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Meeting Abstracts  |   September 2001
Lidocaine and Mexiletine Inhibit Mitochondrial Oxidation in Rat Ventricular Myocytes
Author Affiliations & Notes
  • Yasuo Tsutsumi, M.D.
    *
  • Shuzo Oshita, M.D.
  • Takashi Kawano, M.D.
  • Hiroshi Kitahata, M.D.
    §
  • Yoshinobu Tomiyama, M.D.
    ‖‖
  • Yasuhiro Kuroda, M.D.
    #
  • Yutaka Nakaya, M.D.
    **
  • * Resident, † Professor and Chairman, ‡ Postgraduate Student, § Associate Professor, ‖‖ Assistant Professor, Department of Anesthesiology, # Associate Professor, Division of Critical Care Medicine, ** Professor and Chairman, Department of Nutrition, Tokushima University School of Medicine, Tokushima, Japan.
  • Received from the Department of Anesthesiology, Tokushima University School of Medicine, Tokushima, Japan.
Article Information
Meeting Abstracts   |   September 2001
Lidocaine and Mexiletine Inhibit Mitochondrial Oxidation in Rat Ventricular Myocytes
Anesthesiology 9 2001, Vol.95, 766-770. doi:
Anesthesiology 9 2001, Vol.95, 766-770. doi:
CARDIAC myocytes and other cells have adenosine triphosphate (ATP)–sensitive K+(KATP) channels in the inner mitochondrial membrane, which respond to many of the same openers and blockers as do the sarcolemmal channels. 1–4 Although the physiologic roles of mitochondrial KATPchannels in cardiac myocytes remain unclear, mitochondrial rather than sarcolemmal KATPchannels may be more important for the protection of myocardium during ischemia. Garlid et al.  5 reported that mitochondrial KATPchannels mediate cardioprotection produced by KATPchannel openers. The results of recent studies support this hypothesis. 6–10 
Lidocaine and mexiletine are antiarrhythmic drugs used most frequently for treatment of ventricular arrhythmias during myocardial ischemia. We previously reported that the effects of lidocaine on Na+channel activities 11 are similar to those of mexiletine, 12 but recent studies suggest that these drugs have different effects on sarcolemmal KATPchannel activities. Lidocaine inhibits, 13,14 whereas mexiletine inhibits, 15 does not affect, 16 or activates 17 sarcolemmal KATPchannels. To determine whether lidocaine and mexiletine affect mitochondrial oxidation mediated by mitochondrial KATPchannels, we measured flavoprotein fluorescence in isolated rat ventricular myocytes.
Materials and Methods
Preparation of Cardiac Ventricular Myocytes
This study was approved by the Animal Investigation Committee of Tokushima University (Tokushima, Japan) and followed the animal use guidelines of the American Physiological Society (Bethesda, MD). Forty-eight male Wistar rats (250–300 g) were anesthetized with ether, and 1.0 IU/g heparin was injected intraperitoneally 30 min before surgery. Myocytes were obtained enzymatically (0.2 mg/ml collagenase and 0.05 mg/ml protease) using a Langendorff apparatus. The enzymatic dissociation method was similar to that of our previous study. 18 
Flavoprotein Fluorescence Measurement
Rod-shaped, clear striated ventricular myocytes were cultured on laminin-coated coverslips in M199 culture medium with 5% fetal bovine serum at 37°C. Experiments were performed during the next day. The mitochondrial redox state was monitored by recording the fluorescence of flavin adenine nucleotide-linked enzymes in mitochondria and served as an index of mitochondrial KATPchannel activities. Myocytes were superfused with bath solution containing 140 mm NaCl , 5 mm KCl, 1 mm CaCl2, 1 mm MgCl2, and 10 mm HEPES (pH adjusted to 7.4 with NaOH) at room temperature (20 ± 2°C). Fluorescence was monitored microscopically (Eclipse TS100; Nikon, Tokyo, Japan) with a digital charge coupled device camera (ORCA; Hamamatsu Photonics, Hamamatsu, Japan) from one cell at a time by focusing on individual myocytes. Fluorescence of single cells was excited for 100 ms every 10 s. Excitation of flavoprotein was obtained from a Xenon arc lamp filtered at 450–490 nm and reflected to the microscope objective lens (×40) by a dichroic mirror centered at 505 nm. Emitted fluorescence was recorded to pass through the dichroic mirror to a 520-nm-long path filter and was stored on a computer. The redox signal images were analyzed for average pixel intensities of regions of interest on a myocyte using an image processing system (AQUACOSMOS; Hamamatsu Photonics). The change of fluorescence was normalized to the baseline flavoprotein fluorescence obtained after exposure to 5 μm 2,4-dinitrophenol (DNP), a protonophore that uncouples respiration from ATP synthesis and collapses the mitochondrial potential, at the end of the experiments. At least 30 normalized fluorescence images were averaged before (diazoxide alone) and at each concentration of drugs. In the first series of the experiments, the effects of diazoxide, a selective mitochondrial KATPchannel opener, 6 and 5-hydroxydecanoic acid sodium (5-HD), a relatively selective mitochondrial KATPchannel blocker, on flavoprotein fluorescence were evaluated. Then we assessed the effects of diazoxide alone and in combination with lidocaine or mexiletine on flavoprotein fluorescence in the following series. In the same cell, flavoprotein fluorescence was recorded before (diazoxide alone) and at five concentrations of either lidocaine (103∼ 10 mm) or mexiletine (103∼ 10 mm). Six data points obtained in the same cell were plotted as drug concentration compared with the normalized flavoprotein fluorescence; then these data were converted to probits, and the concentration–response equation was calculated by least-square curve fitting. From this equation, the concentrations of lidocaine or mexiletine needed to induce 50% inhibition of diazoxide-induced flavoprotein oxidation (EC50) were calculated in each cell.
Drugs
Lidocaine and mexiletine were obtained from Sigma Chemical (St. Louis, MO). Diazoxide (Sigma) was dissolved in dimethyl sulfoxide (< 0.1%) and prepared as a stock solution. 5-HD was purchased from Biomol Research Laboratories (Plymouth Meeting, PA). All other solutions were made daily.
Statistical Analysis
Data are expressed as mean ± SD. Differences among data sets were evaluated by analysis of variance followed by Student-Newman-Keuls post hoc  test. A P  value less than 0.05 was considered significant.
Results
Effects of Diazoxide and 5-HD on Mitochondrial KATPChannels
Figure 1shows the representative example of flavoprotein fluorescence in cells exposed to diazoxide and 5-HD. The flavoprotein fluorescence value was expressed as a percent of that exposed to 5 μm DNP at the end of the experiments (DNP value). Diazoxide (25 μm) caused reversible mitochondrial oxidation to 63 ± 19% of the DNP values (n = 7). 5-HD (100 μm) attenuated the oxidative effects of diazoxide to 2 ± 5% of the DNP value (P  < 0.05 vs.  diazoxide, n = 7). After washout of these drugs, mitochondrial oxidation was restored to the baseline level.
Fig. 1. The effects of diazoxide alone or in combination with 5-hydroxydecanoic acid (5-HD) on flavoprotein fluorescence. Diazoxide (25 μm) induced a reversible increase of mitochondrial oxidation (n = 7). 5-HD (100 μm) significantly attenuated the oxidative effects of diazoxide. After washout of diazoxide, mitochondrial oxidation was restored to the baseline level. The redox signal was normalized to the baseline flavoprotein fluorescence obtained during exposure to 5 μm 2,4-dinitrophenol (DNP) at the end of the experiments.
Fig. 1. The effects of diazoxide alone or in combination with 5-hydroxydecanoic acid (5-HD) on flavoprotein fluorescence. Diazoxide (25 μm) induced a reversible increase of mitochondrial oxidation (n = 7). 5-HD (100 μm) significantly attenuated the oxidative effects of diazoxide. After washout of diazoxide, mitochondrial oxidation was restored to the baseline level. The redox signal was normalized to the baseline flavoprotein fluorescence obtained during exposure to 5 μm 2,4-dinitrophenol (DNP) at the end of the experiments.
Fig. 1. The effects of diazoxide alone or in combination with 5-hydroxydecanoic acid (5-HD) on flavoprotein fluorescence. Diazoxide (25 μm) induced a reversible increase of mitochondrial oxidation (n = 7). 5-HD (100 μm) significantly attenuated the oxidative effects of diazoxide. After washout of diazoxide, mitochondrial oxidation was restored to the baseline level. The redox signal was normalized to the baseline flavoprotein fluorescence obtained during exposure to 5 μm 2,4-dinitrophenol (DNP) at the end of the experiments.
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Effects of lidocaine on Mitochondrial KATPChannels
Figure 2shows the relation between lidocaine concentration and diazoxide (25 μm)-induced flavoprotein oxidation (n = 7). Flavoprotein oxidation was 63 ± 5% in the presence of diazoxide alone. With lidocaine, flavoprotein oxidation was 63 ± 7% at 0.001 mm, 42 ± 14% at 0.01 mm (P  < 0.05 vs.  diazoxide alone), 25 ± 7% at 0.1 mm (P  < 0.05), 9 ± 9% at 1 mm (P  < 0.05), and 1 ± 1% at 10 mm (P  < 0.05). Lidocaine induced 50% inhibition of diazoxide-induced flavoprotein oxidation (EC50) at 98 ± 63 μm concentration.
Fig. 2. Concentration-dependent effects of lidocaine on diazoxide (25 μm)-induced flavoprotein oxidation. The redox signal was normalized to the baseline flavoprotein fluorescence obtained during exposure to 5 μm 2,4-dinitrophenol (DNP) at the end of the experiments. Each bar constitutes measurements from seven single ventricular myocytes. *P  < 0.05 versus  diazoxide alone.
Fig. 2. Concentration-dependent effects of lidocaine on diazoxide (25 μm)-induced flavoprotein oxidation. The redox signal was normalized to the baseline flavoprotein fluorescence obtained during exposure to 5 μm 2,4-dinitrophenol (DNP) at the end of the experiments. Each bar constitutes measurements from seven single ventricular myocytes. *P 
	< 0.05 versus 
	diazoxide alone.
Fig. 2. Concentration-dependent effects of lidocaine on diazoxide (25 μm)-induced flavoprotein oxidation. The redox signal was normalized to the baseline flavoprotein fluorescence obtained during exposure to 5 μm 2,4-dinitrophenol (DNP) at the end of the experiments. Each bar constitutes measurements from seven single ventricular myocytes. *P  < 0.05 versus  diazoxide alone.
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Effects of Mexiletine on Mitochondrial KATPChannels
Figure 3shows that mexiletine, like lidocaine, reduced the diazoxide-induced oxidation of flavoproteins in a concentration-dependent manner. Flavoprotein oxidation was 64 ± 6% in the presence of diazoxide alone. With mexiletine, flavoprotein oxidation was 61 ± 8% at 0.001 mm, 51 ± 5% at 0.01 mm (P  < 0.05 vs.  diazoxide alone), 34 ± 10% at 0.1 mm (P  < 0.05), 23 ± 5% at 1 mm (P  < 0.05), and 1 ± 4% at 10 mm (P  < 0.05;fig. 3B; n = 10). The EC50for mexiletine to induce 50% inhibition of diazoxide-induced flavoprotein oxidation was 107 ± 89 μm.
Fig. 3. Concentration-dependent effects of mexiletine on diazoxide (25 μm)-induced flavoprotein oxidation. The redox signal was normalized to the baseline flavoprotein fluorescence obtained during exposure to 5 μm 2,4-dinitrophenol at the end of the experiments. Each bar constitutes measurements from 10 single ventricular myocytes. *P  < 0.05 versus  diazoxide alone.
Fig. 3. Concentration-dependent effects of mexiletine on diazoxide (25 μm)-induced flavoprotein oxidation. The redox signal was normalized to the baseline flavoprotein fluorescence obtained during exposure to 5 μm 2,4-dinitrophenol at the end of the experiments. Each bar constitutes measurements from 10 single ventricular myocytes. *P 
	< 0.05 versus 
	diazoxide alone.
Fig. 3. Concentration-dependent effects of mexiletine on diazoxide (25 μm)-induced flavoprotein oxidation. The redox signal was normalized to the baseline flavoprotein fluorescence obtained during exposure to 5 μm 2,4-dinitrophenol at the end of the experiments. Each bar constitutes measurements from 10 single ventricular myocytes. *P  < 0.05 versus  diazoxide alone.
×
Discussion
The major findings in the current study are that both drugs inhibit diazoxide-induced flavoprotein fluorescence, which correlates with mitochondrial oxidation and depolarization. Activation of KATPchannels produces cardioprotective effects in cardiac myocytes, 19 but the underlying mechanisms for such cardioprotection are poorly understood. One early hypothesis proposed that opening sarcolemmal KATPchannels shortens the action potential duration and then depresses contractility, 19,20 which is a major source of ATPconsumption. Recent evidence, however, contradicts this hypothesis. Yao and Gross 21 found that a low dose of the KATPchannel opener bimakalim had a minimal effect on action potential duration but still reduced infarction size. Such dissociation has also been shown in other studies. 22–25 These data suggest that abbreviation of action potential duration may not be necessary for cardiac protection. The opening of mitochondrial rather than sarcolemmal KATPchannels may be a major contributor to cardiac protection against ischemia. 5 Although the physiologic and pathophysiologic roles of the mitochondrial KATPchannel are not yet clear, opening mitochondrial KATPchannels results in K+entry and intramitochondrial depolarization. 1 Therefore, a possible mechanism for the cardioprotective action of mitochondrial KATPchannels is that dissipation of inner mitochondrial membrane potential decreases the driving force for Ca2+influx through the Ca2+uniporter. 6 This would reduce mitochondrial Ca2+overload and cause matrix swelling, which has been shown to enhance ATP synthesis and stimulate mitochondrial respiration. 6 Another possibility is that opening mitochondrial KATPchannels, by decreasing the membrane potential, could promote binding of the endogenous mitochondrial ATPase inhibitor 26 and thus conserve ATP during ischemia.
The mitochondrial redox state can be monitored by recording the fluorescence of flavin adenine nucleotide–linked enzymes in the mitochondria. 27,28 To test the hypothesis that mitochondrial KATPchannels have an important role in cardioprotection, Liu et al.  6 examined the effects of diazoxide on both mitochondrial and sarcolemmal KATPchannel activities using flavoprotein fluorescence, an index of mitochondrial redox state, and sarcolemmal KATPcurrents as indicators in intact rabbit ventricular myocytes and showed that diazoxide induced reversible oxidation of flavoproteins but did not activate sarcolemmal KATPchannels. They also found that diazoxide decreased the rate of cell death in a cellular model of simulated ischemia to approximately half that of controls. They concluded that diazoxide targets mitochondrial but not sarcolemmal KATPchannels and that the opening of mitochondrial rather than sarcolemmal KATPchannels might contribute to cardiac protection against ischemia. 6 These results are similar to those obtained in the current study. We also studied the effects of diazoxide alone or in combination with 5-HD on flavoprotein oxidation in isolated rat ventricular myocytes and found that diazoxide caused reversible mitochondrial oxidation and that 5-HD attenuated the oxidative effects of diazoxide (fig. 1). Therefore, the results reported by Liu et al.  6 and the results of the current study led us to conclude that the flavoprotein fluorescence we measured reflects the redox state of mitochondria.
In the current study, both lidocaine and mexiletine reduced diazoxide-induced oxidation of flavoprotein in a concentration-dependent manner, suggesting that both drugs attenuate mitochondrial KATPchannel activities. If the opening of mitochondrial rather than sarcolemmal KATPchannels contributes to cardiac protection against ischemia, blockade of mitochondrial KATPchannels by lidocaine and mexiletine may produce impairment of mitochondrial oxidation mediated by mitochondrial KATPchannels. That is, our results suggest that both drugs may attenuate cardioprotective effects of mitochondrial KATPchannels. In contrast, blockade of sarcolemmal KATPchannels by lidocaine and mexiletine may be advantageous in the prevention of arrhythmia. During myocardial ischemia, extracellular myocardial K+concentration in the ischemic zone increases, and the resultant slowing of impulse propagation has a pivotal role in the pathogenesis of ventricular arrhythmia. 29 In heart cells, KATPchannels are activated by depletion of intracellular ATP, hypoxia, or exposure to metabolic inhibitors 18 and cause an increase in K+efflux. The activation of KATPchannels is at least partially responsible for the increase in outward K+currents, shortening of action potential duration, and increase in extracellular K+concentration during anoxic or globally ischemic conditions. 30–32 Bekheit et al.  30 reported that glibenclamide, a KATPchannel blocker, decreases the K+loss from ischemic myocardium and reduces the incidence of arrhythmia. These findings suggest a significant contribution of sarcolemmal KATPchannels to the formation of cardiac arrhythmia during ischemia. 30–33 
Both lidocaine and mexiletine are known to exert their therapeutic effects by selectively blocking voltage-dependent Na+channels in a rate- and concentration-dependent manner. 11,12 In addition, many reports have evaluated the effects of these drugs on sarcolemmal KATPchannel activities. Using voltage clamp techniques, Yoneda et al.  13 reported that lidocaine inhibits KATPchannel activities in a concentration-dependent manner in Xenopus  oocytes. Using patch clamp techniques, Olschewski et al.  14 also reported that lidocaine blocked KATPchannels in rat cardiomyocytes (EC50= 43 μm). In contrast, the effects of mexiletine on KATPchannel activities are controversial. Tricarico et al.  15 reported that mexiletine was a state-dependent KATPchannel inhibitor in skeletal muscle. In ventricular muscles, Wu et al.  16 found that 30 μm mexiletine did not significantly affect KATPcurrent, whereas Sato et al.  17 reported that mexiletine shortened action potential duration via  partial activation of KATPchannels.
In the current study, the EC50s for both lidocaine and mexiletine were higher than those in clinical use. The EC50s obtained in the current study were 98 μm for lidocaine and 107 μm for mexiletine, whereas the therapeutic ranges of plasma concentration of lidocaine and mexiletine used as antiarrhythmic drugs have been reported as approximately 5–30 and 2–9 μm, respectively. 34–36 In addition, we studied the effects of drugs in isolated rat ventricular myocytes. The effects of these drugs on rat myocardium may be different from the effects on human myocardium. Therefore, we should be careful in extending the current results to the human heart.
In conclusion, both lidocaine and mexiletine reduced flavoprotein fluorescence induced by diazoxide in rat ventricular myocytes, indicating that these antiarrhythmic drugs may produce impairment of mitochondrial oxidation mediated by mitochondrial KATPchannels.
References
Inoue I, Nagase H, Kishi K, Higuti T: ATP-sensitive K+channel in the mitochondrial inner membrane. Nature 1991; 352: 244–7Inoue, I Nagase, H Kishi, K Higuti, T
Paucek P, Mironova G, Mahdi F, Beavis AD, Woldegiorgis G, Garlid KD: Reconstitution and partial purification of the glibenclamide-sensitive, ATP-dependent K+channels from rat liver and beef heart mitochondria. J Biol Chem 1992; 267: 26062–9Paucek, P Mironova, G Mahdi, F Beavis, AD Woldegiorgis, G Garlid, KD
Szewczyk A, Wojcik G, Nalecz MJ: Potassium channel opener, RP 66471, induces membrane depolarization of rat liver mitochondria. Biochem Biophys Res Commun 1995; 207: 126–32Szewczyk, A Wojcik, G Nalecz, MJ
Garlid KD, Paucek P, Yarov-Yarovoy V, Sun X, Schindler PA: The mitochondrial KATPchannel as a receptor for potassium channel openers. J Biol Chem 1996; 271: 8796–9Garlid, KD Paucek, P Yarov-Yarovoy, V Sun, X Schindler, PA
Garlid KD, Paucek P, Yarov-Yarovoy V, Murray HN, Darbenzio RB, D’Alonzo AJ, Lodge NJ, Smith MA, Grover GJ: Cardioprotective effect of diazoxide and its interaction with mitochondrial ATP-sensitive K+channels: Possible mechanism of cardioprotection. Circ Res 1997; 81: 1072–82Garlid, KD Paucek, P Yarov-Yarovoy, V Murray, HN Darbenzio, RB D’Alonzo, AJ Lodge, NJ Smith, MA Grover, GJ
Liu Y, Sato T, O’Rourke B, Marban E: Mitochondrial ATP-dependent potassium channels: Novel effectors of cardioprotection? Circulation 1998; 97: 2463–9Liu, Y Sato, T O’Rourke, B Marban, E
Sato T, O’Rourke B, Marban E: Modulation of mitochondrial ATP-dependent K+channels by protein kinase C. Circ Res 1998; 83: 110–4Sato, T O’Rourke, B Marban, E
Sasaki N, Sato T, Ohler A, O’Rourke B, Marban E: Activation of mitochondrial ATP-dependent potassium channels by nitric oxide. Circulation 2000; 101: 439–45Sasaki, N Sato, T Ohler, A O’Rourke, B Marban, E
Sato T, Sasaki N, O’Rourke B, Marban E: Nicorandil, a potent cardioprotective agent, acts by opening mitochondrial ATP-dependent potassium channels. J Am Coll Cardiol 2000; 35: 514–8Sato, T Sasaki, N O’Rourke, B Marban, E
Sato T, Sasaki N, O’Rourke B, Marban E: Adenosine primes the opening of mitochondrial ATP-sensitive potassium channels: A key step in ischemic preconditioning? Circulation 2000; 102: 800–5Sato, T Sasaki, N O’Rourke, B Marban, E
Oshita S, Sada H, Kojima M, Ban T: Effects of tocainide and lidocaine on the transmembrane action potentials as related to external potassium and calcium concentrations in guinea-pig papillary muscles. Naunyn Schmiedebergs Arch Pharmacol 1980; 314: 67–82Oshita, S Sada, H Kojima, M Ban, T
Sada H, Ban T, Oshita S: Effects of mexiletine on transmembrane action potentials as affected by external potassium concentration and by rate of stimulation in guinea-pig papillary muscles. Clin Exp Pharmacol Physiol 1980; 7: 583–93Sada, H Ban, T Oshita, S
Yoneda I, Sakuta H, Okamoto K, Watanabe Y: Effects of local anesthetics and related drugs on endogenous glibenclamide-sensitive K+channels in Xenopus  oocytes. Eur J Pharmacol 1993; 247: 267–72Yoneda, I Sakuta, H Okamoto, K Watanabe, Y
Olschewski A, Brau ME, Olschewski H, Hempelmann G, Vogel W: ATP-dependent potassium channel in rat cardiomyocytes is blocked by lidocaine: Possible impact on the antiarrhythmic action of lidocaine. Circulation 1996; 93: 656–9Olschewski, A Brau, ME Olschewski, H Hempelmann, G Vogel, W
Tricarico D, Barbieri M, Franchini C, Tortorella V, Camerino DC: Effects of mexiletine on ATP sensitive K+channel of rat skeletal muscle fibres: A state dependent mechanism of action. Br J Pharmacol 1998; 125: 858–64Tricarico, D Barbieri, M Franchini, C Tortorella, V Camerino, DC
Wu B, Sato T, Kiyosue T, Arita M: Blockade of 2,4-dinitrophenol induced ATP sensitive potassium current in guinea pig ventricular myocytes by class I antiarrhythmic drugs. Cardiovasc Res 1992; 26: 1095–101Wu, B Sato, T Kiyosue, T Arita, M
Sato T, Shigematsu S, Arita M: Mexiletine-induced shortening of the action potential duration of ventricular muscles by activation of ATP-sensitive K+channels. Br J Pharmacol 1995; 115: 381–2Sato, T Shigematsu, S Arita, M
Tsutsumi Y, Oshita S, Kitahata H, Kuroda Y, Kawano T, Nakaya Y: Blockade of adenosine triphosphate-sensitive potassium channels by thiamylal in rat ventricular myocytes. A nesthesiology 2000; 92: 1154–9Tsutsumi, Y Oshita, S Kitahata, H Kuroda, Y Kawano, T Nakaya, Y
Nichols CG, Ripoll C, Lederer WJ: ATP-sensitive potassium channel modulation of the guinea pig ventricular action potential and contraction. Circ Res 1991; 68: 280–7Nichols, CG Ripoll, C Lederer, WJ
O’Rourke B, Ramza BM, Marban E: Oscillations of membrane current and excitability driven by metabolic oscillations in heart cells. Science 1994; 265: 962–6O’Rourke, B Ramza, BM Marban, E
Yao Z, Gross GJ: Effects of the KATPchannel opener bimakalim on coronary blood flow, monophasic action potential duration, and infarct size in dogs. Circulation 1994; 89: 1769–75Yao, Z Gross, GJ
Grover GJ, D’Alonzo AJ, Parham CS, Darbenzio RB: Cardioprotection with the KATPopener cromakalim is not correlated with ischemic myocardial action potential duration. J Cardiovasc Pharmacol 1995; 26: 145–52Grover, GJ D’Alonzo, AJ Parham, CS Darbenzio, RB
Grover GJ, D’Alonzo AJ, Dzwonczyk S, Parham CS, Darbenzio RB: Preconditioning is not abolished by the delayed rectifier K+blocker dofetilide. Am J Physiol 1996; 271: H1207–14Grover, GJ D’Alonzo, AJ Dzwonczyk, S Parham, CS Darbenzio, RB
Liu Y, Gao WD, O’Rourke B, Marban E: Cell-type specificity of preconditioning in an in vitro model. Basic Res Cardiol 1996; 91: 450–7Liu, Y Gao, WD O’Rourke, B Marban, E
Grover GJ, D’Alonzo AJ, Hess T, Sleph PG, Darbenzio RB: Glyburide-reversible cardioprotective effect of BMS-180448 is independent of action potential shortening. Cardiovasc Res 1995; 30: 731–8Grover, GJ D’Alonzo, AJ Hess, T Sleph, PG Darbenzio, RB
Rouslin W: Regulation of the mitochondrial ATPase in situ  in cardiac muscle: Role of the inhibitor subunit. J Bioenerg Biomembr 1991; 23: 873–88Rouslin, W
Chance B, Salkovitz IA, Kovach AGB: Kinetics of mitochondrial flavoprotein and pyridine nucleotide in perfused heart. Am J Physiol 1972; 223: 207–18Chance, B Salkovitz, IA Kovach, AGB
Hajnoczky G, Robb-Gaspers LD, Seitz MB, Thomas AP: Decoding of cytosolic calcium oscillations in the mitochondria. Cell 1995; 82: 415–24Hajnoczky, G Robb-Gaspers, LD Seitz, MB Thomas, AP
Gettes LS, Buchanan JW, Saito T, Kagiyama Y, Oshita S, Fujino T: Studies concerned with slow conduction, Cardiac Electrophysiology and Arrhythmias. Edited by Zipes DP, Jalife J. Orlando, Grune & Stratton, 1985, pp 81–7
Bekheit SS, Restivo M, Boutjdir M, Henkin R, Gooyandeh K, Assadi M, Khatib S, Gough WB, El-Sherif N: Effects of glyburide on ischemia-induced changes in extracellular potassium and local myocardial activation: A potential new approach to the management of ischemia-induced malignant ventricular arrhythmias. Am Heart J 1990; 119: 1025–33Bekheit, SS Restivo, M Boutjdir, M Henkin, R Gooyandeh, K Assadi, M Khatib, S Gough, WB El-Sherif, N
Kantor PF, Coetzee WA, Carmeliet EE, Dennis SC, Opie LH: Reduction of ischemic K+loss and arrhythmias in rat hearts: Effect of glibenclamide, a sulfonylurea. Circ Res 1990; 66: 478–85Kantor, PF Coetzee, WA Carmeliet, EE Dennis, SC Opie, LH
Wilde AAM, Escande D, Schumacher CA, Thuringer D, Mestre M, Fiolet JWT, Janse MJ: Potassium accumulation in the globally ischemic mammalian heart: A role for the ATP-sensitive potassium channel. Circ Res 1990; 67: 835–43Wilde, AAM Escande, D Schumacher, CA Thuringer, D Mestre, M Fiolet, JWT Janse, MJ
Billman GE: Role of ATP sensitive potassium channel in extracellular potassium accumulation and cardiac arrhythmias during myocardial ischaemia. Cardiovasc Res 1994; 28: 762–9Billman, GE
Rosen MR, Hoffman BF, Wit AL: Electrophysiology and pharmacology of cardiac arrhythmias: V. Cardiac antiarrhythmic effects of lidocaine. Am Heart J 1975; 89: 526–36Rosen, MR Hoffman, BF Wit, AL
Estes NAM III, Manolis AS, Greenblatt DJ, Garan H, Ruskin JN: Therapeutic serum lidocaine and metabolite concentrations in patients undergoing electrophysiologic study after discontinuation of intravenous lidocaine infusion. Am Heart J 1989; 117: 1060–4Estes, NAM Manolis, AS Greenblatt, DJ Garan, H Ruskin, JN
Talbot RG, Clark RA, Nimmo J, Neilson JMM, Julian DG, Prescott LF: Treatment of ventricular arrhythmias with mexiletine. Lancet 1973: II: 399–404Talbot, RG Clark, RA Nimmo, J Neilson, JMM Julian, DG Prescott, LF
Fig. 1. The effects of diazoxide alone or in combination with 5-hydroxydecanoic acid (5-HD) on flavoprotein fluorescence. Diazoxide (25 μm) induced a reversible increase of mitochondrial oxidation (n = 7). 5-HD (100 μm) significantly attenuated the oxidative effects of diazoxide. After washout of diazoxide, mitochondrial oxidation was restored to the baseline level. The redox signal was normalized to the baseline flavoprotein fluorescence obtained during exposure to 5 μm 2,4-dinitrophenol (DNP) at the end of the experiments.
Fig. 1. The effects of diazoxide alone or in combination with 5-hydroxydecanoic acid (5-HD) on flavoprotein fluorescence. Diazoxide (25 μm) induced a reversible increase of mitochondrial oxidation (n = 7). 5-HD (100 μm) significantly attenuated the oxidative effects of diazoxide. After washout of diazoxide, mitochondrial oxidation was restored to the baseline level. The redox signal was normalized to the baseline flavoprotein fluorescence obtained during exposure to 5 μm 2,4-dinitrophenol (DNP) at the end of the experiments.
Fig. 1. The effects of diazoxide alone or in combination with 5-hydroxydecanoic acid (5-HD) on flavoprotein fluorescence. Diazoxide (25 μm) induced a reversible increase of mitochondrial oxidation (n = 7). 5-HD (100 μm) significantly attenuated the oxidative effects of diazoxide. After washout of diazoxide, mitochondrial oxidation was restored to the baseline level. The redox signal was normalized to the baseline flavoprotein fluorescence obtained during exposure to 5 μm 2,4-dinitrophenol (DNP) at the end of the experiments.
×
Fig. 2. Concentration-dependent effects of lidocaine on diazoxide (25 μm)-induced flavoprotein oxidation. The redox signal was normalized to the baseline flavoprotein fluorescence obtained during exposure to 5 μm 2,4-dinitrophenol (DNP) at the end of the experiments. Each bar constitutes measurements from seven single ventricular myocytes. *P  < 0.05 versus  diazoxide alone.
Fig. 2. Concentration-dependent effects of lidocaine on diazoxide (25 μm)-induced flavoprotein oxidation. The redox signal was normalized to the baseline flavoprotein fluorescence obtained during exposure to 5 μm 2,4-dinitrophenol (DNP) at the end of the experiments. Each bar constitutes measurements from seven single ventricular myocytes. *P 
	< 0.05 versus 
	diazoxide alone.
Fig. 2. Concentration-dependent effects of lidocaine on diazoxide (25 μm)-induced flavoprotein oxidation. The redox signal was normalized to the baseline flavoprotein fluorescence obtained during exposure to 5 μm 2,4-dinitrophenol (DNP) at the end of the experiments. Each bar constitutes measurements from seven single ventricular myocytes. *P  < 0.05 versus  diazoxide alone.
×
Fig. 3. Concentration-dependent effects of mexiletine on diazoxide (25 μm)-induced flavoprotein oxidation. The redox signal was normalized to the baseline flavoprotein fluorescence obtained during exposure to 5 μm 2,4-dinitrophenol at the end of the experiments. Each bar constitutes measurements from 10 single ventricular myocytes. *P  < 0.05 versus  diazoxide alone.
Fig. 3. Concentration-dependent effects of mexiletine on diazoxide (25 μm)-induced flavoprotein oxidation. The redox signal was normalized to the baseline flavoprotein fluorescence obtained during exposure to 5 μm 2,4-dinitrophenol at the end of the experiments. Each bar constitutes measurements from 10 single ventricular myocytes. *P 
	< 0.05 versus 
	diazoxide alone.
Fig. 3. Concentration-dependent effects of mexiletine on diazoxide (25 μm)-induced flavoprotein oxidation. The redox signal was normalized to the baseline flavoprotein fluorescence obtained during exposure to 5 μm 2,4-dinitrophenol at the end of the experiments. Each bar constitutes measurements from 10 single ventricular myocytes. *P  < 0.05 versus  diazoxide alone.
×