Selective mitochondrial adenosine triphosphate-sensitive potassium channel activation is sufficient to precondition human myocardium

Redox Regulation of Mitochondrial Potassium Channels Activity

Redox reactions exert a profound influence on numerous cellular functions with mitochondria playing a central role in orchestrating these processes. This pivotal involvement arises from three primary factors: (1) the synthesis of reactive oxygen species (ROS) by mitochondria, (2) the presence of a substantial array of redox enzymes such as respiratory chain, and (3) the responsiveness of mitochondria to the cellular redox state. Within the inner mitochondrial membrane, a group of potassium channels, including ATP-regulated, large conductance calcium-activated, and voltage-regulated channels, is present. These channels play a crucial role in conditions such as cytoprotection, ischemia/reperfusion injury, and inflammation. Notably, the activity of mitochondrial potassium channels is intricately governed by redox reactions. Furthermore, the regulatory influence extends to other proteins, such as kinases, which undergo redox modifications. This review aims to offer a comprehensive exploration of the modulation of mitochondrial potassium channels through diverse redox reactions with a specific focus on the involvement of ROS.

Purinergic signaling in myocardial ischemia-reperfusion injury

Purines and their derivatives, extensively distributed in the body, act as a class of extracellular signaling molecules via a rich array of receptors, also known as purinoceptors (P1, P2X, and P2Y). They mediate multiple intracellular signal transduction pathways and participate in various physiological and pathological cell behaviors. Since the function in myocardial ischemia-reperfusion injury (MIRI), this review summarized the involvement of purinergic signal transduction in diversified pathological processes, including energy metabolism disorder, oxidative stress injury, calcium overload, inflammatory immune response, platelet aggregation, coronary vascular dysfunction, and cell necrosis and apoptosis. Moreover, increasing evidence suggests that purinergic signaling also mediates the prevention and treatment of MIRI, such as ischemic conditioning, pharmacological intervention, and some other therapies. In conclusion, this review exhibited that purinergic signaling mediates the complex processes of MIRI which shows its promising application and prospecting in the future.

Can human myocardium be remotely preconditioned? The results of a randomized controlled trial

OBJECTIVES

No experimental study has shown that the myocardium of a remotely preconditioned patient is more resistant to a standardized ischaemic/hypoxic insult.

METHODS

This was a single-centre randomized (1:1), double-blinded, sham-controlled, parallel-group study. Patients referred for elective coronary bypass surgery were allocated to either remote ischaemic preconditioning (3 cycles of 5-min ischaemia/5-min reperfusion of the right arm using a blood pressure cuff inflated to 200 mmHg) or sham intervention. One hundred and thirty-four patients were recruited, of whom 10 dropped out, and 4 were excluded from the per-protocol analysis. The right atrial trabecula harvested on cannulation for cardiopulmonary bypass was subjected to 60 min of simulated ischaemia and 120 min of reoxygenation in an isolated organ experiment. Postoperative troponin T release and haemodynamics were assessed in an in vivo study.

RESULTS

The atrial trabeculae obtained from remotely preconditioned patients recovered 41.9% (36.3-48.3) of the initial contraction force, whereas those from non-preconditioned patients recovered 45.9% (39.1-53.7) (P = 0.399). Overall, the content of cleaved poly (ADP ribose) polymerase in the right atrial muscle increased from 9.4% (6.0-13.5) to 19.1% (13.2-23.8) (P < 0.001) after 1 h of ischaemia and 2 h of reperfusion in vitro. The amount of activated Caspase 3 and the number of terminal deoxynucleotidyl transferase dUTP nick end labeling-positive cells also significantly increased. No difference was observed between the remotely preconditioned and sham-treated myocardium. In the in vivo trial, the area under the curve for postoperative concentration of troponin T over 72 h was 16.4 ng⋅h/ml (95% confidence interval 14.2-18.9) for the remote ischaemic preconditioning and 15.5 ng⋅h/ml (13.4-17.9) for the control group in the intention-to-treat analysis. This translated into an area under the curve ratio of 1.06 (0.86-1.30; P = 0.586).

CONCLUSIONS

Remote ischaemic preconditioning with 3 cycles of 5-min ischaemia/reperfusion of the upper limb before cardiac surgery does not make human myocardium more resistant to ischaemia/reperfusion injury.

CLINICAL TRIAL REGISTRATION NUMBER

NCT01994707.

Nicorandil Attenuates Reperfusion Injury after Long Cardioplegic Arrest

The cardioprotective efficacy of nicorandil in cardiac surgery was determined using a surgically relevant 4-hr cardioplegic arrest model. Each isolated rabbit heart was parabiotically blood-perfused using a modified Langendorff column. The magnitude of left ventricular developed pressure and rate of change of developed pressure over time were measured before (baseline) and after ischemia. Nicorandil was administered either pre-ischemia, post-ischemia, pre/post-ischemia, or continuously (before, during, and after ischemia). The endothelium of the coronary artery was observed by scanning electron microscopy. Serum myeloperoxidase activities were also measured. Although pretreatment with nicorandil did not affect recovery of developed pressure, administration of nicorandil after ischemia, or before and after ischemia, enhanced the recovery of developed pressure. Serum myeloperoxidase activity was decreased in the pre/post-ischemia and continuous groups. Endothelial reperfusion injury decreased in all nicorandil-treated groups. Administration of nicorandil attenuated ischemia-reperfusion injury of the myocardium and coronary endothelium while ameliorating leukocyte activation. In the event of unexpected prolonged cardioplegic arrest, administration of nicorandil, even just after declamping, may improve cardiac function. However, pre-ischemia administration alone was not helpful in the heart subjected to prolonged cardioplegic arrest.

Role of mitochondrial ATP-sensitive potassium channel-mediated PKC-ε in delayed protection against myocardial ischemia/reperfusion injury in isolated hearts of sevoflurane-preconditioned rats

This study aimed to determine the role of mitochondrial adenosine triphosphate-sensitive potassium (mitoK_ATP) channels and protein kinase C (PKC)-ε in the delayed protective effects of sevoflurane preconditioning using Langendorff isolated heart perfusion models. Fifty-four isolated perfused rat hearts were randomly divided into 6 groups (n=9). The rats were exposed for 60 min to 2.5% sevoflurane (the second window of protection group, SWOP group) or 33% oxygen inhalation (I/R group) 24 h before coronary occlusion. The control group (CON) and the sevoflurane group (SEVO) group were exposed to 33% oxygen and 2.5% sevoflurane for 60 min, respectively, without coronary occlusion. The mitoK_ATP channel inhibitor 5-hydroxydecanoate (5-HD) was given 30 min before sevoflurane preconditioning (5-HD+SWOP group). Cardiac function indices, infarct sizes, serum cardiac troponin I (cTnI) concentrations, and the expression levels of phosphorylated PKC-ε (p-PKC-ε) and caspase-8 were measured. Cardiac function was unchanged, p-PKC-ε expression was upregulated, caspase-8 expression was downregulated, cTnI concentrations were decreased, and the infarcts were significantly smaller (P<0.05) in the SWOP group compared with the I/R group. Cardiac function was worse, p-PKC-ε expression was downregulated, caspase-8 expression was upregulated, cTnI concentration was increased and infarcts were larger in the 5-HD+SWOP group (P<0.05) compared with the SWOP group. The results suggest that mitoK_ATP channels are involved in the myocardial protective effects of sevoflurane in preconditioning against I/R injury, by regulating PKC-ε phosphorylation before ischemia, and by downregulating caspase-8 during reperfusion.

Occult Cardiotoxicity—Toxic Effects on Cardiac Ischemic Tolerance

The outcome of cardiac ischemic events depends not only on the extent and duration of the ischemic stimulus but also on the myocardial intrinsic tolerance to ischemic injury. Cardiac ischemic tolerance reflects myocardial functional reserves that are not always used when the tissue is appropriately oxygenated. Ischemic tolerance is modulated by ubiquitous signal transduction pathways, transcription factors and cellular enzymes, converging on the mitochondria as the main end effector. Therefore, drugs and toxins affecting these pathways may impair cardiac ischemic tolerance without affecting myocardial integrity or function in oxygenated conditions. Such effect would not be detected by current toxicological studies but would considerably influence the outcome of ischemic events. The authors refer to such effect as “occult cardiotoxicity.” In this review, the authors summarize current knowledge about main mechanisms that determine cardiac ischemic tolerance, methods to assess it, and the effects of drugs and toxins on it. The authors offer a view that low cardiac ischemic tolerance is a premorbid status and, therefore, that occult cardiotoxicity is a significant potential source of cardiac morbidity. The authors propose that toxicologic assessment of compounds would include the assessment of their effect on cardiac ischemic tolerance.

Glimepiride upregulates eNOS activity and inhibits cytokine-induced NF-kappaB activation through a phosphoinoside 3-kinase-Akt-dependent pathway

AIMS

Several studies suggest increased mortality postcoronary angioplasty in patients on sulphonylureas. However, a theoretical reduction in cardiac risk has been suggested with the newer sulphonylurea agents, which differ from the first-generation agents. In the present study, we investigated whether a third generation of sulphonylurea, glimepiride, might stimulate nitric oxide (NO) production and thereby inhibit cytokine-induced nuclear factor (NF)-kappaB activation in endothelial cells compared with the classical sulphonylurea glibenclamide.

METHODS AND RESULTS

We demonstrated that glimepiride, but not glibenclamide, induces NO production in human umbilical vein endothelial cells (HUVEC). A significant increase in endothelial NO synthase (eNOS) activity, measured in terms of citrulline production, was observed with glimepiride treatment. Akt phosphorylation followed by phosphorylation of eNOS (Ser1177) was observed with glimepiride treatment in HUVEC. Moreover, two phosphoinoside 3-kinase inhibitors, wortmannin and LY294002, significantly inhibited glimepiride-induced NO production. We also demonstrated inhibition of tumour necrosis factor-alpha (TNFalpha)-induced NF-kappaB activation in HUVEC treated with glimepiride, which was attenuated by pretreatment with N(omega)-nitro-L-arginine methyl ester. We also demonstrated a marked increase in p65 in nuclear extracts from untreated HUVEC following stimulation with TNFalpha, which was dose dependently inhibited by glimepiride, but not by glibenclimide in association with NF-kappaB levels.

CONCLUSION

These data suggest that glimepiride might be a preferable sulphonylurea agent in the setting of type 2 diabetes and vascular disease because it may have protective effects on vascular endothelial cells.

Endogenous cardiac opioids: enkephalins in adaptation and protection of the heart

Opiates have been used for thousands of years in the form of opium for relief of pain or fever and to induce sleep. However, it was only in the 1970s that the endogenous ligands for the opiate receptors were identified and termed opioid peptides. Opioid peptides activate G protein-coupled receptors in the central and autonomic nervous system, with marked effects on the regulation of pain perception, body temperature, respiration, heart rate and blood pressure. Cardiovascular regulatory effects of endogenous opioids were initially considered to originate from neural centres in the central nervous system, facilitating a regulatory role in neuro-transmission, as demonstrated by the presynaptic co-release from sympathetic neurones of norepinephrine with enkephalin or acetylcholine with enkephalin. However, opioid peptides of myocardial origin have also recently been shown to play a key role in local regulation of the heart. This brief review highlights the key features of the enkephalin opioids in the heart and the current understanding of their role in development, ageing, cardioprotection, hypertension, hypertrophy, and heart failure.

Diazoxide provides maximal KATP channels independent protection if present throughout hypoxia

BACKGROUND

It is not clear what the optimal timing of diazoxide administration for cardioprotection in human myocardium is. We aimed to establish it. We next checked whether protection depended on adenosine triphosphate (ATP)-inhibited potassium (KATP) channels.

METHODS

Isolated human right atrial trabeculae were subjected to 90-minute hypoxia and 120-minute reoxygenation in vitro, followed by adding 10(-4) M norepinephrine. Diazoxide (100 microM) was added (1) as a 10-minute preconditioning signal with 10-minute washout before hypoxia or (2) 10-minute pretreatment without washout before hypoxia or (3) throughout hypoxia or (4) 10 minutes before and throughout hypoxia or (5) during the first 20 minutes of reoxygenation only. In the control, no diazoxide was added. In another set of experiments, diazoxide (100 microM) was present throughout hypoxia in control, while we tried to inhibit its protective effect with glibenclamide (1, 10, 100 microM) or 5-hydroxydecanoate (100 microM).

RESULTS

The presence of diazoxide throughout hypoxia improved recovery of contractility during reoxygenation, allowed for significant response to norepinephrine at the end of reoxygenation, prevented "ischemic contracture" development, and reduced release of troponin I to tissue bath during hypoxia. Adding diazoxide 10 minutes before hypoxia conferred significantly weaker protective effects in all the above respects. We failed to show a protective effect of diazoxide used as a preconditioning signal or during reoxygenation. Neither 5-hydroxydecanoate nor glibenclamide significantly influenced protective effects of diazoxide added during hypoxia.

CONCLUSIONS

Administration of diazoxide throughout hypoxia provided maximal protective effect, suggesting that diazoxide may be an important adjunct to cardioplegic solution. The protection offered by diazoxide used during hypoxia appears independent of its influence on KATP channels.

Diazoxide provides protection to human myocardium in vitro that is concentration dependent

BACKGROUND

Diazoxide has been shown to confer significant myocardial protection in many experiments. This study was designed to assess its influence on the structural injury and functional recovery of human myocardium subjected to hypoxia/reoxygenation in vitro.

METHODS

The isolated electrically driven human right atrial trabeculae, obtained during cardiac surgery, were studied. The tissue bath was oxygenated with 95% oxygen and 5% carbon dioxide, hypoxia being obtained by replacing oxygen with argon. The influence of diazoxide on atrial contractility was studied first. Next, the two trabeculae from one atrial appendage were studied simultaneously, adding diazoxide to the tissue bath 10 minutes before hypoxia in one, with another serving as a control. We tested 10(-4.5) mol/L and 10(-4) mol/L diazoxide in three sets of experiments testing 30, 60, and 90 minutes of hypoxia. We continued reoxygenation for 120 minutes (in 60-minute and 90-minute hypoxia experiments) and subsequently tested reaction to 10(-4) mol/L norepinephrine. Apart from continuous recording of the contraction force, we measured the troponin I release into the tissue bath after ischemia and reoxygenation.

RESULTS

Diazoxide exerted a negative inotropic effect in human atrial muscle (pD(2)=3.96 +/- 0.18). Both concentrations of diazoxide studied resulted in better functional recovery of atrial trabeculae subjected to 30 minutes of hypoxia. With longer hypoxia, only the higher diazoxide concentration provided significant protection as assessed by contractility. After 120 minutes of reoxygenation, only diazoxide-treated muscle was viable enough to respond to norepinephrine. Only 10(-4) mol/L diazoxide resulted in lower troponin I release during hypoxia and reoxygenation.

CONCLUSIONS

This study shows that diazoxide provides significant concentration-dependent protection against hypoxia/reoxygenation injury to human myocardium in vitro.

Modulation of mitochondrial adenosine triphosphate-sensitive potassium channels and sodium-hydrogen exchange provide additive protection from severe ischemia-reperfusion injury

BACKGROUND

Preconditioning and inhibition of sodium-proton exchange attenuate myocardial ischemia-reperfusion injury by means of independent mechanisms that might act additively when used together. The hypothesis of this study is that treatment with a sodium-proton exchange inhibitor and a mitochondrial adenosine triphosphate-sensitive potassium channel opener produces superior functional recovery and a greater decrease in left ventricular infarct size compared with treatment with either drug alone in a model of severe global ischemia.

METHODS

Isolated crystalloid-perfused rat hearts (n = 8 hearts per group) were administered vehicle (control, 0.04% dimethyl sulfoxide), diazoxide (100 micromol/L in 0.04% dimethyl sulfoxide), cariporide (10 micromol /L in 0.04% dimethyl sulfoxide), or diazoxide and cariporide before 40 minutes of ischemia at 35.5 degrees C to 36.5 degrees C and 30 minutes of reperfusion.

RESULTS

The combination group had superior postischemic systolic function compared with that seen in the cariporide, diazoxide, and control groups (recovery of developed pressure: 91% +/- 7% vs 26% +/- 5%, 35% +/- 6%, and 16% +/- 3%, respectively; P <.05). Postischemic diastolic function in the combination group was superior compared with that seen in the other groups (change(pre-post) diastolic pressure of 67 +/- 4 mm Hg with control, 49 +/- 11 mm Hg with diazoxide, 59 +/- 10 mm Hg with cariporide, and 3 +/- 3 mm Hg with diazoxide and cariporide combination; P <.05). The left ventricular infarct area was less in the combination group compared with that in the cariporide, diazoxide, and control groups (6% +/- 2% vs 35% +/- 7%, 25% +/- 3%, and 37% +/- 9%, respectively; P <.05).

CONCLUSIONS

Combining a selective mitochondrial adenosine triphosphate-sensitive potassium channel opener with a selective reversible inhibitor of sarcolemmal sodium-proton exchange improves recovery of contractile function from severe global ischemia in the isolated buffer-perfused rat heart. The putative mechanism for this benefit is superior protection of mitochondrial function.

Ischemic preconditioning: fact or fantasy?

Fifteen years ago, an experimental effort to magnify a myocardial infarction, with preinfarction episodes of transient ischemia, proved paradoxically protective. In the ensuing years, surgeons have learned to discriminate a biochemical/metabolic/functional spectrum of cardiac states ranging from healthy myocardium to "stunned" or "hibernating" heart to the modes of "apoptotic" or "necrotic" cardiomyocyte death. It is now clear that "protective cardiac preconditioning" influences all of these cardiac states. The cellular mechanisms of preconditioning (PC) are now sufficiently understood to permit clinical application. Ligation of adrenergic, adenosine, bradykinin or opioid receptors involves signaling via both tyrosine and calcium-dependent protein kinases (PKC), which activate mitochondrial ATP-dependent potassium channels. Subsequently, the release of oxygen radicals induces nuclear translocation of transcriptional regulators, which transform the cardiomyocyte into a more resilient cell. Although preconditioning was initially recognized as protecting only against infarction, PC also limits postischemic dysrhythmias and enhances contractile function. Phase I (safety) and phase II (efficacy) clinical trials now persuasively support pharmacological preconditioning as a safe mode of preventing postcardiac surgical complications. Indeed, preconditioning is currently being proposed as adjunctive to hypothermic perfusates in protecting against the obligate organ ischemia during transplantation.

Delayed cardioprotection by isoflurane: role of K(ATP) channels

Isoflurane mimics the cardioprotective effect of acute ischemic preconditioning with an acute memory phase. We determined whether isoflurane can induce delayed cardioprotection, the involvement of ATP-sensitive potassium (K(ATP)) channels, and cellular location of the channels. Neonatal New Zealand White rabbits at 7-10 days of age (n = 5-16/group) were exposed to 1% isoflurane-100% oxygen for 2 h. Hearts exposed 2 h to 100% oxygen served as untreated controls. Twenty-four hours later resistance to myocardial ischemia was determined using an isolated perfused heart model. Isoflurane significantly reduced infarct size/area at risk (means +/- SD) by 50% (10 +/- 5%) versus untreated controls (20 +/- 6%). Isoflurane increased recovery of preischemic left ventricular developed pressure by 28% (69 +/- 4%) versus untreated controls (54 +/- 6%). The mitochondrial K(ATP) channel blocker 5-hydroxydecanoate (5-HD) completely (55 +/- 3%) and the sarcolemmal K(ATP) channel blocker HMR 1098 partially (62 +/- 3%) attenuated the cardioprotective effects of isoflurane. The combination of 5-HD and HMR-1098 completely abolished the cardioprotective effect of isoflurane (56 +/- 5%). We conclude that both mitochondrial and sarcolemmal K(ATP) channels contribute to isoflurane-induced delayed cardioprotection.

Diazoxide protects the rabbit heart following cardioplegic ischemia

K(ATP) channels are present in sarcolemmal and mitochondrial membranes. This study tests the hypothesis that opening mitochondrial K(ATP) channels with Diazoxide (DZ) improves tolerance to cardioplegic ischemia during surgery. Twenty-two rabbit hearts were perfused with Krebs-Henseleit buffer (KHB) on a Langendorff apparatus and underwent 50 min of 37 degrees C global ischemia with St Thomas' cardioplegia (STCP). Hearts were divided into three groups. Ten (control) received no pretreatment. Seven (DZ) received 10 min of 30 microM DZ, a selective mitochondrial K(ATP) opener, in KHB before arrest with STCP containing 30 microM DZ. Five (5-HD + DZ) received 10 min of 100 microM sodium 5-hydroxydecanoate (5-HD), a selective mitochondrial K(ATP) channel blocker, followed by 10 min of 30 microM DZ and 100 microM 5-HD in KHB before arrest with STCP + 30 microM DZ + 100 microM 5-HD. LV developed pressure (LVDP), dP/dt and coronary flow (CF) were measured after 60 min of reperfusion. Diazoxide pretreatment significantly improved the recovery of LV function and coronary flow compared to control (LVDP: 49 +/- 5* vs. 31 +/- 4; +dP/dtmax 927 +/- 93 vs. 507 +/- 85 mmHg/sec*; CF 33 +/- 4 vs. 22 +/- 2 ml/min, *p < 0.05). Mitochondria K(ATP) channel blockade with 5-HD prevented DZ's salutary effect on the recovery of LV and vascular function. Diazoxide pretreatment protects the rabbit heart during cardioplegic ischemia by opening mitochondrial K(ATP) channels. Opening mitochondrial K(ATP) channels may be a new strategy for improving myocardial protection during cardiac surgery.

Is there a place for preconditioning during cardiac operations in humans?

BACKGROUND

Activation of the kinase cascade (protein kinase C (PKC), tyrosine kinase (TK), and mitogen-activated protein kinase (MAPK) is a key feature of the transduction pathway, elicited by preconditioning signals and mediating their cardioprotective effects. We assessed whether such an activation occurred during cardiac operations and could thus represent a target for cardioprotective strategies.

METHODS

A total of 20 patients undergoing coronary artery bypass grafting surgery were studied. During the first 10 minutes of cardiopulmonary bypass (CPB), 10 were treated with sevoflurane (2.5 minimum alveolar concentration), an inhalational anesthetic that mimics preconditioning through a similar activation of the kinase cascade. Ten case-matched patients undergoing 10 minutes of sevoflurane-free CPB served as controls. Right atrial biopsies were taken before and 10 minutes after CPB and were then processed for the measurement of PKC, TK, and p38 MAPK activities by enzyme assay techniques. Troponin I was also monitored over the first 2 postoperative days.

RESULTS

Compared with pre-CPB values, PKC and p38 MAPK activities (in nanomoles per milligram of protein per minute and arbitrary units, respectively) increased significantly and to the same extent in both groups: PKC, from 20.7+/-0.7 to 29.9+/-3.9 in controls (p = 0.037) and from 18.4+/-1.1 to 23.9+/-1.8 in sevoflurane (p = 0.016); p38 MAPK, from 88.6+/-8.5 to 312.9+/-66.2 in controls (p = 0.005) and from 114.6+/-14.7 to 213.4+/-51.8 in sevoflurane (p = 0.045). Conversely, sevoflurane triggered a significant increase in TK activity (from 68.5+/-1.4 to 83.7+/-2.9 picomoles per milligram of protein per minute p = 0.0015) which did not occur in controls (from 67.5+/-1.9 to 76.8+/-4.2 picomoles per milligram of protein per minute, p = 0.09). Likewise, the peak postoperative value of troponin I was not different between controls and sevoflurane-treated patients (3.4+/-0.6 vs 2.4+/-0.4, p = 0.21).

CONCLUSIONS

Cardiopulmonary bypass triggers an activation of the kinase cascade that is mechanistically linked to opening of potassium channels. The direct opening of these channels by the anesthetic sevoflurane does not increase kinase activation further, nor does it improve markers of cell necrosis, thus suggesting that pharmacologically targeting potassium channels may overlap the preconditioning-like effects of CPB alone.

Mitochondrial ATP-sensitive potassium channel plays a dominant role in ischemic preconditioning of rabbit heart

BACKGROUND

The ATP-sensitive potassium (K(ATP)) channel has been shown to be important in the ischemic preconditioning (IPC) response. Recently, the mitochondrial rather than the sarcolemmal K(ATP) channel has been focused on due to its energy-modulating property. Hence, this study was undertaken to elucidate the role of the mitochondrial K(ATP) channel in IPC by modulating the mitochondrial K(ATP) channel in isolated perfused rabbit hearts.

METHODS

Seven hearts served as a control with no interventions. Seven hearts underwent IPC consisting of two 5-min cycles of global ischemia followed by 5 min of reperfusion. Seven hearts received the selective mitochondrial K(ATP) channel blocker 5-dehydroxydecanoate (5-HD, 100 microM) for 5 min before IPC, and 7 hearts received the selective mitochondrial K(ATP) channel opener diazoxide (50 microM) for 5 min. Then, all hearts were subjected to 1 h of left anterior descending coronary artery ischemia and 1 h of reperfusion. Left ventricular pressures, monophasic action potentials and coronary flow were measured throughout the experiment and infarct size was detected at the end of experiment.

RESULTS

(1) The mitochondria-selective K(ATP) channel opener diazoxide reduced infarct size as compared to control (p < 0.05); (2) IPC reduced infarct size and preserved postischemic diastolic function as compared to control (p < 0.05), and (3) the mitochondria-selective K(ATP) channel blocker 5-HD reversed these effects.

CONCLUSION

The mitochondrial ATP-sensitive potassium channel may be a potential site of cardioprotection.