One hour reperfusion is enough to assess function and infarct size with TTC staining in Langendorff rat model.

BACKGROUND: There is not general agreement concerning the optimal time of reperfusion necessary to assess myocardial function and necrosis on isolated perfused heart model. Nevertheless, the study of cardioprotection (especially, pre- and postconditioning) requires a reliable and standardized assessment of myocardial necrosis. OBJECTIVE: The objective of this study was thus to evaluate whether 1 h of reperfusion was sufficient to assess rat heart viability on Langendorff preparation. Isolated rat hearts (n = 30) underwent 40 min of global normothermic ischemia followed by 60 or 120 min Langendorff reperfusion. In each group, hearts were also randomly assigned into the 2 following sub-groups: postconditioning (PostC, consisting in 2 episodes of 30 s ischemia and 30 s reperfusion at the onset of reperfusion), and control (no intervention). Coronary flow, heart rate, dP/dt and rate-pressure-product were measured. Myocardial necrosis was assessed by TTC staining and LDH, CK release analysis. RESULTS: Our results indicated that heart function tended to slightly decrease between 60 min and 120 min reperfusion. Infarct size was identical at 60 min and 120 min reperfusion, averaging 33-34% of total LV area in controls versus 17% in PostC (p < 0.001 between control and PostC groups). Similarly, the maximum of enzymatic releases (CK and LDH) measured in coronary effluents was at 60 min of reperfusion, followed by a progressive decrease at 90 min and 120 min. As expected, postconditioning limited enzymatic releases whatever the studied time of reperfusion. CONCLUSION: In conclusion, we showed that prolonged reperfusion beyond 60 min was not useful for function assessment and did not change infarct size measurement, on Langendorff rat model of ischemia-reperfusion.

Optimal pressure for low pressure controlled reperfusion to efficiently protect ischemic heart: an experimental study in rats.

Recent work has demonstrated the benefit of low pressure (LP) reperfusion to protect the heart undergoing an ischemic insult. The goal of the present study was to determine the optimal pressure for the application of LP reperfusion. Isolated rats hearts (n = 30) were exposed to 40 minutes of global warm ischemia followed by 70 minutes of reperfusion with a pressure fixed at 100 cm H(2)O (normal pressure [NP] = control group), 85 cm (group LP [low pressure]-85), 70 cm (group LP-70), or 55 cm (group LP-55). Cardiac function was assessed during reperfusion using the Langendorff model. Myocardial necrosis was assessed by measuring lactate dehydrogenase (LDH) and creatine kinase (CK) leakage in the coronary effluents. Functional recovery was progressively and significantly improved with decreased perfusion pressure. Rate-pressure product (RPP) averaged 3765 +/- 408, 6824 +/- 439, and 12,036 +/- 664 mm Hg/min, respectively, among the control, LP-85, and LP-70 groups (P < .001, LP-70 vs other groups). However, RPP collapsed in the LP-55 group. Similarly, necrosis as measured by LDH and CK leakage progressively reduced between LP-100 and LP-70 hearts (P < .01), with a drastic increase in enzyme in the LP-55 group. In conclusion, this study demonstrated that 70 cm H(2)O is an optimal LP to improve postischemic contractile dysfunction and attenuate necrosis during reperfusion.

Optimal time duration for low-pressure controlled reperfusion to efficiently protect ischemic rat heart.

Previous studies have shown the capacity of low-pressure (LP) reperfusion to protect the ischemic heart. The present study sought to determine the optimal time for the application of LP reperfusion. Isolated rat hearts (n = 30) were exposed to 40 minutes of global warm ischemia followed by 70 minutes of reperfusion. Reperfusion was performed under LP (LP = 70 cm H(2)O) for 0 (control group), 5 (group LP-5), 10 (group LP-10), 30 (group LP-30), or 60 (group LP-60) minutes. Following the LP period the hearts were reperfused with normal pressure (100 cm H(2)O) until the end of reperfusion. Cardiac function was assessed during reperfusion using the Langendorff model. Myocardial necrosis was assessed by measuring LDH leakage in the coronary effluents. Functional recovery was reduced among the control and LP-5 groups with rate-pressure products (RPP) averaging 3788 +/- 499 and 5333 +/- 892 mm Hg/min, respectively. RPP was significantly improved in other groups with RPP averaging 7363 +/- 1159, 7441 +/- 863, and 7269 +/- 692 mm Hg/min in LP-10, LP-30, and LP-60 (P < .01). Similarly, necrosis measured by LDH leakage was significantly reduced in LP-10, LP-30, and LP-60 hearts (P < .01). This study demonstrated that LP reperfusion improves postischemic contractile dysfunction and attenuates necrosis when applied for at least 10 minutes.

High energy compound stability during experimental brain death.

The aim of this study was to examine the effect of sudden brain death (BD) on myocardial function and high energy phosphate (HEP) stores. BD was induced by cerebral vessel ligation in six swine (BD group) that were compared to six control swine. At the end of the BD period (3 hours), harvested hearts were stored at 4 degrees C. Myocardial tissue HEP were assessed by: (i) (31)P-NMR spectroscopy of left ventricle for phosphocreatine (PCr), adenosine triphosphate (ATP), inorganic phosphate (Pi) and intracellular pH (pHi), and by (ii) HPLC for ATP, ADP, and AMP levels in left ventricle biopsies. Brain death resulted in a instantaneous major increase in catecholamines (>50-fold, P < .001) and paradoxically a significant progressive decrease in the regional contractility of the left ventricle. After cardioplegia, no significant differences on HEP compounds (ATP/Pi, PCr/Pi, ATP, energetic index) or in pHi were observed between BD and control groups. These data suggest that early heart injury occurring during BD does not seem to be an ischemic phenomenon.

A simple and reliable method to assess heart viability after hypothermic procurement.

Hearts from brain dead pigs (n = 18) were submitted to 0 (group I), 10 (group II), or 20 (group III) minutes of in situ warm ischemia (animal exsanguination). After harvesting, cold cardioplegia solution was perfused in retrograde fashion and initial coronary flow (ICF) measured. After left ventricular energetic indices were measured using NMR spectroscopy, the hearts were transplanted orthotopically. Follow-up was performed over 120 minutes after cardiopulmonary bypass. We observed a progressive decrease in ICF with increased warm ischemia times: 50 +/- 3.4 mL/min per 100 g of tissue in the group I, 36 +/- 7 and 30 +/- 3.5 in groups II and III, respectively (P < .05 and P < .01 versus group I). The ICF strongly correlated with the energetic index (r = 0.76, P < .001) and with posttransplant function of the transplanted heart. These data showed that measurement of initial coronary flow after cardioplegia was a reliable test to evaluate cardiac graft viability before transplantation.

Controlled reperfusion after hypothermic heart preservation inhibits mitochondrial permeability transition-pore opening and enhances functional recovery.

We investigated whether low-pressure reperfusion may attenuate postischemic contractile dysfunction, limits necrosis and apoptosis after a prolonged hypothermic ischemia, and inhibits mitochondrial permeability transition-pore (MPTP) opening. Isolated rats hearts (n = 72) were exposed to 8 h of cold ischemia and assigned to the following groups: 1) reperfusion with low pressure (LP = 70 cmH(2)O) and 2) reperfusion with normal pressure (NP = 100 cmH(2)O). Cardiac function was assessed during reperfusion using the Langendorff model. Mitochondria were isolated, and the Ca(2+) resistance capacity (CRC) of the MPTP was determined. Malondialdehyde (MDA) production, caspase-3 activity, and cytochrome c were also assessed. We found that functional recovery was significantly improved in LP hearts with rate-pressure product averaging 30,380 +/- 1,757 vs. 18,000 +/- 1,599 mmHg/min in NP hearts (P < 0.01). Necrosis, measured by triphenyltetrazolium chloride staining and creatine kinase leakage, was significantly reduced in LP hearts (P < 0.01). The CRC was increased in LP heart mitochondria (P < 0.01). Caspase-3 activity, cytochrome c release, and MDA production were reduced in LP hearts (P < 0.001 and P < 0.01). This study demonstrated that low-pressure reperfusion after hypothermic heart ischemia improves postischemic contractile dysfunction and attenuates necrosis and apoptosis. This protection could be related to an inhibition of mitochondrial permeability transition.

Low-pressure reperfusion alters mitochondrial permeability transition.

We hypothesized that low-pressure reperfusion may limit myocardial necrosis and attenuate postischemic contractile dysfunction by inhibiting mitochondrial permeability transition pore (mPTP) opening. Male Wistar rat hearts (n = 36) were perfused according to the Langendorff technique, exposed to 40 min of ischemia, and assigned to one of the following groups: 1) reperfusion with normal pressure (NP = 100 cmH(2)O) or 2) reperfusion with low pressure (LP = 70 cmH(2)O). Creatine kinase release and tetraphenyltetrazolium chloride staining were used to evaluate infarct size. Modifications of cardiac function were assessed by changes in coronary flow, heart rate (HR), left ventricular developed pressure (LVDP), the first derivate of the pressure curve (dP/dt), and the rate-pressure product (RPP = LVDP x HR). Mitochondria were isolated from the reperfused myocardium, and the Ca(2+)-induced mPTP opening was measured using a potentiometric approach. Lipid peroxidation was assessed by measuring malondialdehyde production. Infarct size was significantly reduced in the LP group, averaging 17 +/- 3 vs. 33 +/- 3% of the left ventricular weight in NP hearts. At the end of reperfusion, functional recovery was significantly improved in LP hearts, with RPP averaging 10,392 +/- 876 vs. 3,969 +/- 534 mmHg/min in NP hearts (P < 0.001). The Ca(2+) load required to induce mPTP opening averaged 232 +/- 10 and 128 +/- 16 microM in LP and NP hearts, respectively (P < 0.001). Myocardial malondialdehyde was significantly lower in LP than in NP hearts (P < 0.05). These results suggest that the protection afforded by low-pressure reperfusion involves an inhibition of the opening of the mPTP, possibly via reduction of reactive oxygen species production.