Regulation of coronary myoplasmic Ca(2+)-myosin light chain phosphorylation pathway and vasomotor tone: hyperpolarizing versus depolarizing cardioplegia

BACKGROUND: This study was designed to compare the effects of hyperpolarizing versus depolarizing cardioplegic solutions on the coronary vasomotor regulation, specifically focusing on coronary myoplasmic Ca2+-myosin light chain (MLC) phosphorylation pathway and beta-adrenergic signal transduction. METHODS: With the use of an in vitro cardioplegic model, rat coronary microvessels loaded with fura-2 were subjected to simulated cold (20 degrees C) cardioplegia and reperfused with Krebs solution for 60 minutes at 37 degrees C. Cardioplegia consisted of either (1) Krebs solution alone (control), (2) Krebs plus adenosine triphosphate-sensitive potassium channel opener (100 micromol/L pinacidil [PCO-CP]), (3) hyperkalemic cardioplegia (K(+) = 25 mmol/L [K-CP]), or (4) K-CP plus magnesium (Mg(2+) = 25 mmol/L; [K/Mg-CP]). RESULTS: At the endpoint of the cardioplegic period, K-CP resulted in a significant increase both in [Ca(2+)](i) and in MLC phosphorylation compared with control (both P <.05). In contrast, PCO-CP did not make any significant difference in these indices compared with control. After reperfusion, the relaxation responses to isoproterenol and forskolin after K-CP were significantly reduced (both P <.05 vs control) but were preserved after PCO-CP. K/Mg-CP provided comparable effects to PCO-CP. CONCLUSIONS: These results suggest that neither an activation of the coronary myoplasmic Ca(2+)-MLC phosphorylation pathway nor beta-adrenergic desensitization seen after exposure to depolarizing cardioplegia occurs with exposure to hyperpolarizing cardioplegia and magnesium-supplemented depolarizing hyperkalemic cardioplegia.     

Calcium-induced ventricular contraction during cardioplegic arrest

Cardiac arrest induced by hyperkalemic perfusion is generally considered to represent a state of complete electromechanical arrest. However, high-energy phosphate concentrations and ventricular function decrease with increasing cardioplegic calcium concentrations, possibly because of elevated resting muscle tone produced by calcium influx. We examined isolated rat hearts containing an isovolumic intraventricular balloon for the presence of contractile activity during the administration at 10 degrees C of a cardioplegic solution containing potassium, 20 mEq/L. Significant left ventricular pressure was developed (35.6% +/- 4.3% of prearrest systolic pressure) during administration of a solution containing a calcium concentration of 1.0 mmol/L and far less (9.7% +/- 1.6% of prearrest systolic pressure) with a calcium-free cardioplegic solution. The muscle contraction diminished with repeated doses, was increased by increasing cardioplegic calcium content, and was inhibited by magnesium. Adenosine triphosphate and creatine phosphate concentrations were 9.0 +/- 1.4 and 7.0 +/- 0.9 nmol/mg dry weight immediately after infusion of 15 ml of a hypoxic cardioplegic solution containing calcium, versus 13.3 +/- 1.3 (p less than 0.02) and 31.9 +/- 3.5 nmol/mg dry weight (p less than 0.0001) after a hypoxic acalcemic solution was given. When repeated doses of a hypoxic cardioplegic solution containing calcium in a concentration of 1.0 mmol/L were given at 15 minute intervals at 10 degrees C, ischemic contracture (a sustained development of ventricular pressure, mean 51% +/- 4% of prearrest systolic pressure) resulted within 1 hour. Coronary vascular resistance was increased during the muscle contractions induced by calcium-containing solutions, markedly so during contracture. Calcium-related mechanical activity was also observed during hypothermic cardioplegic arrest in five of six isolated isovolumic canine hearts. We conclude that hearts remain potentially active mechanically during cold hyperkalemic arrest and undergo energetically wasteful contraction when stimulated with calcium-containing hyperkalemic cardioplegic solutions.     

Risk of low calcium and high magnesium in continuous warm hyperkalemic cardioplegia.

BACKGROUND: The recent introduction of operations on a warm heart has prompted clinical reports on the usefulness of continuous blood cardioplegia, but no in-depth basic evaluation of continuous cardioplegia has been done. The cardioprotective effects of magnesium (Mg) and calcium (Ca) in continuous warm hyperkalemic crystalloid cardioplegic solutions were investigated in an isolated rat heart model. METHODS: Isolated rat hearts were arrested for 180 minutes at 37 degrees C with a continuous warm hyperkalemic (20 mmol/L) modified Krebs-Henseleit bicarbonate buffer solution containing 1.2, 8.0, or 16.0 mmol/L of Mg and 0.1 to 2.5 mmol/L of Ca in different concentrations. Recovery of cardiac function and tissue damage were estimated. RESULTS: For each Mg concentration, the percentage recovery of aortic flow generated dose-response curves depending on Ca concentration. However, as Mg concentration increased, the recovery of aortic flow decreased in the groups with 0.5 mmol/L of Ca or less. CONCLUSIONS: In continuous warm cardioplegia the combination of low Ca and high Mg concentration caused severe cardiac injury, and normal Ca concentration avoids cardiac injury regardless of Mg concentrations.     

Aprikalim reduces the Na+-Ca2+ exchange outward current enhanced by hyperkalemia in rat ventricular myocytes

BACGROUND: Aprikalim, an adenosine triphosphate (ATP) sensitive K+ (K(ATP)) channel opener, attenuates the elevation of intracellular Ca2+ concentration ([Ca2+]i) and improves the contractile functions after hyperkalemic and hypothermic cardioplegia. There is evidence that cardioplegia increases the Na+-Ca2+ exchange activity without affecting Ca2+ influx through L-type Ca2+ channels or Ca2+ content in the sarcoplasmic reticulum, the intracellular Ca2+ store. METHODS: We measured the Na+-Ca2+ exchange outward current with the patch-clamp technique in single rat ventricular myocytes exposed to hyperkalemia and hypothermia in the presence of aprikalim. The intracellular calcium concentration ([Ca2+]i) during cardioplegia, and the contractile function and [Ca2+]i transients induced by electrical stimulation or caffeine during rewarming and reperfusion in single ventricular myocytes were also determined. Contraction and [Ca2+]i were determined with video tracking and spectrofluorometry, respectively. RESULTS: Aprikalim, 100 micromol/L, the effect of which was blocked by glibamclamide, a K(ATP) inhibitor, significantly attenuated the hyperkalemia-elevated Na+-Ca2+ exchange current by 26% and 11% at 22 degrees C and 4 degrees C, respectively. Aprikalim also attenuated significantly the [Ca2+]i elevated during cardioplegia. Furthermore aprikalim significantly attenuated the reduction in amplitude and prolongation in duration of contraction of myocytes after cardioplegia. The effects of aprikalim mimicked those of nickle (Ni2+), a Na+-Ca2+ exchange blocker. The electrically or caffeine-induced [Ca2+]i transients were unaltered by cardioplegia or aprikalim. CONCLUSIONS: Aprikalim attenuates the Na+-Ca2+ exchange outward current elevated by hyperkalemia, which may attenuate the [Ca2+]i elevation during hyperkalemia and improve the contractile function after cardioplegia in the ventricular myocyte. The study provides further support that addition of a K(ATP) channel opener to the cardioplegic solution may produce beneficial effects in open heart surgery.     

Long-term preservation of explanted hearts perfused with L-aspartate-enriched cardioplegic solution. Improved function, metabolism, and ultrastructure.

The effects of supplementing oxygenated St. Thomas' Hospital cardioplegic solution No. 2 with L-aspartate and/or D-glucose for the long-term preservation of excised rat hearts were determined with isolated working heart preparations. Left ventricular function was assessed at 37 degrees C with a crystalloid perfusate, before cardioplegic arrest and after 20 hours of low-flow perfusion (1.5 ml/min) with continuing arrest at 4 degrees C, and after this period, again at 37 degrees C with a crystalloid perfusate. Four groups (n = 8/group) of hearts were studied with four cardioplegic solutions: St. Thomas' Hospital solution alone, St. Thomas' Hospital solution with aspartate 20 mmol/L, St. Thomas' Hospital solution with glucose 20 mmol/L, and St. Thomas' Hospital solution plus both aspartate and glucose (20 mmol/L each). The addition of glucose to St. Thomas' Hospital solution made no significant difference in the recovery of aortic flow rates (17.7% +/- 8.6% and 21.6% +/- 7.8% of prearrest values), but when aspartate or aspartate and glucose were present, hearts showed significant improvements (89.8% +/- 5.2% and 85.0% +/- 6.2%, respectively). These improvements were associated with a reduction in the decline of myocardial high-energy phosphates during reperfusion, a reduction in cellular uptake of Na+ and Ca++, and a reduction in ultrastructural damage. These results indicate that low-flow perfusion with St. Thomas' Hospital solution plus aspartate can considerably extend the duration of safe storage of explanted hearts.     

Nongenomic effects of aldosterone on Ca2+ in M-1 cortical collecting duct cells

BACKGROUND: Aldosterone at physiological levels induces rapid (<5 min) increases in intracellular protein kinase C (PKC) activity and a rise in calcium and pH in mineralocorticoid hormone target epithelia, such as distal colon and sweat gland. The end targets of these rapid responses in epithelia are Na+/H+ exchange and K+ channels. METHODS: The mouse cortical collecting duct (CCD) M-1 cell line was grown to confluency and loaded with Fura-2 for spectrofluorescence measurements of intracellular free calcium at 37 degrees C bathed in Krebs solution. RESULTS: Aldosterone (1 nmol/L) produced a rapid, transient peak increase in [Ca2+]i in M-1 cells. This effect was abolished upon removal of extracellular Ca2+, but was unaffected by pretreatment with spironolactone (10 micromol/L) or actinomycin D (10 micromol/L). However, pretreatment with the specific PKC inhibitor chelerythrine chloride (1 micromol/L) prevented the aldosterone-induced rise in [Ca2+]i. Dexamethasone, at a concentration 10,000-fold higher than aldosterone (10 micromol/L), also produced a transient increase in [Ca2+]i, but this response was significantly smaller than that of aldosterone. In contrast, hydrocortisone had no effect on [Ca2+]i at either nmol/L or micromol/L concentrations. Both of the sex steroids, 17beta-estradiol (10 nmol/L) and progesterone (10 nmol/L), induced protein kinase C-dependent increases in [Ca2+]i. CONCLUSIONS: Aldosterone and sex steroid hormones activate intracellular calcium signaling in CCD cells via a nongenomic PKC-dependent pathway, which may have important implications for renal transport.     

Crystalloid cardioplegia and hypothermia do not impair endothelium-dependent relaxation or damage vascular smooth muscle of epicardial coronary arteries.

Canine hearts were arrested with crystalloid cardioplegic solution (45 minutes at 7 degrees C) to determine whether either cardioplegia or hypothermia impairs the production of endothelium-derived relaxing factor or damages the vascular smooth muscle of epicardial coronary arteries. In addition, isolated coronary artery segments were exposed to either cold (7 degrees C) or warm (37 degrees C) crystalloid cardioplegic solution and physiologic salt solution in vitro for 45 minutes. After cardiac arrest or incubation with the solutions, segments of epicardial coronary artery were prepared and studied in organ chambers. Cardioplegic arrest of the heart or exposure to cardioplegic solution in vitro (7 degrees or 37 degrees C) did not alter endothelium-dependent relaxation of epicardial coronary artery segments in response to adenosine diphosphate or acetylcholine (10(-9) to 10(-4) mol/L). Cardioplegic arrest did not alter G protein-mediated, endothelium-dependent relaxation in response to sodium fluoride. In addition, smooth muscle contraction in response to potassium ions (voltage-dependent) or prostaglandin F2 alpha (receptor-dependent) and relaxation in response to isoproterenol (cyclic adenosine monophosphate-mediated) or sodium nitroprusside (cyclic guanosine monophosphate-mediated) was unaltered after exposure to cardioplegic solution or hypothermia. These experiments demonstrate that hyperkalemic crystalloid cardioplegia does not irreversibly alter function of epicardial coronary arteries. We hypothesize that coronary artery endothelial cell dysfunction identified in previous studies of cardioplegia may have been due to the effects of barotrauma or shear stress on the vasculature and not the effect of cardioplegia per se.     

Methods of cardiac preservation alter the function of the endothelium in porcine coronary arteries

This study was undertaken to determine whether clinical methods for preservation and storage of hearts explanted for transplantation affect the responsiveness of coronary arteries to vasoactive agents. Porcine hearts were perfused with crystalloid or blood cardioplegic solution. Rings of coronary arteries were suspended in organ chambers for measurement of isometric force (1) immediately after perfusion and (2) after 5 hours' storage of the hearts at 4 degrees C in the same cardioplegic solution (n = 6 in each group). The maximal contraction of the smooth muscle to potassium chloride, 40 mmol/L, was reduced significantly after perfusion with crystalloid cardioplegic solution (10.8 +/- 1.2 gm) compared with blood cardioplegic solution (17.3 +/- 0.8 gm) and nonperfused coronary arteries (control group 16.9 +/- 1.8 gm). The sensitivity of the arteries with endothelium to the contractile effects of prostaglandin F2 alpha increased after perfusion with crystalloid cardioplegic solution (ED50, [-log mol/L] 5.8 +/- 0.04) compared with blood cardioplegic solution (5.3 +/- 0.02) and the control group (5.7 +/- 0.03). In addition, relaxations to the calcium ionophore A23187, bradykinin, and the alpha 2-agonist BHT-920, which depend on the presence of endothelial cells, were significantly reduced after perfusion with crystalloid compared with blood cardioplegic solution or the control group. The responsiveness of the endothelium and smooth muscle after 5 hours' cold storage was unaltered in the blood cardioplegia group, whereas storage resulted in functional recovery in the crystalloid cardioplegia group, with the result that all groups were comparable. These data suggest an immediate and reversible change in vascular function with crystalloid cardioplegia, which was not apparent with blood cardioplegia.     

Effects of oxygenated cardioplegic solutions on myocardial aerobic metabolism.

Oxygenated cardioplegic solutions can deliver sufficient oxygen to support aerobic metabolism of heart tissue during cardiac arrest, but little is known about oxygen use after cardioplegic solution infusion. Exhaustion of myocardial oxygen stores after infusion of oxygenated crystalloid cardioplegic solution or Krebs-Henseleit buffer was measured in rat hearts. Since nicotinamide adenine dinucleotide accumulates when mitochondria become anaerobic, the epicardium was monitored during perfusion and ischemia. As ischemia progressed, nicotinamide adenine dinucleotide fluorescence increased, indicating exhaustion of oxygen. After buffer perfusion, at 37 degrees C, 50% of peak fluorescence was seen at 13 +/- 1 seconds and 90% at 37 +/- 3 seconds. Oxygenated cardioplegic solution increased these intervals to 57 +/- 6 and 114 +/- 9 seconds, respectively. Oxygenated cardioplegic solution at 10 degrees C increased the time to 50% fluorescence to 238 +/- 12 seconds and to 90% to 320 +/- 14 seconds. Differences between buffer and cardioplegic solution were less at 10 degrees C. Aerobic metabolism was completely abolished 6 minutes after infusion of 10 degrees C oxygenated cardioplegic solution. Maintenance of continuous aerobic metabolism during surgical cardiac arrest would require frequent administration of oxygenated crystalloid cardioplegic solution.     

Influence of oxygenation on endothelial modulation of coronary vasomotor function during hyperkalemic cardioplegia.

BACKGROUND: The purpose of this study was to determine the influence of oxygenation of a hyperkalemic cardioplegic solution (K-CP) on endothelial modulation of vasomotor tone and to correlate these changes with the intracellular calcium concentration ([Ca++]i) in microvascular smooth muscle. METHODS: Rat coronary arterioles were studied in a pressurized, no-flow normothermic state. Simultaneous monitoring of luminal diameter and [Ca++]i (fura-2) was performed with use of microscopic image analysis. Vessels were subjected to 60 minutes of oxygenated or hypoxic K-CP (K+ = 25.0 mmol/L) and were then reperfused with oxygenated Krebs-physiologic saline solution for 60 minutes. RESULTS: In oxygenated K-CP, the K-CP-induced contraction and [Ca++]i accumulation were significantly increased in endothelium-denuded (ED) vessels compared with endothelium-intact vessels. The effect of ED in oxygenated K-CP was mimicked by administration of the nitric oxide synthase inhibitor NG-monomethyl-L-arginine. Conversely, in hypoxic K-CP the contraction was significantly attenuated in ED vessels compared with endothelium-intact vessels, although there was no significant difference in [Ca++]i. Indomethacin did not affect the endothelium-dependent contraction during hypoxic K-CP. CONCLUSIONS: Endothelium-derived nitric oxide modulates the vascular tone during K-CP by regulating the vascular smooth muscle [Ca++]i, whereas endothelium-derived contracting factor(s), which is not predominantly a product of cyclo-oxygenase, may play a prominent role under hypoxic K-CP by increasing vascular smooth muscle Ca++ sensitivity.     

Magnesium ion is beneficial in hypothermic crystalloid cardioplegia

The role of magnesium ion and its relation to the calcium concentration of cardioplegic solutions was reexamined in this study. Isolated rat hearts were used with an oxygenated modified Krebs-Henseleit bicarbonate buffer as perfusion medium. The hearts were arrested for 20 minutes at 37 degrees C or 90 minutes at 24 degrees C. Treatment groups received one dose of nine possible cardioplegic solutions containing magnesium (0, 1.2, or 15 mmol/L) and calcium (0.05, 1.5, or 4.5 mmol/L). Ninety-six percent of the 75 magnesium-treated hearts recovered, regardless of the calcium concentration, in contrast to a 52% recovery rate in the 69 hearts that did not receive magnesium. The addition of 15 mmol/L Mg2+ to a cardioplegic solution containing no magnesium but 0.05 mmol/L Ca2+ significantly increased (p less than 0.01) the percent recovery of the following parameters of cardiac function: systolic pressure, 74% to 93% (37 degrees C), 64% to 98% (24 degrees C); cardiac output, 76% to 101% (37 degrees C), 71% to 102% (24 degrees C); stroke work, 64% to 104% (37 degrees C), 52% to 99% (24 degrees C); and adenosine triphosphate level, 75% to 83% (37 degrees C), 58% to 90% (24 degrees C). There were significant reductions (p less than 0.03) in percent recovery (37 degrees C and 24 degrees C) of cardiac output, stroke work, and adenosine triphosphate level in the groups that contained 0 or 15 mmol/L Mg2+ as the calcium concentration was increased from 0.05 to 4.5 mmol/L.(ABSTRACT TRUNCATED AT 250 WORDS)     

Adenosine and lidocaine: a new concept in nondepolarizing surgical myocardial arrest, protection, and preservation

OBJECTIVE: Depolarizing potassium cardioplegia has been increasingly linked to left ventricular dysfunction, arrhythmia, and microvascular damage. We tested a new polarizing normokalemic cardioplegic solution employing adenosine and lidocaine as the arresting, protecting, and preserving cardioprotective combination. Adenosine hyperpolarizes the myocyte by A1 receptor activation, and lidocaine blocks the sodium fast channels. METHODS: Isolated perfused rat hearts were switched from the working mode to the Langendorff (nonworking) mode and arrested for 30 minutes, 2 hours, or 4 hours with 200 micromol/L adenosine and 500 micromol/L lidocaine in Krebs-Henseleit buffer (10 mmol/L glucose, pH 7.7, at 37 degrees C) or modified St Thomas' Hospital solution no. 2, both delivered at 70 mm Hg and 37 degrees C (arrest temperature 22 degrees C to 35 degrees C). RESULTS: Adenosine and lidocaine hearts achieved faster mechanical arrest in (25 +/- 2 seconds, n = 23) compared with St Thomas' Hospital solution hearts (70 +/- 5 seconds, n = 24; P=.001). After 30 minutes of arrest, both groups developed comparable aortic flow at approximately 5 minutes of reperfusion. After 2 and 4 hours of arrest (cardioplegic solution delivered every 20 minutes for 2 minutes at 37 degrees C), only 50% (4 of 8) and 14% (1 of 7) of St Thomas' Hospital solution hearts recovered aortic flow, respectively. All adenosine and lidocaine hearts arrested for 2 hours (n = 7) and 4 hours (n = 9) recovered 70% to 80% of their prearrest aortic flows. Similarly, heart rate, systolic pressures, and rate-pressure products recovered to 85% to 100% and coronary flows recovered to 70% to 80% of prearrest values. Coronary vascular resistance during delivery of cardioplegic solution was significantly lower (P <.05) after 2 and 4 hours in hearts arrested with adenosine and lidocaine cardioplegic solution compared with hearts arrested with St Thomas' Hospital solution. CONCLUSIONS: We conclude that adenosine and lidocaine polarizing cardioplegic solution confers superior cardiac protection during arrest and recovery compared with hyperkalemic depolarizing St Thomas' Hospital cardioplegic solution.     

Oxygenation of cardioplegic solutions. Potential for the calcium paradox

Oxygenation of crystalloid cardioplegic solutions is beneficial, yet bicarbonate-containing solutions equilibrated with 100% oxygen become highly alkaline as carbon dioxide is released. In the isolated perfused rat heart fitted with an intraventricular balloon, we recently observed a sustained contraction related to infusion of cardioplegic solution. In the same model, to record these contractions, we studied myocardial preservation by multidose bicarbonate-containing cardioplegic solutions in which first the calcium content and then the pH was varied. An acalcemic cardioplegic solution (Group 1) and the same solution with calcium provided by adding calcium chloride (Group 2) or blood (Group 3) were equilibrated with 100% oxygen. Ionized calcium concentrations were 0, 0.10 +/- 0.06, and 0.11 +/- 0.07 mmol/L and pH values were 8.74 +/- 0.07, 8.54 +/- 0.08, and 8.40 +/- 0.07, all highly alkaline. Hearts were arrested for 2 hours at 8 degrees +/- 2.5 degrees C and reperfused for 1 hour at 37 degrees C. At end-arrest, myocardial adenosine triphosphate was depleted in all three groups, significantly in Groups 2 and 3. In Group 1 the calcium paradox developed upon reperfusion, with contracture (left ventricular end-diastolic pressure = 60 +/- 7 mm Hg), creatine kinase release up to 620 +/- 134 U/L, a profound further decrease in adenosine triphosphate to 1.9 +/- 1.7 nmol/mg dry weight, and either greatly impaired or no functional recovery (17% +/- 10% of prearrest developed pressure). Three hearts in this group released creatine kinase during arrest and did not resume beating during reperfusion. In Groups 2 and 3, the calcium paradox did not occur; functional recovery was 61% +/- 4% and 71% +/- 9% at 5 minutes of reperfusion. In two additional groups (4 and 5), the pH of the acalcemic cardioplegic solution was decreased by equilibration with 2% and 5% carbon dioxide in oxygen to 7.53 +/- 0.03 and 7.11 +/- 0.02. Contractions during arrest were smaller than in Groups 1, 2, and 3; adenosine triphosphate was maintained during arrest; functional recovery was 101% +/- 3% and 96% +/- 4% at 5 minutes of reperfusion. We conclude that acalcemic solutions with carbon dioxide are superior to highly alkaline calcium-containing solutions. If oxygenation of cardioplegic solutions, of proved value, causes severe alkalinity, then calcium paradox may result even with hypothermia. This hazard is prevented by adding calcium or blood to the solution or carbon dioxide to the oxygen used for equilibration.     

Low-temperature Modification of the Inhibitory Effects of Volatile Anesthetics on Airway Smooth Muscle Contraction in Dogs

Background: Because exposure to low temperature can modify the effect of volatile anesthetics on airway smooth muscle contraction, this study was conducted to investigate low-temperature modifications of the inhibitory effects of isoflurane and sevoflurane on canine tracheal smooth muscle tone by simultaneously measuring the muscle tension and intracellular concentration of Ca2+ ([Ca2+]i) and by measuring voltage-dependent Ca2+ channel activity.

Methods: [Ca2+]i was monitored by the 500-nm light emission ratio of preloaded fura-2, a Ca2+ indicator. Isometric tension was measured simultaneously. Whole cell patch clamp recording techniques were used to observe voltage-dependent Ca2+ channel activity in dispersed muscle cells. Isoflurane (0-3.0%) or sevoflurane (0-3%) was introduced to a bath solution at various temperatures (37, 34, or 31[degrees]C).

Results: Low temperature (34 or 31[degrees]C) reduced high-K+-induced (72.7 mm) muscle contraction and increased [Ca2+]i, but it enhanced carbachol-induced (1 [mu]m) muscle contraction with a decrease in [Ca2+]i. The volatile anesthetics tested showed significant inhibition of both high-K+-induced and carbachol-induced airway smooth muscle contraction, with a concomitant decrease in [Ca2+]i. The inhibition of the carbachol-induced muscle contraction by volatile anesthetics was abolished partially by exposure to low temperature. Volatile anesthetics and low-temperature exposure significantly inhibited voltage-dependent Ca2+ channel activity of the smooth muscle.     

Optimal myocardial preservation with an acalcemic crystalloid cardioplegic solution

The effect of the calcium and oxygen contents of a hyperkalemic glucose-containing cardioplegic solution on myocardial preservation was examined in the isolated working rat heart. The cardioplegic solution was delivered at 4 degrees C every 15 minutes during 2 hours of arrest, maintaining a myocardial temperature of 8 degrees +/- 2 degrees C. Hearts were reperfused in the Langendorff mode for 15 minutes and then resumed the working mode for a further 30 minutes. Groups of hearts were given the oxygenated cardioplegic solution containing an ionized calcium concentration of 0, 0.25, 0.75, or 1.25 mmol/L or the same solution nitrogenated to reduce the oxygen content and containing 0 or 0.75 mmol ionized calcium per liter. The myocardial adenosine triphosphate concentrations at the end of arrest in these six groups of hearts were 15.6 +/- 1.2, 9.5 +/- 0.5, 8.2 +/- 1.1, 4.9 +/- 1.8, 10.1 +/- 2.0, and 1.6 +/- 0.4 nmol/mg dry weight, respectively. At 5 minutes of working reperfusion, the percentages of prearrest aortic flow were 80 +/- 2, 62 +/- 4, 33 +/- 6, 37 +/- 5, 48 +/- 7 and 46 +/- 8, respectively. The differences among the groups in adenosine triphosphate concentrations and in functional recovery diminished during reperfusion. In hearts given the hypoxic calcium-containing solution, there was a marked increase in coronary vascular resistance during the administration of successive doses of cardioplegic solution, which was rapidly reversible upon reperfusion. These data indicate that hearts given the acalcemic oxygenated solution had better adenosine triphosphate preservation during arrest and better functional recovery than hearts in any other group. Addition of calcium to the oxygenated cardioplegic solution decreased adenosine triphosphate preservation and functional recovery. Oxygenation of the acalcemic solution increased adenosine triphosphate preservation and functional recovery. The lowest adenosine triphosphate levels at end arrest were observed in hearts given the hypoxic calcium-containing solution. In the setting of hypothermia and multidose administration, the addition of calcium to a cardioplegic solution resulted in increased energy depletion during arrest and depressed recovery.     

Ryanodine receptor and capacitative Ca2+ entry in fresh preglomerular vascular smooth muscle cells

BACKGROUND: A multiplicity of hormonal, neural, and paracrine factors regulates preglomerular arterial tone by stimulating calcium entry or mobilization. We have previously provided evidence for capacitative (store-operated) Ca2+ entry in fresh renal vascular smooth muscle cells (VSMCs). Ryanodine-sensitive receptors (RyRs) have recently been identified in a variety of nonrenal vascular beds. METHODS: We isolated fresh rat preglomerular VSMCs with a magnetized microsphere/sieving technique; cytosolic Ca2+ ([Ca2+]i) was measured with fura-2 ratiometric fluorescence. RESULTS: Ryanodine (3 micromol/L) increased [Ca2+]i from 79 to 138 nmol/L (P = 0.01). Nifedipine (Nif), given before or after ryanodine, was without effect. The addition of calcium (1 mmol/L) to VSMCs in calcium-free buffer did not alter resting [Ca2+]i. In Ca-free buffer containing Nif, [Ca2+]i rose from 61 to 88 nmol/L after the addition of the Ca2+-ATPase inhibitor cyclopiazonic acid and to 159 nmol/L after the addition of Ca2+ (1 mmol/L). Mn2+ quenched the Ca/fura signal, confirming divalent cation entry. In Ca-free buffer with Nif, [Ca2+]i increased from 80 to 94 nmol/L with the addition of ryanodine and further to 166 nmol/L after the addition of Ca2+ (1 mmol/L). Mn2+ quenching was again shown. Thus, emptying of the sarcoplasmic reticulum (SR) with ryanodine stimulated capacitative Ca2+ entry. CONCLUSION: Preglomerular VSMCs have functional RyR, and a capacitative (store-operated) entry mechanism is activated by the depletion of SR Ca2+ with ryanodine, as is the case with inhibitors of SR Ca2+-ATPase.     

Low-temperature modification of the inhibitory effects of volatile anesthetics on airway smooth muscle contraction in dogs

BACKGROUND: Because exposure to low temperature can modify the effect of volatile anesthetics on airway smooth muscle contraction, this study was conducted to investigate low-temperature modifications of the inhibitory effects of isoflurane and sevoflurane on canine tracheal smooth muscle tone by simultaneously measuring the muscle tension and intracellular concentration of Ca2+ ([Ca2+]i) and by measuring voltage-dependent Ca2+ channel activity. METHODS: [Ca2+]i was monitored by the 500-nm light emission ratio of preloaded fura-2, a Ca2+ indicator. Isometric tension was measured simultaneously. Whole cell patch clamp recording techniques were used to observe voltage-dependent Ca2+ channel activity in dispersed muscle cells. Isoflurane (0-3.0%) or sevoflurane (0-3%) was introduced to a bath solution at various temperatures (37, 34, or 31 degrees C). RESULTS: Low temperature (34 or 31 degrees C) reduced high-K+-induced (72.7 mm) muscle contraction and increased [Ca2+]i, but it enhanced carbachol-induced (1 microm) muscle contraction with a decrease in [Ca2+]i. The volatile anesthetics tested showed significant inhibition of both high-K+-induced and carbachol-induced airway smooth muscle contraction, with a concomitant decrease in [Ca2+]i. The inhibition of the carbachol-induced muscle contraction by volatile anesthetics was abolished partially by exposure to low temperature. Volatile anesthetics and low-temperature exposure significantly inhibited voltage-dependent Ca2+ channel activity of the smooth muscle. CONCLUSIONS: Exposure of airway smooth muscle to low temperature leads to an increase in agonist-induced muscle contractility, with a decrease in [Ca2+]i. The inhibition of voltage-dependent Ca2+ channel activity by exposure to low temperature and by volatile anesthetics cam be attributed, at least in part, to the decrease in [Ca2+]i.     

Oxygenation of cardioplegic solutions: a note of caution

The merits of oxygenated crystalloid cardioplegic solutions have been well established in experimental animals. The positive effects of oxygenation of Plasmalyte B (Sabax Ltd) and St. Thomas Hospital solution (Plegisol) were achieved by gassing with 95% O2/5% CO2 and 100% O2, respectively. In view of the marked pH differences induced by these gas mixtures, we evaluated the effect of mode of oxygenation on myocardial recovery during reperfusion after hypothermic cardioplegic arrest. Oxygenation with 100% O2 of Plasmalyte B containing high K+ levels caused marked deterioration in myocardial recovery, whereas the mode of oxygenation did not affect recovery after arrest with St. Thomas Hospital solution. Because the major differences between these solutions reside in their respective K+, Mg2+, and HCO3- contents, the effects of variations in the levels of these ions were investigated. The results showed that oxygenation with 100% O2 was deleterious only in the presence of high K+ (29 mmol/L), low Mg2+ (3 mmol/L), and high NaHCO3 (28 mmol/L) levels. The marked decline in mechanical recovery during reperfusion was associated with significant changes in myocardial adenosine triphosphate and intracellular Ca2+ levels. Although an explanation for these findings is not readily available, it is suggested that complex ionic interactions and possibly oxygen free radical generation may lead to intracellular Ca2+ overload, depression in mitochondrial adenosine triphosphate generation, and, hence, deterioration in mechanical recovery.     

Agonist-induced calcium regulation in freshly isolated renal microvascular smooth muscle cells.

The studies presented here were performed to determine the effect of agonist stimulation on the cytosolic free Ca2+ concentration ([Ca2+]i) in single smooth muscle cells, freshly isolated from afferent arterioles and interlobular arteries averaging between 10 to 40 microns in diameter. Microvessels were obtained from male Sprague-Dawley rats using an iron oxide collection technique followed by collagenase digestion. Freshly isolated microvascular smooth muscle cells (MVSMC) were loaded with fura 2 and studied using fluorescence photometry techniques. The resting [Ca2+]i averaged 67 +/- 3 nM (N = 82 cells). Increasing the extracellular K+ concentration significantly increased [Ca2+]i dose-dependently (P < 0.05). Involvement of extracellular Ca2+ in the response to KCl-induced depolarization was also evaluated. Resting [Ca2+]i increased approximately 132% from 40 +/- 5 nM to 93 +/- 26 nM in response to 90 mM extracellular KCl. This change was abolished in nominally Ca(2+)-free conditions and markedly attenuated by diltiazem. Inhibition of K+ channels with charybdotoxin or tetraethylammonium chloride produced a modest transient increase in [Ca2+]i during the response to 30 mM K+ and had no detectable effect on responses to 90 mM K+. Studies were also performed to establish whether freshly isolated renal MVSMC exhibit appropriate responses to receptor-dependent physiological agonists. Angiotensin II (100 nM) increased cell Ca2+ from 97 +/- 10 nM to 265 +/- 47 nM (N = 12 cells). Similarly, 100 microM ATP increased MVSMC [Ca2+]i from a control level of 71 +/- 14 nM to 251 +/- 47 nM (N = 11 cells). Norepinephrine administration caused [Ca2+]i to increase from 63 +/- 4 nM to 212 +/- 47 nM (N = six cells), and vasopressin increased [Ca2+]i from 86 +/- 10 nM to 352 +/- 79 nM (N = five cells). These data demonstrate that receptor-dependent and -independent vasoconstrictor agonists increase [Ca2+]i in MVSMC, freshly isolated from rat preglomerular vessels. Furthermore, the ability to measure [Ca2+]i in responses to physiological stimuli in these single cells permits investigation of signal transduction mechanisms involved in regulating renal microvascular resistance.     

The role of cardioplegic solution buffering in myocardial protection. A biochemical and histopathological assessment

The advantages of buffering cardioplegic solutions to improve adenosine triphosphate preservation and postarrest hemodynamic function have been previously promoted. We evaluated the benefit of histidine buffering (195 mmol/L) in a low sodium (27 mEq/L) cardioplegic solution (Roe's) in a canine model of multidose cardioplegic arrest. Four solutions, two unbuffered (K+ = 10 mEq/L and K+ = 30 mEq/L) and two buffered (K+ = 10 mEq/L and K+ = 30 mEq/L), were tested in four groups of dogs for a 4 1/2 hour arrest period followed by 1 hour of reperfusion. Use of the unbuffered solution resulted in a drop in myocardial adenosine triphosphate from 29 +/- 1 mmol/kg (mean +/- standard error of the mean) (K+ = 30 mEq/L) and 28 +/- 2 mmol/kg (K+ = 10 mEq/L) to 8 +/- 2 mmol/kg and 7 +/- 2 mmol/kg, respectively, during the arrest period. In both buffered groups, adenosine triphosphate remained at preischemic levels during the entire arrest period. Myocardial glycogen followed the same pattern as adenosine triphosphate in the buffered groups. Lactate production was markedly elevated in all groups during ischemia. Postarrest hemodynamic function, as assessed by intraventricular isovolumic developed pressure measurements, was better (p less than 0.05) in the buffered low-potassium group than in the other three groups. The extent of myocardial necrosis, measured by triphenyl tetrazolium staining and confirmed by electron microscopy, was minimal (2% +/- 1% of biventricular mass) in the buffered low-potassium group, significantly greater (7% +/- 2% and 10% +/- 2%) in the unbuffered high-potassium and low-potassium groups, respectively, and highest (35% +/- 9%) in the buffered high-potassium group. These findings indicate that significant buffering capacity (similar to that of blood) in a crystalloid cardioplegic solution can be effective in preserving myocardial adenosine triphosphate stores, improving postarrest contractile function, and minimizing myocardial necrosis, provided the combination of high extracellular potassium and high pH levels is avoided.