Human thrombocytes are able to induce a myocardial dysfunction in the ischemic and reperfused guinea pig heart mediated by free radicals-role of the GPIIb/IIIa-blocker tirofiban

What do we know about platelets in myocardial ischemia-reperfusion injury and why is it important?

Myocardial ischemia-reperfusion injury (MIRI), the joint result of ischemic injury and reperfusion injury, is associated with poor outcomes in patients with acute myocardial infarction undergoing primary percutaneous coronary intervention. Accumulating evidence demonstrates that activated platelets directly contribute to the pathogenesis of MIRI through participating in the formation of microthrombi, interaction with leukocytes, secretion of active substances, constriction of microvasculature, and activation of spinal afferent nerves. The molecular mechanisms underlying the above detrimental effects of activated platelets include the homotypic and heterotypic interactions through surface receptors, transduction of intracellular signals, and secretion of active substances. Revealing the roles of platelet activation in MIRI and the associated mechanisms would provide potential targets/strategies for the clinical evaluation and treatment of MIRI. Further studies are needed to characterize the temporal (ischemia phase vs. reperfusion phase) and spatial (systemic vs. local) distributions of platelet activation in MIRI by multi-omics strategies. To improve the likelihood of translating novel cardioprotective interventions into clinical practice, basic researches maximally replicating the complexity of clinical scenarios would be necessary.

Platelets in Myocardial Ischemia/Reperfusion Injury

Coronary artery disease, including myocardial infarction (MI), remains a leading cause of global mortality. Rapid reperfusion therapy is key to the improvement of patient outcome but contributes substantially to the final cardiac damage. This phenomenon is called "ischemia/reperfusion injury (IRI)." The underlying mechanisms of IRI are complex and not fully understood. Contributing cellular and molecular mechanisms involve the formation of microthrombi, alterations in ion concentrations, pH shifts, dysregulation of osmolality, and, importantly, inflammation. Beyond their known action as drivers of the development of coronary plaques leading to MI, platelets have been identified as important mediators in myocardial IRI. Circulating platelets are activated by the IRI-provoked damages in the vascular endothelium. This leads to platelet adherence to the reperfused endothelium, aggregation, and the formation of microthrombi. Furthermore, activated platelets release vasoconstrictive substances, act via surface molecules, and enhance leukocyte infiltration into post-IR tissue, that is, via platelet-leukocyte complexes. A better understanding of platelet contributions to myocardial IRI, including their interaction with other lesion-associated cells, is necessary to develop effective treatment strategies to prevent IRI and further improve the condition of the reperfused myocardium. In this review, we briefly summarize platelet properties that modulate IRI. We also describe the beneficial impacts of antiplatelet agents as well as their mechanisms of action in IRI beyond classic effects.

Platelet Contributions to Myocardial Ischemia/Reperfusion Injury

Obstruction of a coronary artery causes ischemia of heart tissue leading to myocardial infarction. Prolonged oxygen deficiency provokes tissue necrosis, which can result in heart failure and death of the patient. Therefore, restoration of coronary blood flow (reperfusion of the ischemic area) by re-canalizing the affected vessel is essential for a better patient outcome. Paradoxically, sudden reperfusion also causes tissue injury, thereby increasing the initial ischemic damage despite restoration of blood flow (=ischemia/reperfusion injury, IRI). Myocardial IRI is a complex event that involves various harmful mechanisms (e.g., production of reactive oxygen species and local increase in calcium ions) as well as inflammatory cells and signals like chemokines and cytokines. An involvement of platelets in the inflammatory reaction associated with IRI was discovered several years ago, but the underlying mechanisms are not yet fully understood. This mini review focusses on platelet contributions to the intricate picture of myocardial IRI. We summarize how upregulation of platelet surface receptors and release of immunomodulatory mediators lead to aggravation of myocardial IRI and subsequent cardiac damage by different mechanisms such as recruitment and activation of immune cells or modification of the cardiac vascular endothelium. In addition, evidence for cardioprotective roles of distinct platelet factors during IRI will be discussed.

Effect of Platelet GPIIb/IIIa Receptor Blockade With MK383 on Infarct Size and Myocardial Blood Flow in a Canine Reocclusion Model

Platelet activation and aggregation during ischemia influence reperfusion-related myocyte necrosis, myocardial perfusion at the microvascular level, and thereby eventual recovery of cardiac performance. Inhibition of platelet activity therefore represents a worthwhile target to reduce cellular injury. The current study examined the effects of MK383 (tirofiban), a potent inhibitor of platelet aggregation, on infarct size and myocardial perfusion in canine subjects to either reocclusion (ie, 120-minute + 60-minute ischemia with intervening reperfusion) or prolonged occlusion (ie, 3 hours) followed by reperfusion (180 minutes). Platelet aggregation, infarct size (tetrazolium staining), coronary blood flow (flow probe), coronary vascular reserve, and myocardial perfusion (microspheres) were evaluated. MK383, administered at the time of reperfusion, produced a modest reduction of tissue necrosis (compared to saline-treated controls) in the reocclusion and prolonged occlusion studies. Blood flow in the infarct-related artery after coronary occlusion was comparable between treatment groups, as was myocardial perfusion in the deeper layers of the ischemic region; coronary vascular reserve decreased progressively during reperfusion. Of note, compensatory changes in blood flow within the adjacent nonischemic myocardium were not observed. In conclusion, we report that that limiting platelet aggregation during reperfusion impacted infarct development. Continued investigation into the mechanisms by which inhibition of platelet activity protects myocardium against ischemia-reperfusion injury and improves clinical outcomes is necessary.

A myocardial ischemia- and reperfusion-induced injury is mediated by reactive oxygen species released from blood platelets

In recent experimental studies, blood platelets have been found to exhibit some cardiodepressive effects in ischemic and reperfused guinea pig hearts independent of thrombus formation. These effects seemed to be mediated by reactive oxygen species (ROS). However, the source of these ROS - platelets or heart - remained still unknown. Isolated, buffer-perfused and pressure-volume work performing guinea pig hearts were exposed to a low-flow ischemia (1 ml/min) of 30 min duration and reperfused at a constant flow of 5 ml/min. Human thrombocytes were administered as 1 min bolus (20 000 thrombocytes/µl perfusion buffer) in the 15th min of ischemia or in the 1st or 5th min of reperfusion in the presence of thrombin (0.3 U/ml perfusion buffer). Recovery of external heart work (REHW) was expressed as ratio between postischemic and preischemic EHW in percent. Intracoronary platelet retention (RET) was quantified as percent of platelets applied. In a second set of experiments, thrombocytes were incubated with 10 µM of the irreversible NADPH oxidase blocker diphenyliodonium chloride and washed twice, thereafter, and administered according to the same protocol as described above. Hearts exposed to ischemia and reperfusion in the presence of thrombin but without application of platelets served as controls. Controls without application of platelets did not reveal a severe compromisation of myocardial function (REHW 85.5 ± 1%). However, addition of platelets during ischemia or in the 1st or 5th min of reperfusion led to a significant reduction of REHW as compared with controls (REHW 62.4 ± 6, 53.9 ± 3, 40.5 ± 3, respectively). Application of platelets pretreated with diphenyliodonium chloride did not reveal any cardiodepressive effects being significantly different from controls without platelet application. Moreover, treatment of platelets with diphenyliodonium chloride did not significantly decrease intracoronary platelet retention. In conclusion, these results demonstrate that cardiodepressive effects of human thrombocytes in ischemic and reperfused guinea pig hearts are mediated by ROS released from thrombocytes and not the heart.

The effects of tirofiban on peripheral markers of oxidative stress and endothelial dysfunction in patients with acute coronary syndromes

BACKGROUND

Endothelial dysfunction and oxidative stress are believed to be central mechanisms in atherogenesis. We aimed to determine the effects of tirofiban on oxidative stress and neutrophil-endothelium interaction markers in patients with acute coronary syndromes (ACS).

MATERIALS AND METHODS

We measured malondialdehyde (MDA), interleukin-6 (IL-6) and soluble endothelial intercellular and vascular adhesion molecules (sICAM-1 and sVCAM-1) on admission, at 48 and 72 h and on 5th day of hospitalization in 34 patients (age 66.5+/-1.8 years) with ACS. Patients with recurrent angina, changes on the electrocardiogram and/or elevated troponin I received intravenously tirofiban for 48 h and the others received normal saline.

RESULTS

Baseline concentrations of all markers did not differ significantly and compared with placebo, tirofiban infusion markedly reduced MDA, IL-6, sICAM-1 and sVCAM-1 at 48 h (-31+/-6% vs. 84+/-49%, p=0.007, -12+/-14% vs. 23+/-10%, p=0.05, -20+/-6% vs. 36+/-25%, p=0.04 and -10+/-5% vs. 6+/-5%, p=0.02, respectively). Relative to baseline, significant reductions were observed for all 4 markers at 72 h and day 5 (p<0.05).

CONCLUSION

Tirofiban potentiates the decline in oxidative stress and may reverse abnormal endothelial activation in patients with ACS. This benefit seems to remain over the following 5 days.

BMS-191095, a cardioselective mitochondrial K(ATP) opener, inhibits human platelet aggregation by opening mitochondrial K(ATP) channels

We evaluated the antiplatelet effects of two classes of ATP-sensitive potassium channel openers (K(ATP) openers) on washed human platelets, and the study's emphasis was on the role of mitochondrial K(ATP) in platelet aggregation. Collagen-induced platelet aggregation was inhibited in a dose dependent manner by lemakalim and SKP-450, which are potent cardio-nonselective K(ATP) openers, and also by cardioselective BMS-180448 and BMS-191095 (IC50: 1,130, >1,500, 305.3 and 63.9 microM, respectively), but a significantly greater potency was noted for the cardioselective K(ATP) openers. The latter two K(ATP) openers also inhibited platelet aggregation induced by thrombin, another important blood-borne platelet activator, with similar rank order of potency (IC50: 498.0 and 104.8 microM for BMS-180448 and BMS-191095, respectively). The inhibitory effects of BMS-191095 on collagen-induced platelet aggregation were significantly blocked by a 30-min pretreatment of platelets with glyburide (1 microM) or sodium 5-hydroxydecanoate (5-HD, 100 microM), a nonselective and selective mitochondrial K(ATP) antagonist, respectively, at similar magnitudes; this indicates the role of mitochondrial K(ATP) in the antiplatelet activity of BMS-191095. However, glyburide and 5-HD had no effect when they were added to the platelet cuvette immediately prior to the addition of BMS-191095. These findings indicate that cardioselective mitochondrial K(ATP) openers like BMS-191095 are able to exert cardioprotective effects in cardiac ischemia/reperfusion injury via dual mechanisms directed at the inhibition of platelet aggregation and the protection of cardiomyocytes, and both these mechanisms are mediated by mitochondrial K(ATP).

Intracoronary formation and retention of micro aggregates of leukocytes and platelets contribute to postischemic myocardial dysfunction

OBJECTIVE

Cardiac pump function and coronary regulation can be impaired after short-term ischemia. Recent studies with platelets (P) and neutrophils (PMN) yielded contradicting results about the "cellular" contribution to reperfusion injury.

METHODS

Isolated guinea pig hearts performing pressure-volume work were employed, external heart work (EHW), aortic flow (AF), coronary flow (CF) and heart rate (HR) serving as parameters of cardiac function. After global ischemia, human blood cells were given as bolus (1 min) during reperfusion (intracoronary hematocrit 7%). Expression of specific adhesion molecules (P: CD62P, CD41; PMN: integrin CD11b) was measured on cells before and after coronary passage (FACS analysis).

RESULTS

Postischemic recovery of pump function was significantly reduced in hearts with blood cell application (EHW: -cells 54 +/- 14%, +cells 41 +/-12%, p <0.05). Coronary response to bradykinin and reactive hyperemia were not effected. The blood-cell dependent functional loss was partly reduced by blocking CD18 (anti-CD 18) and completely abrogated by blockage of CD41 (lamifiban). The expression of CD11b on PMN and monocytes (M) and CD62P on platelets was significantly reduced in the coronary effluent and a significant decrease of CD41 on leukocytes occurred during coronary passage after ischemia. Increases in CD41 on PMN in the presence of lamifiban demasked intracoronary formation of micro aggregates (P/PMN). These micro aggregates were visualized by light microscopy. Electron microscopy revealed no significant microvascular plugging.

CONCLUSION

1) A specifically blood-cell induced loss of myocardial pump function has been demonstrated after short-term ischemia. 2) CD41 (= GpIIbIIIa) on P is responsible for this cardiac reperfusion damage. 3) The effect is causally linked to the formation of micro aggregates between PMN and P, but seems attenuated in the presence of erythrocytes as compared to effects reported from experiments in which PMN and P were applied singly or co-perfused. 4) Intracoronary retention of PMN, M and platelet-leukocyte micro aggregates seems to be transient, as adherence was not confirmed by electron microscopy.