13 regions in 10 patients to measure MTP. There was an increase in MTP from 53+/-9 ml.min(-1).100 g(-1) before cardiopulmonary bypass to 72+/-13 ml. min(-1).100 g(-1) after (means+/-S.E.M.; P=0.05). Tissue PO(2) showed an overall increase from a baseline level of 45+/-8 mmHg to a final level of 88+/-10 mmHg (P<0.0001). Following release of the aortic cross-clamp there was a variable time delay before a change in tissue PO(2) was observed. There was an immediate response in five regions, whereas in 20 regions the response was delayed by between 0.5 and 32 min. In the remaining four regions there was no change in tissue PO(2). The duration of the delay in response was correlated positively with the cross-clamp time (r=0.45, P<0.05) and negatively with the final tissue PO(2) (r=-0.5, P<0.05). Voltammetric methods for monitoring changes in oxygen supply and utilization offer new insights into the changes that occur during ischaemia and reperfusion. A delay in the delivery of oxygen to the myocardium occurs in many patients following coronary artery bypass surgery.