Activation of ATP-Sensitive Potassium Channels Underlies Contractile Failure in Single Human Cardiac Myocytes During Complete Metabolic Inhibition

Novel protection strategy for pulmonary transplantation

BACKGROUND

Ischemia-reperfusion injury continues to represent a significant challenge to successful lung transplantation. Traditional pulmonary ischemic protection is performed using hypothermic hyperkalemic depolarizing solutions to reduce the metabolic demands of the ischemic organ. Measures to further reduce the effects of ischemic injury have focused on the reperfusion period. We tested the hypothesis that novel physiologic hyperpolarizing solutions-using ATP-dependent potassium channel (K(ATP)) openers-given at the induction of ischemia, will reduce cellular injury and provide superior graft function even after prolonged periods of ischemia.

METHODS

An isolated blood-perfused ventilated rabbit lung model was used to study lung injury. Airway, left atrial, and pulmonary artery pressures were measured continuously during the 2-h reperfusion period. Oxygenation, as a surrogate of graft function, was measured using intermittent blood gas analysis of paired left atrial and pulmonary artery blood samples. Graft function was measured by oxygen challenge technique (F(i)O(2) = 1.0). Wet-to-dry ratio was measured at the conclusion of the 2-h reperfusion period. Control (Group I) lungs were perfused with modified Euro-Collins solution (depolarizing) and reperfused immediately (no ischemia). Traditional protection lungs were perfused with modified Euro-Collins flush solution and stored for 4 h (Group II) or 18 h (Group III) at 4 degrees C before reperfusion. Novel protection (Group IV) lungs were protected with a hyperpolarizing solution containing 100 nM Aprikalim, a specific K(ATP) channel opener, added to the modified Euro-Collins flush solution and underwent 18 h of ischemic storage at 4 degrees C before reperfusion.

RESULTS

Profound graft failure was measured after 18 h of ischemic storage with traditional protection strategies (Group III). Graft function was preserved by protection with hyperpolarizing solutions even for prolonged ischemic periods (Group IV). Wet-to-dry weight ratio, airway, left atrial, and pulmonary artery pressures were not significantly different between the groups.

CONCLUSIONS

We have created a model of predictable lung injury. Membrane hyperpolarization with a K(ATP) channel opener (PCO) provides superior prolonged protection from ischemia-reperfusion injury in an in vitro model of pulmonary transplantation.

Reconstituted human cardiac KATP channels: functional identity with the native channels from the sarcolemma of human ventricular cells

ATP-sensitive potassium (KATP) channels in striated myocytes are heteromultimers of KIR6.2, a weak potassium inward rectifier, plus SUR2A, a low-affinity sulfonylurea receptor. We have cloned human KIR6.2 (huKIR6.2) and a huSUR2A that corresponds to the major, full-length splice variant identified by polymerase chain reaction analysis of human cardiac poly A+ mRNA. ATP- and glibenclamide-sensitive K+ channels were produced when both subunits were coexpressed in COSm6 and Chinese hamster ovary cells lacking endogenous KATP channels, but not when huSUR2A or huKIR6.2 were transfected alone. Recombinant channels activated by metabolic inhibition in cell-attached configuration or in inside-out patches with ATP-free internal solution were compared with sarcolemmal KATP channels in human ventricular cells. The single-channel conductance of approximately 80 pS measured at -40 mV in quasi-symmetrical approximately 150 mmol/L K+ solutions, the intraburst kinetics that were dependent on K+ driving force, and the weak inward rectification were indistinguishable for both channels. Similar to the native channels, huSUR2A/huKIR6.2 recombinant channels were inhibited by ATP at quasi-physiological free Mg2+ ( approximately 0. 7 mmol/L) or in the absence of Mg2+, with an apparent IC50 of approximately 20 micromol/L and a pseudo-Hill coefficient of approximately 1. They were "refreshed" by MgATP and stimulated by ADP in the presence of Mg2+ when inhibited by ATP. The huSUR2A/huKIR6.2 channels were stimulated by cromakalim and pinacidil in the presence of ATP and Mg2+ but were insensitive to diazoxide. The results suggest that reconstituted huSUR2A/huKIR6.2 channels represent KATP channels in sarcolemma of human cardiomyocytes and are an adequate experimental model with which to examine structure-function relationships, molecular physiology, and pharmacology of these channels from human heart.

The adenosine-triphosphate-sensitive potassium-channel opener pinacidil is effective in blood cardioplegia

BACKGROUND

This study was designed to evaluate the adenosine-triphosphate-sensitive potassium channel opener pinacidil as a blood cardioplegic agent.

METHODS

Using a blood-perfused, parabiotic, Langendorff rabbit model, hearts underwent 30 minutes of normothermic ischemia protected with blood cardioplegia (St. Thomas' solution [n = 8] or Krebs-Henseleit solution with pinacidil [50 micromol/L, n = 81) and 30 minutes of reperfusion. Percent recovery of developed pressure, mechanical arrest, electrical arrest, reperfusion ventricular fibrillation, percent tissue water, and myocardial oxygen consumption were compared.

RESULTS

The percent recovery of developed pressure was not different between the groups (52.3 +/- 5.9 and 52.8 +/- 6.9 for hyperkalemic and pinacidil cardioplegia, respectively). Pinacidil cardioplegia was associated with prolonged electrical and mechanical activity (14.4 +/- 8.7 and 6.1 +/- 3.9 minutes), compared with hyperkalemic cardioplegia (1.1 +/- 0.6 and 1.1 +/- 0.6 minutes, respectively; p < 0.05). Pinacidil cardioplegia was associated with a higher reperfusion myocardial oxygen consumption (0.6 +/- 0.1 versus 0.2 +/- 0.0 mL/100 g myocardium/beat; p < 0.05) and a higher percent of tissue water (79.6% +/- 0.7% versus 78.6% +/- 1.2%; p < 0.05).

CONCLUSIONS

Systolic recovery was not different between groups, demonstrating comparable effectiveness of pinacidil and hyperkalemic warm blood cardioplegia.

Preservation of myocyte contractile function after hyperthermic cardioplegic arrest by activation of ATP-sensitive potassium channels

BACKGROUND

Left ventricular (LV) dysfunction can occur after hyperkalemic cardioplegic arrest and subsequent reperfusion and rewarming. Activation of adenosine triphosphate (ATP)-sensitive potassium (KATP) channels within the myocyte sarcolemma has been shown to be cardioprotective for myocardial reperfusion injury and ischemia and may play a contributory role in preconditioning for cardioplegic arrest. Accordingly, the present study tested the hypothesis that cardioplegic arrest and activation of KATP channels by a potassium channel opener (PCO) would attenuate alterations in ionic homeostasis and improve myocyte contractile function.

METHODS AND RESULTS

Porcine LV myocytes were isolated and randomly assigned to the following treatment groups: normothermic control, incubation in cell culture media for 2 hours at 37 degrees C (n=60); hyperkalemic cardioplegia, incubation for 2 hours in hypothermic hyperkalemic cardioplegic solution (n=60); or PCO/cardioplegia, incubation in cardioplegic solution containing 100 micromol/L of the PCO aprikalim (n=60). Hyperkalemic cardioplegia and rewarming caused a significant reduction in myocyte velocity of shortening compared with normothermic control values (33+/-2 versus 66+/-2 microm/s, P<.05). Cardioplegic arrest with PCO supplementation significantly improved indices of myocyte contractile function when compared with hyperkalemic cardioplegia (58+/-4 microm/s, P<.05). Myocyte intracellular calcium increased during hyperkalemic cardioplegic arrest compared with baseline values (147+/-2 versus 85+/-2 nmol/L, P<.05). The increase in intracellular calcium was significantly reduced in myocytes exposed to the PCO-supplemented cardioplegic solution (109+/-4 nmol/L, P<.05).

CONCLUSIONS

Cardioplegic arrest with simultaneous activation of KATP channels preserves myocyte contractile processes and attenuates the accumulation of intracellular calcium. These findings suggest that changes in intracellular calcium play a role in myocyte contractile dysfunction associated with cardioplegic arrest. Moreover, alternative strategies may exist for preservation of myocyte contractile function during cardioplegic arrest.

Myocardial protection in the acutely injured heart: hyperpolarizing versus depolarizing hypothermic cardioplegia

OBJECTIVES

The superiority of hyperpolarized arrest with adenosine triphosphate-sensitive potassium channel openers over standard hyperkalemic depolarizing cardioplegia during normothermic ischemia has been documented. This study examined the hypothesis that pinacidil would provide superior protection in a more clinically relevant model of an acutely injured heart and hypothermic cardioplegic arrest.

METHODS

In a blood-perfused, parabiotic, rabbit heart Langendorff model, hearts underwent 15 minutes of unprotected global normothermic ischemia before the administration of 50 ml of cardioplegic solution at 4 degrees C, followed by 50 minutes of hypothermic (15 degrees C) ischemia and 30 minutes of reperfusion. The cardioplegic solutions administered consisted of Krebs-Henseleit solution alone (N = 6), Krebs-Henseleit solution with pinacidil (50 mumol/L; N = 10), Krebs-Henseleit solution with pinacidil (50 mumol/L) and glibenclamide (a potassium channel blocker, 10 mumol/L; N = 8), or St. Thomas' Hospital solution (N = 8). The percent recovery of developed pressure, linear diastolic pressure-volume relationships, and coronary blood flow were compared.

RESULTS

The percent recovery of developed pressure was 32.8% +/- 2.8%, 43.0% +/- 4.3%, 46.5% +/- 2.2%, and 49.3% +/- 2.7% for the Krebs-Henseleit, the Krebs-Henseleit with pinacidil and glibenclamide, the St. Thomas' Hospital, and the Krebs-Henseleit with pinacidil groups, respectively. No hearts had ventricular fibrillation on reperfusion.

CONCLUSIONS

During hypothermic hyperpolarized arrest, as opposed to normothermic ischemia as in our previous studies, there was neither an increased incidence of ventricular fibrillation nor prolonged electrical activity when compared with results during traditional hyperkalemic arrest. Myocardial protection by St. Thomas' Hospital solution and pinacidil was superior (p = 0.009) to that with Krebs-Henseleit solution alone. The protection provided by pinacidil was lost with the addition of glibenclamide, indicating that the drug has adenosine triphosphate-sensitive potassium channel activity during hypothermia.

Effects of tolbutamide on ATP-sensitive K+ channels from human right atrial cardiac myocytes

In order to gain further insight into possible deleterious effects on ischaemia-induced myocardial damage induced by sulfonylureas when administered to humans, the effects of tolbutamide on ATP-sensitive K+ (KATP) channels from human right atrial myocytes were studied. Single myocytes were enzymatically isolated from human right atrium. The cell-attached and inside-out configuration of the patch-clamp technique were employed at room temperature (both the pipette and the bath solution contained high [K+]). KATP channels in inside-out patches showed slight inward rectification, had a slope conductance of 75.1 +/- 2.4 pS (mean +/- S.E.M.; n = 5) at negative membrane potentials and these channels were blocked by ATP (half-maximal block (EC50) at 39 microM; Hill coefficient = 1.65). In cell-attached recordings, cromakalim (300 microM) opened KATP channels (with a slope conductance of 73.3 +/- 1.8 pS (n = 16) at negative membrane potentials) in previously silent patches. Cromakalim-induced openings of KATP channels were not markedly affected by 100 or 300 microM tolbutamide but were blocked by tolbutamide at millimolar concentrations (1-3 mM). The concentration-response relationship for tolbutamide-induced block of KATP channels in the presence of 300 microM cromakalim in cell-attached patches was calculated to values for the EC50 of 1.325 mM and for the Hill coefficient of 1.0, respectively. 1 mM tolbutamide-induced block of cromakalim-induced KATP channel openings was not different at room temperature when compared to 37 degrees. It is concluded that KATP channels from human right atrial myocytes have a low sensitivity towards tolbutamide-induced block.

Myocardial protection with potassium-channel openers is as effective as St. Thomas' solution in the rabbit heart

BACKGROUND

Previous work from our laboratory has demonstrated the advantage of adenosine triphosphate-sensitive potassium-channel openers as cardioplegic agents when compared with hyperkalemic (20 mmol/L KCl) Krebs-Henseleit solution. However, Krebs-Henseleit with 20 mmol/L KCl is not an ideal hyperkalemic cardioplegia. Therefore, we investigated the hypothesis that hyperpolarized arrest with pinacidil and aprikalim could provide equal or superior myocardial protection to hyperkalemic arrest with the widely accepted St. Thomas' solution.

METHODS

Myocardial protection was compared in the blood-perfused isolated parabiotic rabbit heart Langendorff model. Twenty-four hearts were protected with a 50-mL infusion of cardioplegia for a 30-minute global normothermic ischemic period followed by 30 minutes of reperfusion. Systolic function (percent recovery of developed pressure) and the diastolic properties of the left ventricle were measured. Coronary blood flow was measured throughout each experiment.

RESULTS

The percent recovery of developed pressure (mean +/- standard error of the mean) for St. Thomas' solution, pinacidil, and aprikalim was 53.1% +/- 5.4%, 64.0% +/- 3.0%, and 62.4% +/- 3.2%, respectively. The time (minutes) until mechanical and electrical arrest was significantly longer in the pinacidil (4.82 +/- 0.10 and 12.06 +/- 1.07) and aprikalim (3.33 +/- 0.28 and 11.12 +/- 0.94) groups when compared with the St. Thomas group (1.84 +/- 0.74, and 3.17 +/- 1.44). Coronary blood flow upon reperfusion was significantly greater in the pinacidil (16.4 +/- 2.1 mL/min) and aprikalim (19.4 +/- 2.8 mL/min) groups compared with the St. Thomas' solution group (8.0 +/- 1.0 mL/min), and this returned to baseline after 15 minutes of reperfusion.

CONCLUSIONS

Myocardial protection with pinacidil and aprikalim is comparable with that of St. Thomas' solution in the blood-perfused isolated rabbit heart despite prolonged mechanical and electrical activity during ischemia.

Myocardial protection with pinacidil cardioplegia in the blood-perfused heart

BACKGROUND

Adenosine triphosphate-sensitive potassium-channel openers are potent vasodilators that have been found to be cardioprotective during myocardial ischemia. The potassium-channel opener pinacidil was investigated to determine its efficacy as a cardioplegic agent.

METHODS

A blood-perfused, parabiotic, isolated rabbit heart Langendorff preparation was used. Fifty-six hearts underwent 30 minutes of global normothermic ischemia after a 50-mL infusion of cardioplegia, followed by 60 minutes of reperfusion. The cardioplegia consisted of Krebs-Henseleit solution with either vehicle alone (control), 20 mmol KCl, or pinacidil (10, 50, 100, 150, or 200 mumol/L). The developed pressure was measured at baseline and after reperfusion. Coronary blood flow was measured with an in-line ultrasonic probe.

RESULTS

Pinacidil (50 mumol/L), as opposed to potassium cardioplegia, provided significantly better postischemic percentage recovery of developed pressure compared with controls (68.3% +/- 4.0% versus 44.6% +/- 5.5%; p < 0.05). The time until electrical arrest was significantly shorter in the hyperkalemic group than in all other groups. Linear end-diastolic pressure-volume relationships revealed an increase in slope after ischemia in all groups. Coronary flow after 5 minutes of reperfusion was significantly higher in both the 50-mumol/L and 100-mumol/L pinacidil groups compared with traditional hyperkalemic arrest, and this returned to baseline after 15 minutes.

CONCLUSIONS

The potassium channel opener pinacidil provided dose-dependent myocardial protection during global ischemia in the blood-perfused rabbit heart model. Potassium-channel openers are a promising class of drugs that may provide an alternative to traditional hyperkalemic cardioplegia.

Hyperpolarized cardiac arrest with a potassium-channel opener, aprikalim

Cardioplegic solutions that arrest the heart at or near the resting membrane potential may provide better myocardial protection than standard depolarizing hyperkalemic cardioplegia by reducing both metabolic demand and harmful transmembrane ion fluxes. This hypothesis was investigated in an isolated, blood-perfused, rabbit heart Langendorff model during 30 minutes of normothermic global ischemia. Hyperpolarized cardiac arrest induced by aprikalim, an opener of adenosine triphosphate-dependent potassium channels, was compared with hyperkalemic depolarized arrest and with unprotected global ischemia. Left ventricular pressure was recorded over a wide range of balloon volumes before ischemia and 30 minutes after reperfusion. End-diastolic pressure versus balloon volume data were fitted to a two-coefficient exponential relationship. Changes in the diastolic compliance of the left ventricle were assessed by comparison of preischemic and postischemic coefficients within each cardioplegia group. Postischemic recovery of developed pressure was used to assess changes in left ventricular systolic function. The tissue water content of each heart was also determined. Myocardial protection with aprikalim resulted in better postischemic recovery of developed pressure (90% +/- 9%) than either protection with hyperkalemic cardioplegia (73% +/- 11%) or no protection (62% +/- 9%). Myocardial tissue water content in hearts protected with hyperkalemic cardioplegia (77.4% +/- 1.4%) was less than the tissue water content of either unprotected hearts (79.4% +/- 1.2%) or hearts protected with aprikalim (78.7% +/- 0.9%). Despite these differences, neither hyperkalemic cardioplegia (p = 0.15) nor aprikalim cardioplegia (p = 0.30) was associated with a significant postischemic decrease in ventricular compliance. By contrast, unprotected global ischemia was associated with a significant decrease in ventricular compliance (p < 0.001).

Is there an alternative to potassium arrest?

BACKGROUND

Mounting clinical and experimental evidence suggests that postoperative myocardial dysfunction is a frequent consequence of surgical global ischemia and reperfusion, despite our modern techniques of myocardial protection. The ubiquitous use of hyperkalemic depolarizing solutions in all forms of cardioplegia may be partly responsible for this phenomenon because of the known ongoing metabolic processes and damaging transmembrane ionic fluxes that occur at depolarized membrane potentials. Cardiac arrest at hyperpolarized potentials, the natural resting state of the heart, may avoid the shortcomings of depolarized arrest and provide an alternative means of myocardial protection.

METHODS

An adenosine triphosphate-sensitive potassium channel opener, aprikalim, was used to induce hyperpolarized arrest. Aprikalim was able to produce sustained and reproducible electromechanical arrest that was reversible by reperfusion.

RESULTS

In isolated heart models, when compared with depolarized hyperkalemic arrest, hyperpolarized arrest afforded better protection from global normothermic ischemia and resulted in better postischemic recovery of function upon reperfusion. Preliminary studies in a porcine cardiopulmonary bypass model also have revealed that hyperpolarized arrest can be achieved in a model more closely approximating the clinical setting, and can effectively protect the heart during normothermic surgical global ischemia.

CONCLUSIONS

Hyperpolarized cardiac arrest may offer an effective alternative to traditional potassium arrest.

Hyperpolarized arrest attenuates myocardial stunning following global surgical ischemia: an alternative to traditional hyperkalemic cardioplegia?

There is clinical evidence that myocardial stunning is a frequent sequela of surgical global ischemia, despite our modern techniques of myocardial protection. The ubiquitous usage of hyperkalemic depolarizing solutions in all forms of cardioplegia may be partly responsible for this phenomenon because of the known ongoing metabolic requirements and damaging transmembrane ionic fluxes that occur at depolarized membrane potentials. Cardiac arrest at hyperpolarized potentials, the natural resting state of the heart, may avoid the shortcomings of depolarized arrest and provide an alternative means of myocardial protection. To test this hypothesis, a potassium channel opener, aprikalim, was used to induce hyperpolarized arrest in an isolated rabbit heart model. Aprikalim was able to produce sustained and reproducible electromechanical arrest that was reversible by reperfusion. When compared with depolarized hyperkalemic arrest, hyperpolarized arrest afforded better protection after short 20-minute periods of global ischemia and resulted in less myocardial stunning. Moreover, aprikalim was able to significantly prolong the time to ischemic contracture and improve functional recovery after the onset of ischemic contracture when compared with either traditional hyperkalemic cardioplegia or no cardioplegia at all. There was a dose dependence to the protective effect of aprikalim. Preliminary studies in the intact porcine cardiopulmonary bypass model also have revealed that hyperpolarized arrest can effectively protect the heart during surgical global ischemia.

Calcium current in single human cardiac myocytes

INTRODUCTION

Significant species-, tissue-, and age-dependent differences have been described for the L-type calcium current (ICa). Therefore, extrapolation of data obtained from the many animal models to human cardiac physiology is difficult. In this study, we have characterized the voltage-dependent properties of ICa from pediatric and adult, atrial and ventricular human heart tissue.

METHODS AND RESULTS

ICa was measured in single human heart muscle cells using the "whole cell," voltage clamp method. Single myocytes were isolated from myocardial specimens obtained intraoperatively from both pediatric and adult patients (ages 3 months to 75 years) undergoing cardiac surgery. Cells obtained for these experiments appeared to be healthy; the resting potential was between -80 and -85 mV. The action potential shape and duration and current-voltage relationship for ICa were similar to that reported by others for human heart cells. The steady-state activation variable, d infinity, was found to be similar in both pediatric atrial and ventricular cells but shifted approximately 5 mV negative in the adult atrial and ventricular cells. ICa of all cells displayed biexponential inactivation and steady-state inactivation was incomplete at positive potentials (steady-state inactivation curves turned up at positive potentials) consistent with inactivation arising from voltage-dependent and calcium-dependent processes as reported in heart cells from many species. The potential of maximal inactivation was more negative for adult cells (around -10 mV) than pediatric cells (around 0 mV). Estimates of the calcium "window" current, using a modified Hodgkin-Huxley model, could explain measured differences in action potential shape and duration.

CONCLUSION

Human cardiac ICa can be investigated using whole cell, voltage clamp methods and a modified Hodgkin-Huxley model. Quantitative characterization of many of the properties of ICa in human heart tissue suggests that important species differences do exist and that further investigations are required to characterize the dependence of inactivation on [Ca2+]i in human heart cells. Since the array of characteristics of ICa in different species varies, the study of human myocardial cells per se continues to be important when examining human cardiac physiology.