In recent investigations, we could demonstrate that thrombocytes are able to contribute to ischemia- and reperfusion-induced injury of the heart. The aim of the current study was to investigate whether reactive oxygen species are responsible for induction of myocardial dysfunction under these conditions. Isolated, perfused, and pressure-volume work-performing guinea pig hearts were exposed to a 30-min low-flow ischemia (1 ml/min) and were reperfused (5 ml/min). Washed, homologous blood platelets were administered as a 1-min bolus (20,000 per microliter of perfusion buffer), either during the 15th minute of ischemia or in the first or fifth minute of reperfusion in the presence of thrombin (0.3 U/ml perfusion buffer)). The radical scavengers superoxide dismutase (SOD; 10 U/ml perfusate) and catalase (30 U/ml perfusate) were added during ischemia or in the first or fifth minute of reperfusion, respectively. Intracoronary platelet retention (in percentage of platelets applied) and recovery of EHW (postischemic EHW in percentage of preischemic EHW) were quantified. Ischemic and reperfused hearts with time-matched application of platelets but without administration of SOD or catalase served as controls. Interestingly, both administration of SOD during ischemia and in reperfusion significantly improved recovery of EHW (88.4 +/- 2%, 82. 6 +/- 1%, and 90 +/- 3%, respectively) as compared with the case of controls (56.2 +/- 3%, 42 +/- 2%, and 75 +/- 2%, respectively). Platelet retention, however, was not significantly influenced by administration of SOD during ischemia or reperfusion (26 +/- 2%, 31 +/- 2%, and 26 +/- 2%) compared with controls (30.5 +/- 3%, 33 +/- 2%, and 22 +/- 3%, respectively). Coadministration of catalase, on the other hand, exhibited some cardioprotective potential only in the first minute of reperfusion (recovery, 61% +/- 4%) as compared with the case of control (42 +/- 2%). We conclude that thrombocytes under conditions of ischemia and reperfusion are able to induce a myocardial dysfunction mediated by reactive oxygen species. Superoxide seems to play a major role in this respect.