Proposed role of calcium in reperfusion injury

Beneficial effects of carbon monoxide-releasing molecules on post-ischemic myocardial recovery

There is increasing evidence corroborating a protective role of carbon monoxide releasing molecules (CORMs) in injured tissues. Carbon monoxide (CO) carriers have been recently developed as a pharmacological tool to simulate the effect of heme oxygenase-1-derived CO. The effects of CORM-3, a water-soluble CO releaser, on the incidence of reperfusion-induced ventricular fibrillation (VF) and tachycardia (VT) were studied in isolated rat hearts. Hearts were treated with different doses of CORM-3 before the induction of 30 min global ischemia followed by 120 min reperfusion. We found that at concentrations of 25 microM and 50 microM of CORM-3 promoted a significant reduction in the incidence of VF and VT. Thus, the incidence of VF was reduced by 67% (p<0.05) and 92% (p<0.05) with 25 microM and 50 microM of CORM-3, respectively. The protective effect of CORM-3 on the incidence of VT followed the same pattern. The antiarrhythmic protection was associated with a marked attenuation in infarct size, significant decreases in cellular Na(+) and Ca(2+) gains and K(+) loss. Consequently, the recovery of post-ischemic function was significantly improved. In conclusion, CORM-3 exerts beneficial effects against ischemia/reperfusion-induced injury through its abilities to release CO which mediates a cardioprotective action by regulating tissue Na(+), K(+), and Ca(2+) levels.

Evaluation of intestinal intramucosal pH, arterial and portal venous blood gas values, and intestinal blood flow during small intestinal ischemia and reperfusion in dogs

OBJECTIVES

To determine whether small intestinal ischemia and reperfusion affects intestinal intramucosal pH (pHi), arterial and portal venous blood gas values, and intestinal blood flow (IBF) and to investigate relationships between regional intestinal tissue oxygenation and systemic variables in dogs.

ANIMALS

15 healthy adult Beagles.

PROCEDURE

Occlusion of superior mesenteric artery (SMA) for 0, 30, or 60 minutes, followed by reperfusion for 180 minutes, was performed; IBF, pHi, arterial and portal venous blood gas values, arterial pressure, and heart rate were measured at various time points; and intestinal mucosal injury was histologically graded.

RESULTS

Occlusion of the SMA induced significant decreases in pHi and IBF. After the release of the occlusion, IBF returned rapidly to baseline values, but improvement in pHi was slow. Arterial and portal venous blood gas analyses were less sensitive than tonometric measurements of pHi, and there was no correlation between results of blood gas analyses and tonometric measurements. Histologic score for intestinal mucosal injury increased significantly, depending on duration of ischemia, and there was a correlation between tonometric results and the histologic score.

CONCLUSIONS AND CLINICAL RELEVANCE

Results suggest that it is difficult to accurately evaluate local oxygenation disorders by monitoring at the systemic level, whereas clinically pHi is the only reliable indicator of inadequate regional intestinal tissue oxygenation in dogs.

Glucose and glycogen utilisation in myocardial ischemia--changes in metabolism and consequences for the myocyte

Experimentally, enhanced glycolytic flux has been shown to confer many benefits to the ischemic heart, including maintenance of membrane activity, inhibition of contracture, reduced arrhythmias, and improved functional recovery. While at moderate low coronary flows, the benefits of glycolysis appear extensive, the controversy arises at very low flow rates, in the absence of flow; or when glycolytic substrate may be present in excess, such that high glucose concentrations with or without insulin overload the cell with deleterious metabolites. Under conditions of total global ischemia, glycogen is the only substrate for glycolytic flux. Glycogenolysis may only be protective until the accumulation of metabolites (lactate, H+, NADH, sugar phosphates and Pi ) outweighs the benefit of the ATP produced. The possible deleterious effects associated with increased glycolysis cannot be ignored, and may explain some of the controversial findings reported in the literature. However, an optimal balance between the rate of ATP production and rate of accumulation of metabolites (determined by the glycolytic flux rate and the rate of coronary washout), may ensure optimal recovery. In addition, the effects of glucose utilisation must be distinguished from those of glycogen, differences which may be explained by functional compartmentation within the cell.

Effects of felodipine on the ischemic heart: insight into the mechanism of cytoprotection

To assess whether the administration of felodipine protects the myocardium in a dose-dependent manner against ischemia and reperfusion, isolated rabbit hearts were infused with three different concentrations of felodipine: 10(-10), 10(-9), and 10(-8) M. Diastolic and developed pressures were monitored; coronary effluent was collected and assayed for CPK activity and for noradrenaline concentration; mitochondria were harvested and assayed for respiratory activity; and ATP production and calcium content and tissue concentration of ATP, creatine phosphate (CP), and calcium were determined. The occurrence of oxidative stress during ischemia and reperfusion was also monitored in terms of tissue content and release of reduced (GSH) and oxidized (GSSG) glutathione. Treatment with felodipine at 10(-10) and 10(-9) M had no effect on the hearts when perfused under aerobic conditions, whilst the higher dose reduced developed pressure from 57.7 +/- 2.6 to 30.0 +/- 2.6 mmHg (p < 0.01). On reperfusion treated hearts recovered better than the untreated hearts with respect to left ventricular performance, replenishment of ATP and CP stores, and mitochondrial function. Recovery of developed pressure was 100% at 10(-8) M, 55% at 10(-9) M, and 46% at 10(-10) M. The reperfusion-induced tissue and mitochondrial calcium overload, release of CPK and noradrenaline, and oxidative stress were also significantly reduced. The effects of felodipine were dose dependent. Felodipine inhibited the initial rate of ATP-driven calcium uptake but failed to affect the initial rate of mitochondrial calcium transport. It is concluded that felodipine infusion provides dose-dependent protection of the heart against ischemia and reperfusion. Because this protection also occurred at 10(-9) M and 10(-10) M in the absence of a negative inotropic effect during normoxia and of a coronary dilatory effect during ischaemia, it cannot be attributed to an energy-sparing effect or to improvement in oxygen delivery. From our data we can envisage two other major mechanisms-(1) membrane protection and (2) reduction in oxygen toxicity. The ATP-sparing effect occurring at 10(-8) M is likely to be responsible for the further protection.

The scientific basis for hypocalcemic cardioplegia and reperfusion in cardiac surgery

The scientific rationale for avoiding the use of calcium-enriched cardioplegic solutions and calcium supplementation during cardioplegic induction and the early phase of reperfusion in open heart surgical procedures is reviewed. The role of the extracellular and intracellular free ionized calcium concentrations during ischemia and reperfusion is explored and the biochemical effects of ischemia on calcium fluxes, adenosine triphosphate levels, and mitochondrial function are discussed. The role of calcium in causing myocardial stunning and the biochemical basis of reperfusion injury are also addressed. Both prolonged ischemia and an increased concentration of Ca2+ during reperfusion have proved to be deleterious. I conclude on the basis of my review that there is no justification for the use of calcium chloride before and during the early phase of reperfusion and that hypocalcemic perfusion is an effective and easily controllable means of myocardial protection.

MYOCARDIAL REVASCULARIZATION

Atherosclerotic coronary artery disease causes more morbidity, mortality and loss of economic capacity than any other group of diseases. The modalities of revascularization of the myocardium have undergone rapid advances with emphasis shifting alternately from medical methods to surgical. Lately interventional cardiology armed with laser technology stands at par with coronary artery bypass grafts.

Changes in calcium content of the liver during hepatic ischemia-reperfusion in dogs

Alteration of calcium metabolism in cells has been thought to be one of the main factors in ischemia-reperfusion injury. Serial changes in the tissue calcium content of the liver and the correlation between calcium level and liver injury were investigated. Experimental dogs were divided into two groups and subjected to hepatic ischemia of different duration: 60 min in Group A and 120 min in Group B, followed by reperfusion. Serum alanine aminotransferase, as an indicator of liver injury, was more elevated in Group B than in Group A. There was no change in hepatic calcium content during ischemia in either group. Immediately after reperfusion, there was no change in hepatic calcium level in Group A, whereas in Group B it was markedly elevated. The peak value occurred 30 min after reperfusion and gradually decreased thereafter, but did not return to pre-ischemic levels during the observation time. Plasma calcium concentrations in hepatic venous blood were markedly decreased in Group B 30 min and 60 min after reperfusion. These results suggest that calcium accumulation in the liver during the early reperfusion period may be one of the mediators of hepatic injury. To elucidate the mechanisms for elevation of calcium in hepatic tissue, serum malondialdehyde, a product of lipid peroxidation, was measured in hepatic venous blood. No elevation of serum malondialdehyde was observed in either group, indicating that the increases in calcium may not be due to oxidative stress. Serum mitochondrial aspartate aminotransferase and electron microscopic findings were used as indicators of mitochondrial injury.(ABSTRACT TRUNCATED AT 250 WORDS)

Myocardial stunning--are calcium antagonists useful?

Considerable data support the point of view that calcium antagonists, whether given before the onset of ischemia or exactly at the time of reperfusion, ameliorate stunning. Benefit after the onset of reperfusion is much more controversial. It is proposed that the mechanisms whereby calcium antagonists act vary between these situations. When given before or at the onset of ischemia, then an antiischemic effect is likely. According to the hypothesis that the severity of ischemic damage determines the severity of reperfusion damage, the calcium antagonists indirectly lessen reperfusion damage. When given exactly at the time of reperfusion, the proposal is that the calcium antagonists are specifically limiting the entry of calcium ions via the calcium channel and thereby diminishing pathogenic cytosolic calcium oscillations. The reported benefit of calcium antagonists when given postreperfusion to the heart in situ, in the presence of established stunning, is of unknown mechanism and controversial significance. The hypothesis of a two-stage model of stunning with calcium as a pathogen is in accord with most of the available evidence.

Effect of ischemia and reperfusion on cardiac ryanodine receptors--sarcoplasmic reticulum Ca2+ channels

We investigated the effect of ischemia and reperfusion on the cardiac ryanodine receptor, which corresponds to the sarcoplasmic reticulum Ca2+ channel. Isolated working rat hearts were subjected to 10 to 30 minutes of global ischemia, followed or not by reperfusion. Ischemia produced significant reduction in the density of high-affinity 3H-ryanodine binding sites, determined either in whole-heart homogenate (Bmax, 220 +/- 22, 203 +/- 12, and 228 +/- 14 fmol/mg protein after 10, 20, and 30 minutes of ischemia versus 298 +/- 18 fmol/mg protein in the control condition; P < .01) or in a fraction enriched in sarcoplasmic reticulum (Bmax, 1.08 +/- 0.15 pmol/mg protein after 20 minutes of ischemia versus 1.69 +/- 0.08 pmol/mg protein in the control condition; P < .01). The Kd (1.5 +/- 0.1 nmol/L) and the Ca2+ dependence of high-affinity 3H-ryanodine binding were not affected by ischemia. The density of low-affinity 3H-ryanodine binding sites was also reduced after 20 minutes of ischemia (14.0 +/- 2.3 versus 34.0 +/- 8.2 pmol/mg protein in the sarcoplasmic reticulum fraction, P < .05), without significant changes in Kd (4.7 +/- 1.2 versus 2.4 +/- 1.0 mumol/L). All these changes persisted after 20 minutes of reperfusion. Analysis of tissue fractions showed that 55% of the ryanodine binding sites were retained in the pellet of a low-speed centrifugation ("nuclear pellet") and that the effects of ischemia concerned only the receptors released in the supernatant ("postnuclear supernatant"). In parallel experiments, we evaluated the effect of ryanodine on oxalate-supported Ca2+ uptake, which represents sarcoplasmic reticulum Ca2+ uptake. As expected, we found that high concentrations of ryanodine stimulated Ca2+ uptake, owing to channel blockade. The response to 900 mumol/L ryanodine was slightly reduced in crude homogenate and significantly reduced in postnuclear supernatant obtained from ischemic hearts. In conclusion, the number of ryanodine receptors is reduced after ischemia; this effect concerns a subpopulation of the receptors, persists after reperfusion, and might contribute to modify sarcoplasmic reticulum function.

Moderation of myocardial ischemia reperfusion injury by calcium channel and calmodulin receptor inhibition

Intracellular Ca2+ accumulation is implicated in the pathogenesis of myocardial reperfusion injury. To study approaches designed to modify Ca2+ uptake during coronary revascularization after acute infarction, a pig heart surgical infarct model (left anterior descending artery occlusion for 60 min) was subjected to 60 min hypothermic potassium cardioplegic arrest, followed by 60 min of global reperfusion. Four groups of six hearts each were studied in a randomized manner, i.e., cardioplegia alone (control), cardioplegia + 10 microM diltiazem (Ca2+ slow channel blocker), cardioplegia + 10 microM trifluoperazine (TFP), (a Ca(2+)-calmodulin antagonist), and cardioplegia+diltiazem (10 microM) + TFP (10 microM). Left ventricular contractility (global and segmental), metabolism (coronary blood flow and O2 consumption), and creatine kinase generation were measured during reperfusion. Both the Ca2+ channel blocker, diltiazem, and the calmodulin antagonist, TFP, improved myocardial global and regional function as well as myocardial metabolism. While diltiazem better restored global and regional contractility, trifluoperazine had a greater effect on coronary blood flow and myocardial oxygen consumption. Enzyme release and lipid peroxidation were equally moderated by both drugs. From this study it can be concluded that Ca2+ influx does play a role in ischemic and reperfusion injury. The mechanisms of its effect are complex, but can be successfully antagonized by Ca2+ blockers as well as by calmodulin antagonists, with improved myocardial preservation.

Thioctic acid protects against ischemia-reperfusion injury in the isolated perfused Langendorff heart

Antioxidant properties of thioctic and dihydrolipoic acid have been demonstrated in membranes and low density lipoproteins (LDL) in vitro. In vivo studies with dietary supplementation of thioctic acid to rats showed that it can also protect tissues against oxidative damage. Presumably, this action is due to a thioctic acid dihydrolipoic acid (TA/DHLA) coupled antioxidant mechanism, which enhances the activity of other antioxidants (i.e. ascorbate, alpha-tocopherol) by regenerating them from their radical form. In the present study, thioctic acid proved to protect against ischemia/reperfusion injury to Langendorff perfused hearts. Hearts isolated from rats fed thioctic acid and subjected to ischemia exhibited better mechanical recovery (left ventricular developed pressure) after reperfusion and lower lactate dehydrogenase leakage. Thioctic acid supplementation also decreased the appearance of fluorescent lipid peroxidation products after ischemia/reperfusion, lowered the rate of 2,2'-azobis-(2,4-dimethylvaleronitrile) (AMVN) induced lipid peroxidation in heart homogenates, and prevented the loss of alpha-tocopherol. The total sulfhydryl group content in thioctic acid fed animals was higher and the decrease due to ischemia-reperfusion was not as marked in this group as observed in the control. These results show that dietary supplementation with thioctic acid in vivo provides protection against ischemia/reperfusion injury in the Langendorff heart model.

Hydrogen peroxide-induced oxidative stress to the mammalian heart-muscle cell (cardiomyocyte): lethal peroxidative membrane injury

Oxidative stress induced by hydrogen peroxide (H2O2) may contribute to the pathogenesis of ischemic-reperfusion injury in the heart. For the purpose of investigating directly the injury potential of H2O2 on heart muscle, a cellular model of H2O2-induced myocardial oxidative stress was developed. This model employed primary monolayer cultures of intact, beating neonatal-rat cardiomyocytes and discrete concentrations of reagent H2O2 in defined, supplement-free culture medium. Cardiomyocytes challenged with H2O2 readily metabolized it such that the culture content of H2O2 diminished over time, but was not depleted. The consequent H2O2-induced oxidative stress caused lethal sarcolemmal disruption (as measured by lactate dehydrogenase release), and cardiomyocyte integrity could be preserved by catalase. During oxidative stress, a spectrum of cellular derangements developed, including membrane phospholipid peroxidation, thiol oxidation, consumption of the major chain-breaking membrane antiperoxidant (alpha-tocopherol), and ATP loss. No net change in the protein or phospholipid contents of cardiomyocyte membranes accompanied H2O2-induced oxidative stress, but an increased turnover of these membrane constituents occurred in response to H2O2. Development of lethal cardiomyocyte injury during H2O2-induced oxidative stress did not require the presence of H2O2 itself; a brief "pulse" exposure of the cardiomyocytes to H2O2 was sufficient to incite the pathogenic mechanism leading to cell disruption. Cardiomyocyte disruption was dependent upon an intracellular source of redox-active iron and the iron-dependent transformation of internalized H2O2 into products (e.g., the hydroxyl radical) capable of initiating lipid peroxidation, since iron chelators and hydroxyl-radical scavengers were cytoprotective. The accelerated turnover of cardiomyocyte-membrane protein and phospholipid was inhibited by antiperoxidants, suggesting that the turnover reflected molecular repair of oxidized membrane constitutents. Likewise, the consumption of alpha-tocopherol and the oxidation of cellular thiols appeared to be epiphenomena of peroxidation. Antiperoxidant interventions coordinately abolished both H2O2-induced lipid peroxidation and sarcolemmal disruption, demonstrating that an intimate pathogenic relationship exists between sarcolemmal peroxidation and lethal compromise of cardiomyocyte integrity in response to H2O2-induced oxidative stress. Although sarcolemmal peroxidation was causally related to cardiomyocyte disruption during H2O2-induced oxidative stress, a nonperoxidative route of H2O2 cytotoxicity was also identified, which was expressed in the complete absence of cardiomyocyte-membrane peroxidation. The latter mode of H2O2-induced cardiomyocyte injury involved ATP loss such that membrane peroxidation and cardiomyocyte disruption on the one hand and cellular de-energization on the other could be completely dissociated.(ABSTRACT TRUNCATED AT 400 WORDS)

Role of calcium and other ions in reperfusion injury

Calcium-related mechanisms may play a role in several aspects of reperfusion injury. One proposal is that internal cytosolic calcium concentration is elevated early in the reperfusion period and that excess oscillations of calcium can very significantly contribute to reperfusion ventricular arrhythmias. Alternate hypotheses, such as those involving free radicals and the local tissue renin-angiotensin system, can be married to the existing hypothesis. Furthermore, the hypothesis allows for a role of the sodium-calcium exchange system and the proton-sodium exchanger. The hypothesis also provides an explanation for "stunning," as it is proposed that early excessive cytosolic calcium damages the organelles regulating the contractile cycle, which subsequently develops into imperfect functioning of the contractile apparatus. Calcium antagonist drugs given during the ischemic period may lessen reperfusion injury by decreasing the severity of ischemic damage. When given at the time of reperfusion, results are complex and to some extent conflicting. The biggest challenge is to understand how relatively low doses of calcium antagonists given after the onset of reperfusion help to decrease delayed reperfusion "stunning." A logical but untested proposal is that calcium antagonists help to prevent delayed contraction-band necrosis, one of the causes of delayed no-reflow.

Mechanism of the effect of exogenous fructose 1,6-bisphosphate on myocardial energy metabolism

The effects of fructose 1,6-bisphosphate (F-1,6-P2) on the isolated Langendorff-perfused heart were studied by monitoring flavoprotein fluorescence, oxygen consumption (MVO2), coronary flow (Fc), systolic intraventricular pressure (Psys), diastolic intraventricular pressure, and contraction frequency. The cellular energy state and cytosolic pH were determined by means of 31P nuclear magnetic resonance. Infusion of 5 mM F-1,6-P2 caused a rapid shift toward reduction in the flavoprotein redox state and initial 50% and 44% decreases in Psys and MVO2, respectively. After a partial recovery, these measures remained 11% and 25% below the basal value. Concomitantly, after an initial transient increase of 13%, Fc remained 17% lower than in the basal state. When the F-1,6-P2 concentration was subsequently increased to 10 mM, psys and MVO2 dropped temporarily to 31% and 29% of the basal value and then remained at 50% and 53%, respectively. Simultaneously, a brief increase was observed in Fc, which then fell 34% below the basal value. Rapid reoxidation of the flavoproteins and increases in MVO2, Psys, and Fc occurred on discontinuation of the F-1,6-P2 infusion. 31P nuclear magnetic resonance during infusions of both 5 and 10 mM F-1,6-P2 revealed a decrease in cytosolic inorganic phosphate and a tendency to increase creatine phosphate, suggesting elevation in the cellular energy state. No changes in intracellular pH occurred as estimated from the chemical shift of the nuclear magnetic resonance of inorganic phosphate. F-1,6-P2 (5 mM and 10 mM) lowered the free Ca2+ concentration in the Krebs-Henseleit bicarbonate buffer (by 32% and 47%, respectively). This probably explains the effects of F-1,6-P2 on mechanical work performance and cellular respiration. A direct metabolic effect also exists, however, because flavoprotein reduction by F-1,6-P2 could be observed in the K(+)-arrested heart, where its effects on MVO2 were minimal. This redox effect may not be caused by changes in free Ca2+ concentration because it could not be reproduced by infusion of EGTA.

Therapeutic potential of vitamin E against myocardial ischemic-reperfusion injury

Myocardial ischemia is a disease process characterized by reduced coronary flow such that the supply of nutritive blood to heart muscle (myocardium) is insufficient for normal myocardial aerobic metabolism. Prompt reestablishment of coronary flow by invasive and noninvasive clinical procedures is the most direct and effective means of limiting myocardial damage in ischemic heart disease patients, although reperfusion carries with it an injury component which may reflect, at least to some degree, the toxic effects of partially reduced oxygen species and their participation in degenerative cellular processes such as membrane lipid peroxidation. Vitamin E, a lipophilic, chain-breaking antioxidant, is a prominent membrane constituent in heart muscle, where it modulates/regulates various aspects of heart muscle-cell metabolism and function. Vitamin E's beneficial effects against experimentally induced oxidative damage to the heart, along with inverse epidemiological correlations between plasma vitamin E level and either anginal pain or mortality due to ischemic heart disease, suggest that vitamin E might have protective and therapeutic roles against myocardial ischemic-reperfusion injury. Laboratory investigations aimed at addressing this possibility have demonstrated that vitamin E supplementation protects isolated hearts against ischemic-reperfusion injury, and relatively more inconsistent and limited data document cardioprotective effects of vitamin E in some animal models of myocardial ischemia-reperfusion, especially when administered prior to the ischemic period. Clinical attempts to establish whether vitamin E has therapeutic benefit in ischemic heart disease patients remain inconclusive, having relied upon a variety of nonuniformly controlled protocols and a single, rather subjective endpoint (anginal pain). Consequently, although laboratory data constitute a conceptual context for and indirect support of the idea that vitamin E could be a cardioprotectant against ischemic-reperfusion injury, compelling clinical evidence regarding vitamin E's therapeutic potential in the ischemic heart-disease patient is lacking. Elective coronary revascularization would appear to provide an attractive clinical setting for evaluating the therapeutic efficacy of vitamin E in the context of cardiac ischemia-reperfusion. Further biochemical work would still be required to define how vitamin E exerts any cardioprotective effect observed in these patients.