Elaine J. Tanhehco

Reduction of myocardial infarct size after ischemia and reperfusion by the glycosaminoglycan pentosan polysulfate.

Activation of the complement system contributes to the tissue destruction associated with myocardial ischemia/reperfusion. Pentosan polysulfate (PPS), a negatively charged sulfated glycosaminoglycan (GAG) and an effective inhibitor of complement activation, was studied for its potential to decrease infarct size in an experimental model of myocardial ischemia/reperfusion injury. Open-chest rabbits were subjected to 30-min occlusion of the left coronary artery followed by 5 h of reperfusion. Vehicle (saline) or PPS (30 mg/kg/h) was administered intravenously immediately before the onset of reperfusion and every hour during the reperfusion period. Treatment with PPS significantly (p < 0.05) reduced infarct size as compared with vehicle-treated animals (27.5+/-2.9% vs. 13.34+/-2.6%). Analysis of tissue demonstrated decreased deposition of membrane-attack complex and neutrophil accumulation in the area at risk. The results indicate that, like heparin and related GAGs, PPS possesses the ability to decrease infarct size after an acute period of myocardial ischemia and reperfusion. The observations are consistent with the suggestion that PPS may mediate its cytoprotective effect through modulation of the complement cascade.

Protective Effects of Ranolazine on Ventricular Fibrillation Induced by Activation of the ATP-Dependent Potassium Channel in the Rabbit Heart.

Background: The authors studied the antifibrillatory effects of the adenosine-triphosphate (ATP)-sparing metabolic modulator ranolazine in a rabbit isolated heart model in which ventricular fibrillation occurs under conditions of hypoxia/reoxygenation in the presence of the ATP-dependent potassium channel opener pinacidil. Methods and Results: Ten minutes after ranolazine or vehicle administration, addition of pinacidil (1.25 μM) to the buffer was followed by a 12-minute hypoxic period and 40 minutes of reoxygenation. At a reduced concentration of ranolazine (10 μM), ventricular fibrillation occurred in 60% of the hearts. compared to 89% in the control group (P = NS). In contrast, only three of nine hearts (33%) treated with 20 μM ranolazine developed ventricular fibrillation (P <.05 vs vehicle). Hemodynamic parameters including coronary perfusion pressure, left ventricular developed pressure, and ±dP/dt were not affected by the presence of ranolazine in the perfusion medium. Ranolazine did not prevent or modify the negative inotropic or coronary vasodilator actions of pinacidil, suggesting a mechanism of action independent of potassium channel antagonism. Conclusions: Ranolazine significantly reduced the incidence of ventricular fibrillation in the hypoxic/reoxygenated heart exposed to the ATP-dependent potassium channel opener, pinacidil. The reported ability of ranolazine to prevent the decrease in cellular ATP during periods of a reduced oxygen supply may account for its observed antifibrillatory action. By maintaining intracellular ATP, ranolazine may modulate or prevent further opening of the ATP-dependent potassium channel in response to hypoxia and/or pinacidil.

Effects of tedisamil (KC-8857) on cardiac electrophysiology and ventricular fibrillation in the rabbit isolated heart.

1 The direct cardiac electrophysiological and antifibrillatory actions of tedisamil (KC‐8857) were studied in rabbit isolated hearts. 2 Tedisamil (1, 3, and 10 μm), prolonged the ventricular effective refractory period (VRP) from 120±18ms (baseline) to 155±19, 171±20, and 205±14 ms, respectively. Three groups of isolated hearts (n = 6 each) were used to test the antifibrillatory action of tedisamil. Hearts were perfused with 1.25 μm pinacidil, a KATP channel activator. Hearts were subjected to hypoxia for 12 min followed by 40 min of reoxygenation. Ventricular fibrillation (VF) developed during hypoxia and reoxygenation in both the control and 1 μm tedisamil‐treated groups (5/6 and 4/6, respectively). Tedisamil (3 μm) reduced the incidence of VF (0/6, P = 0.007 vs. control). 3 In a separate group of hearts, VF was initiated by electrical stimulation. The administration of 0.3 ml of 10 mM tedisamil, via the aortic cannula, terminated VF in all hearts, converting them to normal sinus rhythm. 4 Tedisamil (3 μm) reversed pinacidil‐induced negative inotropic effects in rabbit isolated atrial muscle which were equilibrated under normoxia, as well as in atrial muscle subjected to hypoxia and reoxygenation. 5 The results demonstrate a direct antifibrillatory action of tedisamil in vitro. The mechanism responsible for the observed effects may involve modulation by tedisamil of the cardiac ATP‐regulated potassium channel, in addition to its antagonism of IK and Ito.

Therapeutic potential of complement inhibitors in myocardial ischaemia

Under normal conditions, the complement system functions to eradicate microbes and other membrane bound pathogens. In other situations, complement activation comprises a pivotal mechanism for mediating tissue demolition in inflammatory disorders, including ischaemia/reperfusion injury. Complement-mediated tissue damage has long been recognised as a significant contributor to myocardial reperfusion injury. However, clinical use of complement inhibitors to reduce the extent of irreversible tissue injury related to reperfusion, remains in the early stages of development. Activation of the complement system generates anaphylatoxins, opsonins and the lytic moiety known as the membrane attack complex (MAC). In addition, fragments of the complement cascade proteins (e.g., C3a and C5a) secondarily initiate processes deleterious to myocytes by recruiting and stimulating inflammatory cells, such as neutrophils and macrophages, within the area of reperfusion. Damaged tissue itself, is capable of upregulating the genes that encode the formation of complement proteins leading to assembly of the MAC, which in turn further advances tissue injury. All of these factors contribute to the development of myocardial infarction subsequent to ischaemia and reperfusion. This paper provides an overview of how the complement system operates and examines the various inhibitors, both endogenous and exogenous, that regulate the complement cascade. Activation and inhibition of the complement system will be discussed primarily in the context of myocardial ischaemia and reperfusion injury.

Preconditioning reduces tissue complement gene expression in the rabbit isolated heart

Both preconditioning and inhibition of complement activation have been shown to ameliorate myocardial ischemia-reperfusion injury. The recent demonstration that myocardial tissue expresses complement components led us to investigate whether preconditioning affects complement expression in the isolated heart. Hearts from New Zealand White rabbits were exposed to either two rounds of 5 min global ischemia followed by 10 min reperfusion (ischemic preconditioning) or 10 μM of the ATP-dependent K+(KATP) channel opener pinacidil for 30 min (chemical preconditioning) before induction of 30 min global ischemia followed by 60 min of reperfusion. Both ischemic and chemical preconditioning significantly ( P < 0.05) reduced myocardial C1q, C1r, C3, C8, and C9 mRNA levels. Western blot and immunohistochemistry demonstrated a similar reduction in C3 and membrane attack complex protein expression. The KATPchannel blocker glyburide (10 μM) reversed the depression of C1q, C1r, C3, C8, and C9 mRNA expression observed in the pinacidil-treated hearts. The results suggest that reduction of local tissue complement production may be one means by which preconditioning protects the ischemic myocardium.Both preconditioning and inhibition of complement activation have been shown to ameliorate myocardial ischemia-reperfusion injury. The recent demonstration that myocardial tissue expresses complement components led us to investigate whether preconditioning affects complement expression in the isolated heart. Hearts from New Zealand White rabbits were exposed to either two rounds of 5 min global ischemia followed by 10 min reperfusion (ischemic preconditioning) or 10 microM of the ATP-dependent K+ (KATP) channel opener pinacidil for 30 min (chemical preconditioning) before induction of 30 min global ischemia followed by 60 min of reperfusion. Both ischemic and chemical preconditioning significantly (P < 0.05) reduced myocardial C1q, C1r, C3, C8, and C9 mRNA levels. Western blot and immunohistochemistry demonstrated a similar reduction in C3 and membrane attack complex protein expression. The K(ATP) channel blocker glyburide (10 microM) reversed the depression of C1q, C1r, C3, C8, and C9 mRNA expression observed in the pinacidil-treated hearts. The results suggest that reduction of local tissue complement production may be one means by which preconditioning protects the ischemic myocardium.

Sublytic complement attack reduces infarct size in rabbit isolated hearts: evidence for C5a-mediated cardioprotection.

Sublytic complement attack can elicit protective cellular responses without precipitating cell death. Our investigation examined the effects of non-lethal complement activation in isolated hearts. New Zealand white rabbit hearts were subjected to 30 min of ischemia followed by 1 h of reperfusion. Prior to ischemia, hearts were perfused for 20 min with 0.5% normal human plasma (NHP). Hearts treated with NHP developed significantly (p<0.05) smaller infarcts compared with controls, expressed as percent of area at risk (AAR) (25.3+/-4.0% vs. 40.9+/-4.3%, respectively). Heat-inactivation, soluble complement receptor 1 (sCR1; 20 nM), and anti-C5a antibody reversed the protective effect of NHP (39.0+/-3.1%, 41.7+/-5.1% and 38.4+/-2.3% AAR, respectively). Hearts treated with 3 nM C5a exhibited infarct sizes similar to those exposed to NHP (27.6+/-5.0% AAR). sCR1 alone did not affect infarct size (37.9+/-4.5% AAR). The results suggest that non-lethal complement activation attenuates reperfusion injury through formation of C5a.

Reviparin-sodium prevents complement-mediated myocardial injury in the isolated rabbit heart.

The cytoprotective action of reviparin-sodium (LU-47311: Clivarin), a low-molecular-weight heparin, was examined in an ex vivo model of complement-mediated myocardial injury. The effective concentration of reviparin was determined by using an in vitro rabbit erythrocyte-lysis assay using 4% normal human plasma. Reviparin (0.01-2.73 mg/ml) reduced erythrocyte lysis in a concentration-dependent manner. Subsequently, 0.91 mg/ml of reviparin was evaluated in an ex vivo rabbit isolated-heart model of human complement-mediated injury. Hearts perfused in the presence of 0.91 mg/ml of reviparin (n = 10) demonstrated significant preservation of ventricular function compared with vehicle-treated hearts (n = 10), as evidenced by coronary artery perfusion pressure, left ventricular developed pressure, and left ventricular end-diastolic pressure. A reduction in myocyte creatine kinase release was observed in reviparin-treated hearts compared with controls. Myocardial injury in vehicle-treated hearts was associated with an increased assembly of the membrane-attack complex, as determined by immunohistochemical localization of C5b-9 neoantigen. Reviparin decreased fluid-phase Bb formation detected in the lymphatic drainage of plasma-perfused hearts. The results of this study demonstrate that reviparin inhibits complement-mediated myocardial injury as assessed in an ex vivo experimental model of complement activation.