微血栓形成和纤维蛋白原、载脂蛋白比值与大鼠急性心肌缺血再灌注无再流现象的相关性

摘要 目的：探讨微血栓形成和纤维蛋白原、载脂蛋白比值与大鼠急性心肌缺血再灌注无再流现象的相关性。方法：选择70只SD大鼠构建大鼠急性心肌缺血再灌注模型,根据再灌注后有无再流分为2组,分别为无再流组（n=42）和有再流组（n=28）。分析各组大鼠血流动力学、微血栓形成、纤维蛋白原、载脂蛋白比值以及血清细胞因子水平,并分析微血栓形成和纤维蛋白原、载脂蛋白比值与大鼠急性心肌缺血再灌注无再流现象的相关性。结果：有再流组大鼠HR和LVEDP值、纤维蛋白原水平、VCAM-1值显著高于无再流组,而SBP、DBP和LVSP值、微血栓形成数量、ApoB值和ApoB/ApoA1值、P-selectin、ICAM-1、IL-6和IL-10值则显著低于无再流组,差异均有统计学意义（P<0.05）。微血栓形成（r=0.654,P=0.005）和载脂蛋白比值（r=0.582,P=0.004）与大鼠急性心肌缺血再灌注无再流现象之间存在正相关关系;纤维蛋白原（r=-0.552,P=0.002）与大鼠急性心肌缺血再灌注无再流现象之间存在负相关关系。结论：微血栓形成和纤维蛋白原、载脂蛋白比值与急性心肌缺血再灌注无再流现象之间存在一定的相关性,三者可作为急性心肌缺血再灌注无再流现象的预测因子。     

"Ischemia/reperfusion" for stem cells of two "critical" cell renewal systems of organism

In this article is presented the result of the experiments on mice-hybrids F1(CBA x C57B1/6), which indicates the presence of the reaction of "ischemia/reperfusion" for stem cells of two "critical" cell renewal systems of organism (bone marrow and intestinal epithelium) during the irradiation under the conditions of hypoxic radioprotector application. The additional injection of the source of nitric oxide radicals-sodum nitroprusside (SNT) to the mice right after the irradiation under the conditions of hypoxic protection by serotonin, resulted the substantial increase of the survival rate of hematopoietic stem cells (registered by the methods of endogenous and exogenous colony forming in spleen) and stem cells of intestinal epithelium (registered by the method of intestinal "microcolonies"). The similar radioprotective effect was also registered during the test of survival rate of mice under tests of "bone marrow" and "intestinal" forms of radiation lethality that is evidence of the importance of the realization of phenomenon "ischemia/reperfusion" in the reaction of whole organism on the acute radiation injury. As SNP weakens the manifestation apoptosis and necrosis through competition with active forms of oxygen (AFO) during the period of "reperfusion" on basis of the found out phenomenon experimental model for studying mechanisms of stem cells damage in vivo induced by AFO and for the search of the modifiers weakening or strengthening such damage can be developed.     

Postconditioning fails to improve no reflow or alter infarct size in an open-chest rabbit model of myocardial ischemia-reperfusion

Postconditioning (PoC) with brief intermittent ischemia after myocardial reperfusion has been shown to lessen some elements of postischemic injury including arrhythmias and, in some studies, the size of myocardial infarction. We hypothesized that PoC could improve reflow to the risk zone after reperfusion. Anesthetized, open-chest rabbits were subjected to 30 min of coronary artery occlusion followed by 3 h of reperfusion. In protocol 1, rabbits were randomly assigned to the control group (n = 10, no further intervention after reperfusion) or to the PoC group, which consisted of four cycles of 30-s reocclusions with 30 s of reperfusion in between starting at 30 s after the initial reperfusion (4 x 30/30, n = 10). In protocol 2, rabbits were assigned to the control group (n = 7) or the PoC group, which received PoC consisting of four cycles of 60-s intervals of ischemia and reperfusion starting at 30 s after the initial reperfusion (4 x 60/60, n = 7). No reflow was determined by injecting thioflavine S (a fluorescent marker of capillary perfusion), risk zone by blue dye, and infarct size by triphenyltetrazolium chloride. In protocol 1, there were no statistical differences in hemodynamics, ischemic risk zone, or infarct size (35 +/- 6% of the risk zone in the PoC group vs. 29 +/- 4% in the control group, P = 0.38) between the groups. Similarly, in protocol 2, PoC failed to reduce infarct size compared with the control group (45 +/- 4% of the risk zone in the PoC group vs. 42 +/- 6% in the control group, P = 0.75). There was a strong correlation in both protocols between the size of the necrotic zone and the portion of the necrotic zone that contained an area of no reflow. However, PoC did not affect this relationship. PoC did not reduce infarct size in this model, nor did it reduce the extent of the anatomic zone of no reflow, suggesting that this intervention may not impact postreperfusion microvascular damage due to ischemia.     

Real-time continuous-flow spin trapping of hydroxyl free radical in the ischemic and post-ischemic myocardium

Real-time monitoring of spin-trapped oxygen-derived free radicals released by the isolated ischemic and reperfused rat heart has been achieved by ESR analysis of the coronary effluents using continuous flow detection and high-speed acquisition techniques. Two nitrone spin traps 5,5-dimethyl pyrroline 1-oxide (Me2PnO) and 3,3,5,5-tetramethyl pyrroline 1-oxide (MePnO) have been separately perfused at a concentration of 40 mM during a sequence of 50 min of low-flow ischemia (1 ml/min) followed by 30 min of global ischemia and subsequent reperfusion at the control flow rate (14 ml/min). ESR spectra were sequentially obtained in 5-min or 30-s blocks during low-flow ischemia and reperfusion, respectively. 1. The results show the formation of OH. free radicals in the ischemic and reperfused heart, as demonstrated by the observation of Me2PnO-OH (aN = aH = 14.9 G; g = 2.0053) and Me4PnO-OH (aN = 15.2 G, aH = 16.8 G; g = 2.0055) spin adducts. There is no evidence of significant biological carbon-centered or peroxyl free radicals spin-adduct formation in the coronary effluents or in lipid extracts analyzed after reflow. 2. The OH. generation began 15-20 min after the onset of ischemia and was moderate, peaking at 30-40 min. During reperfusion, an intense formation of OH. spin adducts was observed, with a maximum at 30-60 s and a further gradual decrease over the following 2 min. 3. Cumulative integrated values of the amount of spin adducts released during the ischemic period show a Me2PnO-OH level fourfold greater than that of Me4PnO-OH. It was 2.5 times greater during reflow, reflecting slower kinetics with the more stable Me4PnO. 4. The original ESR detection technique developed in this study allows accurate real-time quantitative monitoring of the oxygen-derived free radicals generated during myocardial injury. It might provide a quick and reliable new means for assessing the efficacy of free-radical inhibitors.     

Ischemic Modification of Cerebrocortical Membranes: 5-Hydroxytryptamine Receptors, Fluidity, and Inducible In Vitro Lipid Peroxidation

The effect of ischemia on the properties of 5-hydroxytryptamine1A + B (5-HT1A+B) and 5-hydroxytryptamine1B (5-HT1B) binding sites, physical-state "fluidity" of the membrane, and its susceptibility to peroxidation in vitro was investigated in the cerebral cortex of gerbils. Ischemia was induced by bilateral carotid artery occlusion for 15 min alone or with release for 1 h. Ischemia both with and without reflow decreased the number of 5-HT1A + B and 5-HT1B binding sites, whereas ischemia and reflow altered the affinity for 5-HT1B binding sites. Resistance to the temperature-dependent increase in "fluidity" of the membrane was detected (by fluorescence anisotropy using 1,6-diphenyl-1,3,5-hexatriene as a probe) after ischemia and reflow but not in ischemia alone. Susceptibility of the membranes to Fe2+- and ascorbic acid-stimulated lipid peroxidation in vitro was decreased following ischemia and recirculation only. These findings strongly suggest that the composition and the function of the membrane are markedly disturbed during recirculation after ischemia.     

Sympathetic and parasympathetic regulation of the heart in transitory coronary insufficiency

Experiments were made on 480 rats and 60 rabbits with transitory insufficiency (duration of myocardial ischemia 10.40 and 120 min the length of subsequent reperfusion 40-60 min). It was discovered that there was natural development of the phenomenon of limitation of drawing the heart in direct and reflectory reactions of the circulation system within the increase of duration of local ischemia and the beginning of the subsequent reperfusion. The phenomenon of "limitation", which is realized with the involvement of sympathetic and parasympathetic mechanisms, promotes a decrease of the extent of heart alteration during its local ischemia and increase of reparative process in the heart at the reperfusion period.     

Quantitation of particles in the freeze-fractured nuclear membrane after renal ischemia.

Changes in the number and sizes of membrane-associated particles have been quantitated in the protoplasmic (P) and exoplasmic (E) fracture faces of the outer membrane of nuclei isolated from the inner cortex following renal ischemia and reflow in the rat. No changes were observed in the inner nuclear membrane. After 20-min ischemia, the number of particles in both fracture faces decreased. With reflow, the total number of particles decreased after both 20- and 60-min ischemia. The partition coefficient (Kp = CPF/CEF) increased from 10 to 11 and 17 at 20- and 60-min ischemia then fell below control values to a Kp of 7 after 120 min. After reflow, Kp steadily decreased except after 20-min ischemia followed by 240-min reflow when Kp began to rise. The sizes of particles were predominantly 60 A in the P face of control outer membranes but became larger after ischemia. After 20- and 60-min ischemia with reflow, the size distribution became more normal. The shifts in particle numbers and sizes seem to indicate modifications within the membrane resulting from ischemia.     

Microvascular reperfusion injury: rapid expansion of anatomic no reflow during reperfusion in the rabbit

The aim was to define the degree and time course of reperfusion-related expansion of no reflow. In five groups of anesthetized, open-chest rabbits (30-min coronary occlusion and different durations of reperfusion), anatomic no reflow was determined by injection of thioflavin S at the end of reperfusion and compared with regional myocardial blood flow (RMBF; radioactive microspheres) and infarct size (triphenyltetrazolium). The area of no reflow progressively increased from 12.2 +/- 4.2% of the risk area after 2 min of reperfusion to 30.8 +/- 3.1% after 2 h and 34.9 +/- 3.3% after 8 h and significantly correlated with infarct size after 1 h of reperfusion (r = 0.88-0.97). This rapid expansion of no reflow predominantly occurred during the first 2 h, finally encompassing approximately 80% of the infarct size, and was accompanied by a decrease of RMBF within the risk area, being hyperemic after 2 min of reperfusion (3.78 +/- 0.75 ml x min(-1) x g(-1)) and plateauing at a level of approximately 0.9 ml x min(-1) x g(-1) by 2 and 8 h of reperfusion (preischemic RMBF: 2.06 +/- 0.01 ml x min(-1) x g(-1)). The development of macroscopic hemorrhage lagged behind no reflow, was closely correlated with it, and may be the consequence of microvascular damage.     

Transient Spinal Cord Ischemia in Rat: The Time Course of Spinal FOS Protein Expression and the Effect of Intraischemic Hypothermia (27°C)

1. In the present study, we characterize the time course of spinal FOS protein expression after transient noninjurious (6-min) or injurious (12-min) spinal ischemia induced by inflation of a balloon catheter placed into the descending thoracic aorta. In addition, this work examined the effects of spinal hypothermia on FOS expression induced either by ischemia or by potassium-evoked depolarization (intrathecal KCl).2. Short-lasting (6-min) spinal ischemia evoked a transient FOS protein expression. The peak expression was seen 2 hr after reperfusion in all laminar levels in lumbosacral segments. At 4 hr of reperfusion, more selective FOS expression in spinal interneurons localized in the central part of laminae V–VII was seen. At 24 hr no significant increase in FOS protein was detected.3. After 12 min of ischemia and 2 hr of reflow, nonspecific FOS expression was seen in both white and gray matter, predominantly in nonneuronal elements. Intrathecal KCl-induced FOS expression in spinal neurons in the dorsal horn and in the intermediate zone. Spinal hypothermia (27°C) significantly suppressed FOS expression after 6 or 12 min of ischemia but not after KCl-evoked depolarization.4. Data from the present study show that an injurious (but not noninjurious) interval of spinal ischemia evokes spinal FOS protein expression in glial cells 2 hr after reflow. The lack of neuronal FOS expression corresponds with extensive neuronal degeneration seen in this region 24 hr after reflow. Noninjurious (6-min) ischemia induced a transient, but typically neuronal FOS expression. The significant blocking effect of hypothermia (27°C) on the FOS induction after ischemia but not after potassium-evoked depolarization also suggests that simple neuronal depolarization is a key trigger in FOS induction.     

Flow heterogeneity following global no-flow ischemia in isolated rabbit heart

The purpose of this study was to evaluate flow heterogeneity and impaired reflow during reperfusion after 60-min global no-flow ischemia in the isolated rabbit heart. Radiolabeled microspheres were used to measure relative flow in small left ventricular (LV) segments in five ischemia + reperfused hearts and in five nonischemic controls. Relative flow heterogeneity was expressed as relative dispersion (RD) and computed as standard deviation/mean. In postischemic vs. preischemic hearts, RD was increased for the whole LV (0.92 +/- 0.41 vs. 0.37 +/- 0.07, P < 0.05) as well as the subendocardium (Endo) and subepicardium considered separately (1.28 +/- 0.74 vs. 0.30 +/- 0.09 and 0.69 +/- 0.22 vs. 0.38 +/- 0.08; P < 0.05 for both comparisons, respectively) during early reperfusion. During late reperfusion, the increased RD for the whole LV and Endo remained significant (0.70 +/- 0.22 vs. 0.37 +/- 0.07 and 1.06 +/- 0.55 vs. 0.30 +/- 0.09; P < 0.05 for both comparisons, respectively). In addition to the increase in postischemic flow heterogeneity, there were some regions demonstrating severely impaired reflow, indicating that regional ischemia can persist despite restoration of normal global flow. Also, the relationship between regional and global flow was altered by the increased postischemic flow heterogeneity, substantially reducing the significance of measured global LV reflow. These observations emphasize the need to quantify regional flow during reperfusion after sustained no-flow ischemia in the isolated rabbit heart.     

Ischemic postconditioning during reperfusion activates Akt and ERK without protecting against lethal myocardial ischemia-reperfusion injury in pigs

Transient episodes of ischemic preconditioning (PC) render myocardium protected against subsequent lethal injury after ischemia and reperfusion. Recent studies indicate that application of short, repetitive ischemia only during the onset of reperfusion after the lethal ischemic event may obtain equivalent protection. We assessed whether such ischemic postconditioning (Postcon) is cardioprotective in pigs by limiting lethal injury. Pentobarbital sodium-anesthetized, open-chest pigs underwent 30 min of complete occlusion of the left anterior descending coronary artery and 3-h reflow. PC was elicited by two cycles of 5-min occlusion plus 10-min reperfusion before the 30-min occlusion period. Postcon was elicited by three cycles of 30-s reperfusion, followed by 30-s reocclusion, after the 30-min occlusion period and before the 3-h reflow. Infarct size (%area-at-risk using triphenyltetrazolium chloride macrochemistry; means +/- SE) after 30 min of ischemia was 26.5 +/- 5.2% (n = 7 hearts/treatment group). PC markedly limited myocardial infarct size (2.8 +/- 1.2%, n = 7 hearts/treatment group, P < 0.05 vs. controls). However, Postcon had no effect on infarct size (37.8 +/- 5.1%, n = 7 hearts/treatment group). Within the subendocardium, Postcon increased phosphorylation of Akt (74 +/- 12%) and ERK1/2 (56 +/- 10%) compared with control hearts subjected only to 30-min occlusion and 15-min reperfusion (P < or = 0.05), and these changes were not different from the response triggered by PC (n = 5 hearts/treatment group). Phosphorylation of downstream p70S6K was also equivalent in PC and Postcon groups. These data do not support the hypothesis that application of 30-s cycles of repetitive ischemia during reperfusion exerts a protective effect on pig hearts subjected to lethal ischemia, but this is not due to a failure to phosphorylate ERK and Akt during early reperfusion.     

Effects of barium and 5-hydroxydecanoate on the electrophysiologic response to acute regional ischemia and reperfusion in rat hearts

The aim of this work was to investigate the role of the inward rectifying (K₁) and the sarcolemmal ATP-sensitive K⁺ (K-ATP) channels in the electrical response to regional ischemia and the subsequent development of ventricular tachyarrhythmias on reflow (RA). Surface electrograms (ECG) and the transmembrane potential from subepicardial left ventricular cells were recorded in spontaneously beating rat hearts perfused with buffer alone (controls) or exposed to 100 M BaCl₂ or 100 M 5-hydroxydecanoate (5-HD) to block either K₁ or K-ATP channels respectively. After 20 min of equilibration and 10 min of control recordings, the left anterior descending coronary artery was occluded for 10 min. This was followed by reperfusion. The effects of regional ischemia as well as those of reperfusion (10 min) were recorded throughout. In the three groups, ischemia induced a modest decrease in heart rate and a sharp reduction in resting potential within 3 min. The latter as well as the accompanying depression of propagated electrical activity were enhanced by Ba²⁺. A partial recovery of the resting potential was observed in all groups during the last 2 min of coronary occlusion. Concomitantly, a slight reduction in the action potential duration was found in the control hearts. This effect was blocked by 5-HD. Under Barium the action potential duration increased by a factor of 3 and its ischemic variations were minimized. Severe sustained ventricular tachyarrhythmias developed on reflow in the controls and in the 5-HD exposed hearts. Barium limited the duration of arrhythmic episodes to a few seconds. Our data indicate that the initial electrical effects of ischemia are unrelated to activation of ATP sensitive K⁺ channels and that g_K1 dominates the K⁺ membrane conductance at this stage. Furthermore, they show that action potential lengthening limits the duration of arrhythmic episodes triggered by reperfusion. This suggests that electrical heterogeneity plays an important role in the perpetuation of reperfusion arrhythmias.     

Protective effect of a low K+ cardioplegic solution on myocardial Na,K-ATPase activity.

Long duration ischemia in hypothermic conditions followed by reperfusion alters membrane transport function and in particular Na,K-ATPase. We compared the protective effect of two well-described cardioplegic solutions on cardiac Na,K-ATPase activity during reperfusion after hypothermic ischemia. Isolated perfused rat hearts (n = 10) were arrested with CRMBM or UW cardioplegic solutions and submitted to 12 hr of ischemia at 4 degrees C in the same solution followed by 60 min of reperfusion. Functional recovery and Na,K-ATPase activity were measured at the end of reperfusion and compared with control hearts and hearts submitted to severe ischemia (30 min at 37 degrees C) followed by reflow. Na,K-ATPase activity was not altered after 12 hr of ischemia and 1 hr reflow when the CRMBM solution was used for preservation (55 +/- 2 micromolPi/mg prot/hr) compared to control (53 +/- 2 micromol Pi/mg prot/hr) while it was significantly altered with UW solution (44 +/- 2 micromol Pi/mg prot/hr, p < 0.05 vs control and CRMBM). Better preservation of Na,K-ATPase activity with the CRMBM solution was associated with higher functional recovery compared to UW as represented by the recovery of RPP, 52 +/- 12% vs 8 +/- 5%, p < 0.05 and coronary flow (70 +/- 2% vs 50 +/- 8%, p < 0.05). The enhanced protection provided by CRMBM compared to UW may be related to its lower K+ content.     

Measurement and characterization of postischemic free radical generation in the isolated perfused heart

Electron paramagnetic resonance spectroscopy has been applied to measure radical generation in the postischemic heart; however, there is controversy regarding the methods used and the conclusion as to whether radicals are generated. In order to resolve this controversy, direct and spin trapping measurements of the time course and mechanisms of radical generation were performed in isolated perfused rabbit hearts. In reperfused tissue, 3 prominent radical signals are observed: A, isotropic g = 2.004 suggestive of a semiquinone; B, anisotropic g parallel = 2.033 and g perpendicular = 2.005 suggestive of ROO.; and C, a triplet g = 2.000 and aN = 24 G suggestive of a nitrogen centered radical. B and C, however, are highly labile and disappear at temperatures probably encountered in some previous studies. In normally perfused hearts, A is observed with only small amounts of B and C. During ischemia, B and C increase reaching a maximum after 45 min while A decreases. On reflow with oxygenated perfusate all 3 signals increase. With varying duration of ischemia and reflow, peak signal intensities occurred after 15 s of reflow following 30 min of ischemia. Reperfusion with superoxide dismutase, deferoxamine, or mannitol abolished the reperfusion increase of B. Measurements performed with the spin trap 5,5'-dimethyl-1-pyrroline-N-oxide (DMPO) demonstrated a similar time course of radical generation with prominent DMPO-OH and DMPO-R signals peaking between 10 and 20 s of reflow. Superoxide dismutase and deferoxamine also quenched these signals. Thus, .O2- derived .OH, R., and ROO. radicals are generated in postischemic myocardium. While the experimental techniques used can result in loss of intrinsic radicals and generation of extraneous radicals, with proper care and controls valid measurements of free radicals in biological tissues can be performed.     

The balance between the production of tumor necrosis factor-alpha and interleukin-10 determines tissue injury and lethality during intestinal ischemia and reperfusion

A major goal in the treatment of acute ischemia of a vascular territory is to restore blood flow to normal values, i.e. to "reperfuse" the ischemic vascular bed. However, reperfusion of ischemic tissues is associated with local and systemic leukocyte activation and trafficking, endothelial barrier dysfunction in postcapillary venules, enhanced production of inflammatory mediators and great lethality. This phenomenon has been referred to as "reperfusion injury" and several studies demonstrated that injury is dependent on neutrophil recruitment. Furthermore, ischemia and reperfusion injury is associated with the coordinated activation of a series of cytokines and adhesion molecules. Among the mediators of the inflammatory cascade released, TNF-alpha appears to play an essential role for the reperfusion-associated injury. On the other hand, the release of IL-10 modulates pro-inflammatory cytokine production and reperfusion-associated tissue injury. IL-1beta, PAF and bradykinin are mediators involved in ischemia and reperfusion injury by regulating the balance between TNF-alpha and IL-10 production. Strategies that enhance IL-10 and/or prevent TNF-alpha concentration may be useful as therapeutic adjuvants in the treatment of the tissue injury that follows ischemia and reperfusion.     

Cardioprotective effects of erythropoietin in the reperfused ischemic heart: a potential role for cardiac fibroblasts

Erythropoietin has recently been shown to have effects beyond hematopoiesis such as prevention of neuronal and cardiac apoptosis secondary to ischemia. In this study, we evaluated the in vivo protective potential of erythropoietin in the reperfused rabbit heart following ventricular ischemia. We show that "preconditioning" with erythropoietin activates cell survival pathways in myocardial tissue in vivo and adult rabbit cardiac fibroblasts in vitro. These pathways, activated by erythropoietin in both whole hearts and cardiac fibroblasts, are also activated acutely by ischemia/reperfusion injury. Moreover, in vivo studies indicate that erythropoietin treatment either prior to or during ischemia significantly enhances cardiac function and recovery, including left ventricular contractility, following myocardial ischemia/reperfusion. Our data indicate that a contributing in vivo cellular mechanism of this protection is mitigation of myocardial cell apoptosis. This results in decreased infarct size as evidenced by area at risk studies following in vivo ischemia/reperfusion injury, translating into more viable myocardium and less ventricular dysfunction. Therefore, erythropoietin treatment may offer novel protection against ischemic heart disease and may act, at least in part, by direct action on cardiac fibroblasts and myocytes to alter survival and ventricular remodeling.     

The essential role of the intestinal microbiota in facilitating acute inflammatory responses

The restoration of blood flow, i.e., reperfusion, is the treatment of choice to save viable tissue following acute ischemia of a vascular territory. Nevertheless, reperfusion can be accompanied by significant inflammatory events that limit the beneficial effects of blood flow restoration. To evaluate the potential role of the intestinal microbiota in facilitating the development of tissue injury and systemic inflammation, germ-free and conventional mice were compared in their ability to respond to ischemia and reperfusion injury. In conventional mice, there was marked local (intestine) and remote (lung) edema formation, neutrophil influx, hemorrhage, and production of TNF-alpha, KC, MIP-2, and MCP-1. Moreover, there was an increase in the concentration of serum TNF-alpha and 100% lethality. In germ-free mice, there was no local, remote, or systemic inflammatory response or lethality after intestinal ischemia and reperfusion and, in contrast to conventional mice, germ-free animals produced greater amounts of IL-10. Similar results were obtained after administration of LPS, i.e., little production of TNF-alpha or lethality and production of IL-10 after LPS in germ-free mice. Blockade of IL-10 with Abs induced marked inflammation and lethality in germ-free mice after ischemia and reperfusion or LPS administration, demonstrating that the ability of these mice to produce IL-10 was largely responsible for their "no inflammation" phenotype. This was consistent with the prevention of reperfusion-associated injury by the exogenous administration of IL-10 to conventional mice. Thus, the lack of intestinal microbiota is accompanied by a state of active IL-10-mediated inflammatory hyporesponsiveness.     

Superoxide anion production during reperfusion is reduced by an antineutrophil antibody after prolonged cerebral ischemia

Neutrophils may be involved in the pathophysiology of reperfusion injury following cerebral ischemia. One potential mechanism of reperfusion injury by neutrophils is through production of the superoxide anion. We hypothesized that, due to progressive endothelial damage during ischemia, neutrophil activation would be more prominent after longer periods of ischemia prior to reperfusion. Thus, neutrophils would contribute more to pathological processes such as superoxide anion formation after longer than after shorter periods of ischemia. A reversible middle cerebral artery occlusion model in rats was employed and superoxide anion concentration was measured with a cytochrome c coated electrode placed on the cortical penumbral region. Occlusion times were varied from 60 min to 2 h, and neutrophils were inhibited with an antiCD18 antibody administered prior to occlusion. Neutrophil accumulation and reduction with antibody treatment was confirmed immunohistochemically. Superoxide anion (O₂^•−) concentration was detected during the hours following 60 min of occlusion, and increased further with 2 h of occlusion. Treatment with the antiCD18 antibody had no effect on O₂^•− concentration during reperfusion in the 60–90 min occlusion groups, but O₂^•− concentration was significantly lower in the antiCD18 antibody treated group than in the control group during reperfusion after 120 min of ischemia. The antibody also reduced cortical neutrophil accumulation in the 120 min ischemia group. These results indicate for the first time that superoxide production by neutrophils becomes more important with longer periods of ischemia, and other quantitatively less important sources of superoxide predominate with shorter periods of ischemia. This phenomenon may explain some of the variation seen between different models of ischemia with different durations of ischemia when targeting reactive oxygen species, and supports an approach to combination therapy to extend the therapeutic window and reduce the deleterious effects of reperfusion.     

Extracellular Acidic Sulfur-Containing Amino Acids and γ-Glutamyl Peptides in Global Ischemia: Postischemic Recovery of Neuronal Activity Is Paralleled by a Tetrodotoxin-Sensitive Increase in Cysteine Sulfinate in the CA1 of the Rat Hippocampus

An excessive activation of the excitatory amino acid system has been proposed as one possible mediator of the ischemia-induced delayed death of CA1 pyramidal cells in the hippocampus. Using dialytrodes in the CA1 of the rat, we have investigated multiple-unit activity and extracellular changes in acidic sulfur-containing amino acids and gamma-glutamyl peptides during ischemia (20-min, four-vessel occlusion) and during 8 h of reflow. Multiple-unit activity was abolished during ischemia and for the following 1 h, but then recovered, gradually reaching preischemic levels after 8 h of reflow. Extracellular cysteate, cysteine sulfinate, and gamma-glutamyltaurine increased (1.5- to threefold) during ischemia, and extracellular glutathione and gamma-glutamylaspartate plus gamma-glutamylglutamine increased during early reflow (two- to threefold). The recovery of neuronal activity at 4-8 h was paralleled by an increase in extracellular cysteine sulfinate (2.5-fold at 8 h of reflow). Perfusion with 10 microM tetrodotoxin at 8 h of reflow abolished the multiple-unit activity and reduced extracellular cysteine sulfinate. Considering the glutamate-like properties of cysteine sulfinate, the observed postischemic increase may be involved in the development of the delayed neuronal death.     

Na+ overload-induced mitochondrial damage in the ischemic heart

Ischemia induces a decrease in myocardial contractility that may lead more or less to contractile dysfunction in the heart. When the duration of ischemia is relatively short, myocardial contractility is immediately reversed to control levels upon reperfusion. In contrast, reperfusion induces myocardial cell death when the heart is exposed to a prolonged period of ischemia. This phenomenon is the so-called "reperfusion injury". Numerous investigators have reported the mechanisms underlying myocardial reperfusion injury such as generation of free radicals, disturbance in the intracellular ion homeostasis, and lack of energy for contraction. Despite a variety of investigations concerning the mechanisms for ischemia and ischemia-reperfusion injury, ionic disturbances have been proposed to play an important role in the genesis of the ischemia-reperfusion injury. In this present study, we focused on the contribution of Na+ overload and mitochondrial dysfunction during ischemia to the genesis of this ischemia-reperfusion injury.