Different responses of non-ischemic and post-ischemic myocardium towards Ca2+ sensitization.

We tested whether decreased Ca2+ sensitivity is a major cause for dysfunctional stunned myocardium. The experiments employed a novel Ca2+ sensitizing agent: the thiadiazinone derivative EMD 60 263. Experiments were done on 14 isolated, blood-perfused rabbit hearts. After control, seven hearts were subjected to 20 min no-flow ischemia, and then allowed to recover during 30 min reperfusion. Thereafter, EMD 60 263 was administered (3, 10 and 30 microm). For comparison, the effect of the same doses was investigated in seven non-ischemic hearts. At the low dose, the agent improved ventricular systolic function in the post-ischemic group significantly (LVPmax: 65+/-13 v 91+/-17 mmHg; dP/dtmax: 845+/-235 v 1300+/-350 mmHg/s), and non-significantly in the non-ischemic group (LVPmax: 115+/-35 v 132+/-39 mmHg; dP/dtmax: 1415+/-545 v 1885+/-720 mmHg/s). Early relaxation (dP/dtmin) was slightly improved in both groups (800+/-225 v 1050+/-220 mmHg/s post-ischemic; 1120+/-315 v 1205+/-285 mmHg/s non-ischemic). Heart rate was increased (151+/-35 v 175+/-45 beats/min) in the post-ischemic group and was unaffected in the non-ischemic group. At the higher dose, systolic ventricular function in the post-ischemic group was further improved (LVPmax: 109+/-17 mmHg, dP/dtmax: 1330+/-180 mmHg/s), but tended to decrease in the non-ischemic group (LVPmax: 121+/-40 mmHg, dP/dtmax: 1605+/-680 mmHg/s). This dose decreased heart rate in both groups (133+/-34 and 134+/-23 beats/min). 30 microm EMD 60 263 had deleterious effects in both groups. The different responses towards Ca2+ sensitization suggest that a decrease in Ca2+ sensitivity might play a role in dysfunctional stunned myocardium. Therefore, Ca2+ sensitizing agents of the thiadiazinone type could be useful to recruit a positive inotropic reserve in stunned myocardium.

Haemodynamic and energetic properties of stunned myocardium in rabbit hearts.

OBJECTIVE: To amplify the description of myocardial stunning. DESIGN: Control versus 30 min after a 20 min no flow ischaemia. EXPERIMENTAL ANIMALS: 15 isolated rabbit hearts perfused with erythrocyte suspension. MAIN OUTCOME MEASURES: Left ventricular systolic function in terms of aortic flow, peak systolic pressure (LVPmax), dP/dtmax, and the end systolic pressure-volume relation (ESPVR); early relaxation from dP/dtmin and rate of left ventricular pressure decay (tau). Passive properties: ventricular and myocardial stiffness. Coronary resistance from coronary blood flow and perfusion pressure. Total myocardial oxygen consumption (MVo2tot). Total mechanical energy via pressure-volume area (PVA). Contractile efficiency (Econ) and MVo2 of the unloaded contracting heart (MVo2unl). External mechanical efficiency (Eext) from stroke work and MVo2tot. RESULTS: Systolic variables in stunned myocardium were significantly decreased (mean (SD)): aortic flow: 38 (13) v 9 (11) ml/min; LVPmax: 112 (19) v 74 (18) mm Hg; dP/dtmax: 1475 (400) v 1075 (275) mm Hg/s. ESPVR was not significantly decreased, at 138 (73) v 125 (58) mm Hg/ml, but the volume axis intercept was shifted rightward: 0.30 (0.37) v 0.65 (0.25) ml. Likewise, early relaxation was impaired: dP/dtmin (-1275 (250) v -975 (250) mm Hg/s) and tau (37 (7) v 46 (10) ms). LVPed was significantly decreased at 19 (12) v 12 (7) mm Hg, and both the ventricular (end diastolic pressure-volume relation) and the myocardial stiffness (constant k) were increased by 75% and 31%, respectively. Coronary resistance increased non-significantly from 0.83 (0.31) to 1.04 (0.41) mm Hg/(ml/min/100 g). Decreases in PVA (570 (280) v 270 (200) mm Hg.ml/100 g), MVo2tot (40 (9) v 34 (8) microliters/beat/100 g), and MVo2unl (26 (9) v 22 (6) microliters/beat/100 g) did not reach significance, in contrast to significant decreases in Econ (31 (18) v 14 (7)%) and Eext (0.75 (0.29) v 0.18 (0.25) arbitrary units). CONCLUSIONS: Ventricular systolic function is decreased after brief episodes of ischaemia. The decrease in diastolic function probably amplifies the systolic deterioration during myocardial stunning. Passive diastolic properties are also changed, shown by increases in both ventricular and myocardial stiffness. The increase in coronary resistance indicates stunning at the vascular level which could limit oxygen supply. With maintained MVo2tot during stunning, external efficiency is decreased. Possible candidates for this metabolic stunning are inadequate excitation-contraction coupling and disturbed O2 utilisation by the contractile apparatus.