A.G. Semb

Functional impairment in isolated rat hearts induced by activated leukocytes: Protective effect of oxygen free radical scavengers

Ischemia-reperfusion activates polymorphonuclear leukocytes (PMN). Depletion of PMN has been shown to reduce the size of experimental myocardial infarction. We have studied whether PMN activated by phorbol myristate acetate (PMA) would depress function of the isolated rat heart, and if this effect was mediated by oxygen free radicals (OFR). Cells and/or drugs were added to the perfusate into the aortic cannula for 10 min, followed by a 30 min recovery period. Oxygen free radicals formation was verified by chemiluminescence (CL). PMA-activated PMN (n = 13) caused CL response of 27,493 +/- 5113 counts (mean +/- S.E.M.) and reduced left ventricular developed pressure (LVDP) to 30 +/- 9% and coronary flow (CF) to 49 +/- 7% of the baseline value at the end of the observation period. Addition of super-oxide dismutase (SOD) and catalase (CAT) (n = 11) reduced the CL response to 5623 +/- 806 counts, but did not influence either LVDP (36 +/- 15%) or CF (51 +/- 18%). Addition of thiourea (TU) to the activated cell suspension (n = 8) further reduced the CL response (3663 +/- 474 counts), and LVDP was 86 +/- 5% and CF was 87 +/- 3%. When TU + SOD + CAT was mixed with PMN + PMA (n = 11), the CL was almost abolished (117 +/- 21 counts) and LVDP was 73 +/- 8% and CF was 94 +/- 6%. When CF was reduced (n = 7) alike the CF reduction in the hearts receiving PMA + PMA, LVDP was not significantly changed at the end of the observation period (75 +/- 6%). Unactivated PMN (n = 8) caused minor response of LVDP and CF, similar to PMN + PMA + TU and PMN + PMA + SOD + CAT + TU. PMA alone (n = 8) was cardiotoxic and caused changes similar to PMN + PMA. This effect was not inhibited by scavengers (n = 6). The supernatant of the PMN + PMA suspension (n = 7) did not impair cardiac function, suggesting that no free PMA was available after mixing with PMN. We conclude that activated PMN in the coronary circulation depressed cardiac function and increased vascular resistance due to OFR production.

Exogenous reactive oxygen species deplete the isolated rat heart of antioxidants.

The effects of reactive oxygen species (ROS) on myocardial antioxidants and on the activity of oxidative mitochondrial enzymes were investigated in the following groups of isolated, perfused rat hearts. I: After stabilization the hearts freeze clamped in liquid nitrogen (n = 7). II: Hearts frozen after stabilization and perfusion for 10 min with xanthine oxidase (XO) (25 U/l) and hypoxanthine (HX) (1 mM) as a ROS-producing system (n = 7). III: Like group II, but recovered for 30 min after perfusion with XO + HX (n = 9). IV: The hearts were perfused and freeze-clamped as in group III, but without XO + HX (n = 7). XO + HX reduced left ventricular developed pressure and coronary flow to approximately 50% of the baseline value. Myocardial content of hydrogen peroxide (H2O2) and malondialdehyde (MDA) increased at the end of XO + HX perfusion, indicating that generation of ROS and lipid peroxidation occurred. Levels of H2O2 and MDA normalized during recovery. Superoxide dismutase, reduced glutathione and alpha-tocopherol were all reduced after ROS-induced injury. ROS did not significantly influence the tissue content of coenzyme Q10 (neither total, oxidized, nor reduced), cytochrome c oxidase, and succinate cytochrome c reductase. The present findings indicate that the reduced contractile function was not correlated to reduced activity of the mitochondrial electron transport chain. ROS depleted the myocardium of antioxidants, leaving the heart more sensitive to the action of oxidative injury.

Oxygen free radical producing leukocytes cause functional depression of isolated rat hearts: Role of leukotrienes

Polymorphonuclear granulocytes PMN) are suggested mediators of myocardial ischemia-reperfusion injury. We have previously shown that activated PMN producing oxygen free radicals (OFR) in the coronary circulation are cardiodepressive. OFR may induce lipid peroxidation and production of eicosanoids. We have investigated the influence of cyclo-oxygenase and lipoxygenase inhibitors on the effects of activated, OFR producing PMN in the Langedorff rat heart model. Left ventricular developed pressure (LVDP) was measured by a balloon in the left ventricle. Human PMN and drugs were given into the aortic cannula for 10 min and the hearts were observed for 30 min thereafter. After infusion for 5 min OFR production in the cellular infusate was measured at the level of the aortic cannula by a chemiluminescence (CL) technique. Phorbol 12-myristate 13-acetate (PMA)-activated PMN (n = 8), produced a CL response of 27649 +/- 11048 counts (mean +/- S.E.M.), and reduced coronary flow (CF) to 53 +/- 6% (mean +/- S.E.M.) and LVDP to 38 +/- 9% of baseline values at the end of the observation period. Ibuprofen (n = 6), a cyclooxygenase (CO) inhibitor, neither influenced the CL response (31915 +/- 7563) of activated PMN, nor the reduction of CF and LVDP at this time. Although both BW 755C (n = 7), a dual inhibitor of CO and lipoxygenase (LO) (CF:90 +/- 4%, LVDP:99 +/- 6%) and diethylcarbamazine (DCM) (n = 8), a LO inhibitor (CF:88 +/- 11%, LVDP:87 +/- 4%), significantly inhibited the cardiodepressive effects of activated PMN. BW 755C alone abolished the CL response (431 +/- 158 counts), whereas DCM had no effect on CL (30105 +/- 1698 counts).(ABSTRACT TRUNCATED AT 250 WORDS)

Leucocytes and cardiopulmonary bypass: in vitro production of oxygen free radicals and trapping in the reperfused myocardium

The production of oxygen free radicals (OFR) by leucocytes was evaluated ex vivo by chemiluminescence (CL) before, during and after routine coronary artery bypass surgery (group A, n=11). The possibility of leucocyte trapping in the coronary circulation during the early reperfusion period was also investigated (group B, n=9). In group A, arterial blood samples were taken immediately before the start of surgery during anaesthesia, five minutes before and five and 30 minutes after the start of cardiopulmonary bypass (CPB), five minutes before and five and 30 minutes after the start of reperfusion of the heart, and then four and 24 hours after the end of CPB. In group B, arterial and coronary sinus blood samples were simultaneously drawn five and 30 minutes after the release of the aortic crossclamp. All blood samples were corrected for haemodilution. In group A, both CL and the level of circulating leucocytes declined during CPB. The lowest value of CL was measured 30 minutes after the start of CPB (69± 2% of baseline values) (mean±SEM). The lowest level of leucocytes was found after 30 minutes of CPB: 2.6±0.4 (109/l) vs 4.2±0.5 before surgery. Twenty-four hours after CPB, CL was increased to 170±49% and a leucocytosis was present (12.2±1.1). In group B, after five minutes of reperfusion the number of circulating leucocytes in arterial blood was 3.8±0.9 x 10 9/l as compared to 2.2±0.5 x 109/l in the coronary sinus (p<0.0017). However, no such difference was found after 30 minutes of reperfusion. The decreased CL during CPB was probably due to in vivo activation and exhaustion of leucocytes. The postischaemic trapping of these cells may play a pathogenetic role in reperfusion injury.

Inhibition of lipoxygenase and cyclooxygenase augments cardiac injury by H2O2

The role of arachidonic acid metabolites in the cardiac effects of toxic oxygen metabolites (TOM) was investigated in buffer-perfused rat hearts (Langendorff model). Hydrogen peroxide (H2O2, 200 microM) was given for 10 min to generate TOM, followed by 30 min recovery. H2O2 reduced left ventricular developed pressure (LVDP), increased left ventricular end-diastolic pressure (LVEDP), and increased coronary flow (CF). The hydroxyl radical scavenger thiourea inhibited the H2O2-induced effects. Perfusion with three lipoxygenase inhibitors, AA861, BWA4C, and diethylcarbamazine, in addition to H2O2, augmented the decrease of LVDP and the increase of LVEDP induced by H2O2. The cyclooxygenase inhibitor indomethacin had the same effects. The H2O2-induced increase in CF was not influenced by diethylcarbamazine, but inhibited by all other drugs. Control perfusion with drugs alone did not influence cardiac function. In conclusion, inhibition of lipoxygenase and cyclooxygenase augmented the depression of cardiac function induced by TOM. Leukotrienes and prostanoids appear to be protective against H2O2-induced cardiac injury.

Coronary Trapping of a Complement Activation Product (C3a des-Arg) During Myocardial Reperfusion in Open-Heart Surgery

Accumulation of complement factors has been found to occur in the myocardium after infarction. We studied the possibility that the complement activation product C3a des-Arg is trapped within the coronary circulation during reperfusion of the ischemic myocardium. In 11 patients undergoing routine coronary artery bypass grafting, arterial blood was sampled before, during and after cardiopulmonary bypass. Blood was drawn from the coronary sinus concomitantly with arterial blood sampling 5 and 30 min after release of the aortic cross-clamp (n = 10). From a preoperative value of 92 +/- 13 ng/ml, C3a des-Arg rose during CPB to a maximum of 1816 +/- 393 at the end of CPB. Following reperfusion for 5 min, C3a des-Arg was 1284 +/- 232 ng/ml in arterial and 1106 +/- 100 in coronary sinus blood, a significant difference (p less than 0.05). The amount of C3a des-Arg trapped in the heart at 5-min reperfusion showed positive correlation with its arterial concentration (p less than 0.05). No significant difference was found after 30 min of reperfusion. Complement activation products trapped in the heart in the early reperfusion period may play a pathogenetic role in myocardial ischemia-reperfusion injury.

Oxygen free radicals decrease survival time of isolated rat hearts

Effects of oxygen free radicals (OFR), enzymatically generated in the coronary circulation, were studied in isolated rat hearts retrogradely perfused with Krebs-Ringer solution. Control hearts (n = 6) functioned adequately for at least 5 hours. When rat hearts (n = 6) received xanthine oxidase (XOD) and hypoxanthine (HX) in order to generate OFR, survival time was reduced to 31 +/- 0.4 min (mean +/- SEM). Infusion of XOD (n = 8) or HX (n = 5) alone also reduced cardiac survival time, to 32 +/- 6 min and 139 +/- 23 min, respectively. When allopurinol (an inhibitor of XOD) was given together with XOD (n = 6), survival time (277 +/- 30 min) was similar to the control value. The production of OFR did not result in depressed coronary flow or heart rate, but reduced the aortic pulse pressure. OFR thus can depress cardiac function and may ultimately cause cardiac arrest.