A comparative study on the antioxidant effects of hesperidin and ellagic acid against skeletal muscle ischemia/reperfusion injury

Abstract

The antioxidant effects of ellagic acid (EA) and hesperidin (HES) against skeletal muscle ischemia/reperfusion injury (I/R) were performed. Hindlimb ischemia has been induced by tourniquet occlusion for 2?h on left hindlimb. At the end of ischemia, the tourniquate has been removed and initiated reperfusion for 2?h. EA (100?mg/kg) has been applied orally before ischemia/reperfusion in the EA?+?I/R group. HES (100?mg/kg) has been given orally in the HES?+?I/R group. The left gastrocnemius muscle has been harvested and stored immediately at??80?°C until assessed for the levels of MDA and antioxidant enzymes activities. MDA level has statistically increased in I/R group (p?<?0.05) compared to other groups. The muscle tissue antioxidant enzymes activities were lower than the other groups in the I/R group (p?<?0.05). EA and HES treatments significantly reversed the damage level in I/R, also activity of tissue SOD increased in the EA?+?I/R and HES?+?I/R groups.     

Ascorbic acid prolongs the viability and stability of isolated perfused lungs: A mechanistic study using 31P and hyperpolarized 13C nuclear magnetic resonance

Ex vivo lung perfusion (EVLP) has recently shown promise as a means of more accurately gauging the health of lung grafts and improving graft performance post-transplant. However, reperfusion of ischemic lung promotes the depletion of high-energy compounds and a progressive loss of normal mitochondrial function, and it remains unclear how and to what extent the EVLP approach contributes to this metabolic decline. Although ascorbate has been used to mitigate the effects of ischemia–reperfusion injury, the nature of its effects during EVLP are also not clear. To address these uncertainties, this study monitored the energy status of lungs during EVLP and after the administration of ascorbate using ³¹P and hyperpolarized ¹³C NMR (nuclear magnetic resonance). Our experiments demonstrated that the oxidative phosphorylation capacity and pyruvate dehydrogenase flux of lungs decline during ex vivo perfusion. The addition of ascorbate to the perfusate prolonged lung viability by 80% and increased the hyperpolarized ¹³C bicarbonate signal by a factor of 2.7. The effect of ascorbate is apparently due not to its antioxidant quality but rather to its ability to energize cellular respiration given that it increased the lung’s energy charge significantly, whereas other antioxidants (glutathione and α-lipoic acid) did not alter energy metabolism. During ascorbate administration, inhibition of mitochondrial complex I with rotenone depressed energy charge and shifted the metabolic state of the lung toward glycolysis; reenergizing the electron transport chain with TMPD (N,N,N',N'-tetramethyl-p-phenylenediamine) recovered metabolic activity. This indicates that ascorbate slows the decline of the ex vivo perfused lung’s mitochondrial activity through an independent interaction with the electron transport chain complexes.     

Significance of myocardial eicosanoid production

Summary The precise role of eicosanoids in the development of myocardial injury during ischemia and reperfusion is still a matter of debate. Enhanced local production of these bioactive compounds appears to be a common response to tissue injury. Most likely, the cardiac tissue has the capacity to generate prostaglandins, thromboxanes as well as leukotrienes. Prostacyclin (PGI,) is the major eicosanoid produced by the jeopardized myocardium. In addition, at sites of tissue injury activation of platelets and infiltrating leukocytes results in the formation of considerable amounts of thromboxanes and leukotrienes. The production of eicosanoids requires prior release of arachidonic acid (AA) from phospholipids. Both ischemia and reperfusion are associated with a rise in the tissue level of AA. The absence of a proportional relationship between the tissue level of AA and the amounts of PGI, produced suggests that the sites of AA accumulation and PGI₂ formation are different. It is conceivable that AA accumulation is mainly confined to myocytes, whereas the capacity to synthesize PGI, mainly resides in vascular cells. Both beneficial and detrimental effects of eicosanoids on cardiac tissue have been described. Prostaglandins act as vasodilators. Besides, some of the prostaglandins, especially PGI,, are thought to possess cyto-protective properties. Thromboxanes and leukotrienes may impede blood supply by increasing smooth muscle tone. Besides, leukotrienes augment vascular permeability. Experimental studies, designed to evaluate the effect of pharmacological agents, like PGI₂-analogues and lipoxygenase and cyclo-oxygenase inhibitors, indicat that eicosanoids influence the outcome of myocardial injury. However, the delineation of the physiological significance of the locally produced eicosanoids is complicated by such factors as the wide variety of AA derivatives produced and the dose-dependency of their effects.     

The effect of oxidants on biomembranes and cellular metabolism

During the reductive process in the tissues, the aerobes generate a number of oxidants. Unless these oxidants are reduced, oxidative damage and cell death would occur. Oxidation of plasma membrane lipids leads to autocatalytic chain reactions which eventually alter the permeability of the cell. The role of oxidative damage in the pathophysiology of diabetic complications and ischemic reperfusion injury of myocardium, especially the changes in the channel activity which may lead to arrhythmia have been studied. Hyperglycemia activates aldose reductase which could efficiently reduce glucose to sorbitol in the presence of NADPH. Since NADPH is also aldose required by glutathione reductase for reducing oxidants, its diversion would lead to membrane lipid oxidation and permeability changes which are probably responsible for diabetic complications such as cataractogenesis, retinopathy, neuropathy etc. Antioxidants such as butylated hydroxy toluene (BHT) and also reductase inhibitors prevent or delay some of these complications. By using patch-clamp technique in isolated frog myocytes, we have shown that hydroxy radicals generated by ferrous sulfate and ascorbate as well as lipid peroxides such as t-butyl hydroperoxide facilitate the entry of Na⁺ by oxidizing Na⁺-channels. Increased intracellular Na⁺ leads to an increase in Na⁺/Ca²⁺ exchange. The increased Na⁺ concentration by itself may produce electrical disturbance which would result in arrhythmia. Increased Ca²⁺ may affect proteases and may help in the conversion of xanthine dehydrogenase to xanthine oxidase, consequently increased production of super oxide radicals. Increased membrane lipid peroxidation and other oxygen free-radical associated membrane damage in myocytes has been demonstrated.     

清醒狗短暂缺血心肌复灌注时舒缩功能的变化

在狗的心脏上装入微超声探头和高精度微压力传感器,手术后两星期,在清醒状态下给予左冠状动脉旋支阻断三分钟。在复灌注过程中,观察到血液动力学指标与收缩期心室壁厚度(WT)迅速恢复正常;但在 dWT/dt—WT 环形图上出现舒张早期异常相,其形状与缺血过程不同。低氧和急遽冠状动脉过度充盈可以产生此种异常图形。我们推测,心肌缺血可能促使一些产物的形成,复灌注时它使冠脉过度舒张,冠脉灌注增加,从而造成舒张早期急遽充盈而形成了此种异常的形图。     

Formation of Hydroxyl Radicals in Biological Systems. Does Myoglobin Stimulate Hydroxyl Radical Formation from Hydrogen Peroxide?

Incubation of horse-heart oxymyoglobin or metmyoglobin with excess H₂O₂ causes formation of myoglobin(IV), followed by haem degradation. At the time when haem degradation is observed, hydroxyl radicals (.OH) can be detected in the reaction mixture by their ability to degrade the sugar deoxyribose. Detection of hydroxyl radicals can be decreased by transferrin or by OH scavengers (mannitol, arginine, phenylalanine) but not by urea. Neither transferrin nor any of these scavengers inhibit the haem degradation. It is concluded that intact oxymyoglobin or metmyoglobin molecules do not react with H₂O₂ to form OH detectable by deoxyribose, but that H₂O₂ eventually leads to release of iron ions from the proteins. These released iron ions can react to form OH outside the protein or close to its surface. Salicylate and the iron chelator desferrioxamine stabilize myoglobin and prevent haem degradation. The biological importance of OH generated using iron ions released from myoglobin by H₂O₂ is discussed in relation to myocardial reoxygenation injury.     

Singlet oxygen: a potential culprit in myocardial injury?

The purpose of this study was to explore the role of singlet oxygen in cardiovascular injury. To accomplish this objective, we investigated the effect of singlet oxygen [generated from photoactivation of rose-bengal] on the calcium transport and Ca²⁺-ATPase activity of cardiac sarcoplasmic reticulum and compared these results with those obtained by superoxide radical, hydrogen peroxide and hydroxyl radical. Isolated cardiac SR exposed to rose bengal (10 nM) irradiated at (560 nm) produced a significant inhibition of Ca ²⁺ uptake; from 2.27 ± 0.05 to 0.62 ± 0.05 µmol Ca⁺/mg.min (mean ± SE) (P < 0.01) and Ca²⁺-ATPase activity from 2.08 ± 0.05 µmol Pi/min. mg to 0.28 ± 0.04 µmol Pi/min. mg (mean ± SE) (P < 0.01). The inhibition of calcium uptake and Ca²⁺-ATPase activity by rose bengal derived activatedoxygen (singlet oxygen) was dependent on the duration of exposure and intensity of light. The singlet oxygen scavengers ascorbic acid and histidine significantly protected SR Ca²⁺-ATPase against rose bengal derived activated oxygen species but superoxide dismutase and catalase did not attenuate the inhibition. SDS-polyacrylamide gel electrophoresis of SR exposed to photoactivated rose bengal up to 14 min, demonstrated complete loss of Ca²⁺-ATPase monomer band which was significantly protected by histidine. Irradiation of rose bengal also caused an 18% loss of total sulfhydryl groups of SR. On the other hand, superoxide (generated from xanthine oxidase action on xanthine) and hydroxyl radical (0.5 mM H₂O₂ + Fe²⁺ -EDTA) as well as H₂O₂ (12 mM) were without any effect on the 97,000 dalton Ca²⁺-ATPase band ofsarcoplasmic reticulum. The results suggest that oxidative damage of cardiac sarcoplasmic reticulum may be mediated by singlet oxygen. This may represent an important mechanism by which the oxidative injury to the myocardium induces both a loss of tension development and arrhythmogenesis.     

Toxicity oft-butylhydroperoxide in hepatocyte monolayers exposed to hypoxia and reoxygenation

Summary Inasmuch as it is known that the toxicity of anesthetic agents is potentiated by hypoxia and that the reductive metabolism of these agents results in the formation of lipid hydroperoxides, we investigated the toxicity of hydroperoxides under low-oxygen concentrations. We found that hypoxia exacerbates the toxicity oft-butyl hydroperoxide, shifting the dose-response curve oft-butyl hydroperoxide vs. lysis of hepatocytes approximately an order of magnitude to the left. Furthermore, although at the end of a 4-h exposure to 0.5% O₂ hepatocyte monolayers seemed normal by three indices (release of⁵¹Cr and serum glutamate transaminase or exclusion of trypan blue), they were completely lysed after an additional 20 h reoxygenation at 20%. O₂. In contrast, monolayers exposed to 2% O₂ for 4 h seemed normal after 20 h reoxygenation. However, cells exposed to both a subtoxic dose of hydroperoxide and 4 h of 2% O₂, although seeming healthy at the end of the hypoxic period, were completely lysed within 20 h after reoxygenation. The study was supported by grant OH 00978 from the National Institutes for Occupational Safety and Health, Atlanta, Georgia.     

丹参酮Ⅱ－A磺酸钠对鼠肝线粒体功能的影响

利用大鼠肝脏线粒体为材料,以琥珀酸为底物,研究了不同浓度的丹参酮Ⅱ－Ａ磺酸钠对线粒体态４、态３呼吸及呼吸控制率,线粒体跨膜电位,线粒体呼吸链复合体（Ⅱ＋Ⅲ）电子传递及质子转移活性的影响。结果证明丹参酮ⅡＡ－磺酸钠是线粒体呼吸链复合体（Ⅱ＋Ⅲ）的有效抑制剂。文中对丹参酮ⅡＡ－磺酸钠在心肌缺血再灌注过程中的保护作用的分子机理进行了讨论。     

Release of 6-KETO-PGF1α and thromboxane B2 in late appearing cardioprotection induced by the stable PGI analogue: 7-OXO-PGI

We have shown earlier that prostacylin (PGI₂) and its stable analogue: 7-oxo-prostacyclin(7-OXO) may induce a prolonged, late appearing (24–48 h after drug administration), dose dependent protection of the heart from harmful consequences of a subsequent severe ischaemic stress, such as myocardial ischaemia, life-threatening ventricular arrhythmias and early ischaemic morphological changes. In an other study we observed that a similar but shortlived (less than 1 h) cardioprotection, induced by preconditioning brief coronary artery occlusions, is greatly reduced by blockade of the cyclooxygenase pathway, suggesting that prostanoids might play a role in this shortlasting protection.Objective of our present study was to elucidate the importance of some arachidonic acid (AA) metabolites, such as PGI₂ and thromboxane A₂ (TXA₂) in the mechanism of the late appearing, prolonged cardioprotection. Estimation of the metabolites: 6-keto-PGF₁ (6-KETO) and thromboxane B₂ (TXB₂) was made from the perfusate of isolated Langendorff hearts of guinea-pigs pretreated with 50 g/kg 7-OXO, 24 and 48 h before preparation. Pretreatment alone produced a slight, but significant elevation of 6-KETO (from 206±11 to 284±19 pg/ml/min after 24 h, and to 261±18 pg/ml/min after 48 h). No change was seen in TXB₂ production. Global ischaemia for 25 min (followed by 25 min reperfusion) markedly increased the release of both AA metabolites; maximal values were observed in the third min of reperfusion (6-KETO from 206±11 to 1275±55 pg/ml/min and TXB₂ from 29±4 to 172±12 pg/ml/min). All values returned to the preischaemic level by the 25th min of reperfusion. Ischaemic increase in 6-KETO level was significantly higher in the perfusate of hearts from pretreated animals (1507±73 pg/ml/min after 24 h, and 1398±54 pg/ml/min after 48 h) that in those of untreated controls. There was no difference in TXB₂ values. Thus both basal and ischaemic release of PGI₂ increased 24 and 48 h after pretreatment with 7-OXO but not TXA₂ production. Results suggest that endogenous prostanoids might play a role in late appearing cardioprotection.