Molecular variation, evolution and geographical distribution of louping ill virus

The effect of lidocaine on the palmitoyl-L-carnitine (PALCAR)-induced mechanical and metabolic derangements was studied in Langendorff rat hearts, perfused aerobically at a constant flow rate and paced electrically. PALCAR (5 mumol/l) increased the left ventricular end-diastolic pressure, decreased the left ventricular developed pressure (i.e., mechanical dysfunction), and decreased the tissue levels of adenosine triphosphate and creatine phosphate (i.e., metabolic change). These mechanical and metabolic alterations induced by PALCAR were concentration-dependently attenuated by lidocaine (20, 50 or 100 mumol/l). Nevertheless, lidocaine (20, 50 or 100 mumol/l) did not affect the mechanical function and energy metabolism of the normal (PALCAR-untreated) heart. These results indicate that lidocaine has a cardioprotective action against the PALCAR-induced mechanical and metabolic derangements.     

Protective effect of l-cis-diltiazem on hypercontracture of rat myocytes induced by veratridine

The protective effect of l-cis-diltiazem, the stereoisomer of d-cis-diltiazem, was studied against the veratridine-induced hypercontracture of rat myocytes. Veratridine increased both [Na+]i and [Ca2+]i, but did not cause hypercontracture in the absence of extracellular Ca2+. Both l-cis-diltiazem (0.1-10 microM) and d-cis-diltiazem (10-30 microM) inhibited the hypercontracture and the increase in [Ca2+]i in a concentration-dependent manner. However, l-cis-diltiazem did not exert a negative inotropic effect in K+ (20 mM)-depolarized rat papillary muscles even at a dose of 10 microM. As seen in the case of tetrodotoxin, l-cis-diltiazem and d-cis-diltiazem also suppressed the increase in [Na+]i. The results show that l-cis-diltiazem prevents the veratridine-induced hypercontracture of myocytes by suppression of the [Ca2+]i increase. The attenuation of the [Ca2+]i increase by l-cis-diltiazem was not dependent on inhibition of Ca2+ channels, but was partly due to inhibition of excessive Na+ entry via veratridine-modified Na+ channels.     

Adenosine A1 receptor stimulation antagonizes the negative inotropic effects of the PKC activator dioctanoylglycerol

It has been suggested that adenosine cardioprotection occurs via adenosine A1 receptor-mediated activation of protein kinase C (PKC). However, adenosine has well-known vasodilatory effects in the myocardium, whereas PKC is a vasoconstrictor. This study examined whether adenosine A1 receptor activation alters the effects of the PKC activator. 1,2-dioctanoyl-s,n-glycerol (DOG) in isolated perfused rat hearts (left-ventricular developed pressure) and rat ventricular myocytes ([Ca2+]i and cell shortening). Exposure to DOG decreased left-ventricular developed pressure by 30%, an effect that was completely reversible. Pretreatment of isolated hearts with either the PKC inhibitor chelerythrine or the adenosine A1 agonist 2-chloro-N6-cyclo-cyclo-isolated pentlyadenosine (CCPA) attenuated the negative inotropic effects of DOG. In the isolated myocytes, DOG decreased [Ca2+]i and cell shortening by 25 and 28%, respectively, effects that were attenuated by both chelerythrine and CCPA. The CCPA attenuation of the DOG-induced decrease in [Ca2+]i and cell shortening was blocked by pretreating the myocytes with the adenosine A1 antagonist, 8-cyclopentyl-1,3-dipropylxanthine (DPCPX). These results indicate that in rat ventricular myocardium, adenosine A1 receptor activation attenuates the apparent PKC-dependent negative inotropic effects of DOG via preservation of [Ca2+]i levels.     

Extra-anatomic bypass for aorto-iliac occlusive disease in octogenarians

Effect of verapamil post-treatment (0.2 mg/kg bolus, followed by 0.01 mg/kg/min infusion) on the functional and metabolic changes of the heart after a brief regional ischemia (20 min) followed by 1 hr of reperfusion was studied in open-chest pentobarbitone anaesthetized dogs. In control dogs 1 hr of reperfusion failed to cause any improvement of depressed myocardial contractility (LVdP/dtmax and LVEDP) caused by 20 min of ischemia, which confirmed the earlier reported phenomenon of 'Stunned Myocardium'. Myocardial ischemia caused a significant loss of high-energy phosphate (HEP) content of the affected myocardium (ATP decreased by 60% and CP decreased by 75% of non-ischemic level). Following 1 hr of reperfusion, myocardial ATP was not replenished, though creatine phosphate became near normal. When verapamil was administered just before reperfusion, it showed a profound beneficial effect on the incidence of fatal reperfusion arrhythmias. At the end of 1 hr of reperfusion in this group, the recovery of the myocardial contractility was incomplete, but a significant replenishment of the myocardial HEP content was observed. Thus verapamil post-treatment can prevent reperfusion-induced myocardial injury but functional recovery may be delayed due to the drug's inherent direct myocardial depressant effect.     

Developmental features of human striatal tissue transplanted in a rat model of Huntington''s disease

The actions of the novel calcium (Ca2+) channel antagonist mibefradil (Ro 40-5967), a selective T-type channel blocker in myocardium, were investigated in embryonic rat spinal motoneurones maintained in culture. Whole-cell currents were recorded with the patch-clamp technique. Motoneurones displayed transient, low-voltage-activated (LVA) and, more sustained, high-voltage-activated (HVA) Ca2+ currents. The LVA currents were small and preferentially blocked by amiloride and low doses of nickel. Most of the HVA Ca2+ current flowed through N-type Ca2+ channels, while L-, and P/Q-type channels represented a smaller fraction. Mibefradil caused a rapid and reversible dose-dependent block of inward Ca2+ channel currents. Inhibition was nearly complete at 10 microM, suggesting mibefradil blockade of all subclasses of Ca2+ channels. The IC50 was approximately 1.4 microM on currents measured at 0 mV, from a holding potential of -90 mV. Inhibition of LVA Ca2+ current occurred over the same contraction range. Slow tail currents induced by the dihydropyridine agonist Bay K 8644 were also blocked by mibefradil, although with a slightly lower potency (IC50 = 3.4 microM). These broad inhibitory effects of mibefradil on Ca2+ influx were also supported by the strong inhibition of depolarization-induced intracellular calcium transients, measured from Indo-1 loaded motoneurones imaged with confocal microscopy. We conclude that mibefradil has potent blocking effects on Ca2+ channels in mammalian motoneurones. We hypothesize that therapeutic and pharmacological effects of mibefradil may involve actions on Ca2+ channels other than type T.     

Transgenic A1 adenosine receptor overexpression increases myocardial resistance to ischemia

Activation of myocardial A1 adenosine receptors (A1AR) protects the heart from ischemic injury. In this study transgenic mice were created using the cardiac-specific alpha-myosin heavy chain promoter and rat A1AR cDNA. Heart membranes from two transgene positive lines displayed approximately 1,000-fold overexpression of A1AR (6,574 +/- 965 and 10,691 +/- 1,002 fmol per mg of protein vs. 8 +/- 5 fmol per mg of protein in control hearts). Compared with control hearts, transgenic Langendorff-perfused hearts had a significantly lower intrinsic heart rate (248 beats per min vs. 318 beats per min, P < 0. 05), lower developed tension (1.2 g vs. 1.6 g, P < 0.05), and similar coronary resistance. The difference in developed tension was eliminated by pacing. Injury of control hearts during global ischemia, indexed by time-to-ischemic contracture, was accelerated by blocking adenosine receptors with 50 microM 8-(p-sulfophenyl) theophylline but was unaffected by addition of 20 nM N6-cyclopentyladenosine, an A1AR agonist. Thus A1ARs in ischemic myocardium are presumably saturated by endogenous adenosine. Overexpressing myocardial A1ARs increased time-to-ischemic contracture and improved functional recovery during reperfusion. The data indicate that A1AR activation by endogenous adenosine affords protection during ischemia, but that the response is limited by A1AR number in murine myocardium. Overexpression of A1AR affords additional protection. These data support the concept that genetic manipulation of A1AR expression may improve myocardial tolerance to ischemia.     

Factors modifying ischemic injury in the isolated rat heart

The extent of ischemic injury has been studied in the isolated working rat heart utilizing an aortic ball valve that reduces the coronary flow. A number of factors were tested including high heart rate, noradrenaline, acidosis, alkalosis, high afterload, beta-blockade, glucose-insulin-potassium (GIK), palmitate and methylprednisolone. Mechanical performance, myocardial contents of ATP, creatine phosphate, glycogen and lactate and the leakage of creatine phosphokinase (CK) from the myocardium to the perfusion buffer were measured and used for determination of the ischemic injury. Tachycardia, noradrenaline and palmitate are factors that markedly increase the ischemic injury in this preparation. GIK and probably metoprolol decrease the release of CK compared with the controls.     

Effects of hyperthermic stress on myocardial function during experimental coronary ischemia

We evaluated hyperthermic influences on ischemic hearts by comparing two groups of intact working swine hearts (n = 20) made globally ischemic. Heart muscle temperature was selectively increased from 37.5 +/- 0.3 degrees C to 39.7 +/- 0.3 degrees C in one group (n = 11) by warming the coronary perfusate. Ischemia in normothermic hearts significantly (P less than 0.05) decreased mechanical function (as reflected by increases in left ventricular end-diastolic pressure [LVEDP]), myocardial oxygen consumption (MVO2), glucose uptake, glycolytic flux, free fatty acid (FFA) uptake and oxidation, and tissue stores of high energy phosphates. Hearing in ischemic hearts further depressed mechanical function at similar reductions in coronary flow and MVO2. Glucose uptake was terminally increased over normothermic values (329 vs. 221 mumol/hr per g) as was glycolytic metabolism, FFA uptake (26 vs. 17 mumol/hr per g), and FFA oxidation (21 vs. 11 mumol/hr per g). However, these changes were not translated into increased energy stores of tissue creatine phosphate and ATP. Thus, in ischemic hearts, hyperthermia neither prevented the development of mechanical deterioration nor improved oxidative phosphorylation despite increases in metabolic substrate utilization. These data suggest that in experimental global ischemia heat is an added energy drain in already burdened myocardium.     

Three-dimensional 31P magnetic resonance spectroscopic imaging of regional high-energy phosphate metabolism in injured rat heart

The purpose of this study was to measure the spatially varying 31P MR signals in global and regional ischemic injury in the isolated, perfused rat heart. Chronic myocardial infarcts were induced by occluding the left anterior descending coronary artery eight weeks before the MR examination. The effects of acute global low-flow ischemia were observed by reducing the perfusate flow. Chemical shift imaging (CSI) with three spatial dimensions was used to obtain 31P spectra in 54-microl voxels. Multislice 1H imaging with magnetization transfer contrast enhancement provided anatomical information. In normal hearts (n = 8), a homogeneous distribution of high-energy phosphate metabolites (HEP) was found. In chronic myocardial infarction (n = 6), scar tissue contained negligible amounts of HEP, but their distribution in residual myocardium was uniform. The size of the infarcted area could be measured from the metabolic images; the correlation of infarct sizes determined by histology and 31P MR CSI was excellent (P < 0.006). In global low-flow ischemia (n = 8), changes of HEP showed substantial regional heterogeneity. Three-dimensional 31P MR CSI should yield new insights into the regionally distinct metabolic consequences of various forms of myocardial injury.     

Myocardial protection during antegrade versus retrograde cardioplegia

BACKGROUND: It has been suggested that the right ventricular myocardium is suboptimally protected during retrograde blood cardioplegia. METHODS: Twenty patients undergoing an elective coronary bypass procedure were randomized to receive antegrade or retrograde mild hypothermic blood cardioplegia. Transventricular differences in oxygen extraction, lactate production, and pH were monitored during aortic cross-clamping, and myocardial biopsy specimens were taken from both ventricles before cannulation and 15 minutes after aortic declamping for analysis of adenine nucleotides and their breakdown products. The extent of myocardial injury was estimated by monitoring postoperative leakage of troponin T and the MB isoenzyme of creatine kinase. Hemodynamic recovery and postoperative complications were noted. RESULTS: The preoperative characteristics of the two groups were similar. Oxygen extraction and lactate production in the right ventricular myocardium were higher in the retrograde group. In this group, the right ventricle also extracted more oxygen and produced more lactate and acid than did the left ventricle. Tissue levels of adenine nucleotides tended to decrease in both ventricles during operation, with no differences between them. The level of adenosine catabolites did increase somewhat in the right ventricular myocardium of the retrograde cardioplegia group after aortic declamping. There was a tendency for more prominent efflux of troponin T and the MB isoenzyme of creatine kinase in the retrograde group. Nevertheless, the postoperative course was uneventful in both groups. CONCLUSIONS: Retrograde mild hypothermic blood cardioplegia leads to metabolic changes compatible with right ventricular ischemia. Nevertheless, tissue levels of high-energy phosphates are well preserved, and the postoperative course seems to be unproblematic. Care should be taken when retrograde normothermic blood cardioplegia is provided for patients with right ventricular hypertrophy, poor right ventricular function, or severe preoperative myocardial ischemia.     

Superoxide scavenging activity of erythromycin-iron complex

Protein kinase C (PKC) appears to be a common intracellular effector and signal collector during cardiac preconditioning; however, it remains unknown whether agonists that activate different PKC isoforms are also linked to select aspects of myocardial protection. Using agonists that are known to activate unique combinations of PKC isoforms, we interrogated the relationship between isoform activation and the different aspects (pH, function, and viability) of endogenous myocardial protection. To study this, isolated rat hearts were subjected to ischemia-reperfusion (I/R) (20 min/40 min), without (control = Ctrl) or with receptor-dependent [phenylephrine (PE), 50 microM; adenosine (ADO), 125 microM] or -independent [phorbol myristate acetate (PMA), 100 nM] activation of PKC. Function, pH, and viability were assessed by rate pressure product (%RPP) and coronary flow (CF; ml/min), by 31P NMR, and by CF creatine kinase (CK; U/liter) leak, respectively. PMA, which activates PKC delta but not eta, resulted in intracellular pH (pHi) and viability protection, but did not protect against postischemic myocardial stunning. ADO, which activates PKC eta but not delta, protects against stunning, but not acidosis or necrosis. PE, which activates PKC delta and eta, provided global myocardial protection against necrosis, acidosis, and stunning. Different PKC isoforms may be linked to distinct aspects of myocardial protection. Targeted activation of PKC isoforms may allow precise mechanistic application of preconditioning-like myocardial protection.     

Impairment of energy metabolism in intact residual myocardium of rat hearts with chronic myocardial infarction

The purpose of this study was to test the hypothesis that energy metabolism is impaired in residual intact myocardium of chronically infarcted rat heart, contributing to contractile dysfunction. Myocardial infarction (MI) was induced in rats by coronary artery ligation. Hearts were isolated 8 wk later and buffer-perfused isovolumically. MI hearts showed reduced left ventricular developed pressure, but oxygen consumption was unchanged. High-energy phosphate contents were measured chemically and by 31P-NMR spectroscopy. In residual intact left ventricular tissue, ATP was unchanged after MI, while creatine phosphate was reduced by 31%. Total creatine kinase (CK) activity was reduced by 17%, the fetal CK isoenzymes BB and MB increased, while the "adult" mitochondrial CK isoenzyme activity decreased by 44%. Total creatine content decreased by 35%. Phosphoryl exchange between ATP and creatine phosphate, measured by 31P-NMR magnetization transfer, fell by 50% in MI hearts. Thus, energy reserve is substantially impaired in residual intact myocardium of chronically infarcted rats. Because phosphoryl exchange was still five times higher than ATP synthesis rates calculated from oxygen consumption, phosphoryl transfer via CK may not limit baseline contractile performance 2 mo after MI. In contrast, when MI hearts were subjected to acute stress (hypoxia), mechanical recovery during reoxygenation was impaired, suggesting that reduced energy reserve contributes to increased susceptibility of MI hearts to acute metabolic stress.     

MgADP promotes a catch-like state developed through force-calcium hysteresis in tonic smooth muscle

Tonic rabbit femoral artery and phasic rabbit ileum smooth muscles permeabilized with Triton X-100 were activated either by increasing [Ca2+] from pCa > 8.0 to pCa 6.0 (calcium-ascending protocol) or contracted at pCa 6.0 before lowering [Ca2+] (calcium-descending protocol). The effects of, respectively, high [MgATP]/low [MgADP] [10 mM MgATP + creatine phosphate (CP) + creatine kinase (CK)] or low [MgATP]/[MgADP] (2 mM MgATP, 0 CP, 0 CK) on the "force-[Ca]" relationships were determined. In femoral artery at low, but not at high, [MgATP]/[MgADP] the force and the ratio of stiffness/force at pCa 7.2 were significantly higher under the calcium-descending than calcium-ascending protocols (54% vs. 3% of Po, the force at pCa 6.0) (force hysteresis); the levels of regulatory myosin light chain (MLC20) phosphorylation (9 +/- 2% vs. 10 +/- 2%) and the velocities of unloaded shortening V0 (0.02 +/- 0.004 l/s with both protocols) were not significantly different. No significant force hysteresis was detected in rabbit ileum under either of these experimental conditions. [MgADP], measured in extracts of permeabilized femoral artery strips by two methods, was 130-140 microM during maintained force under the calcium-descending protocol. Exogenous CP (10 mM) applied during the descending protocol reduced endogenous [MgADP] to 46 +/- 10 microM and abolished force hysteresis: residual force at low [Ca2+] was 17 +/- 5% of maximal force. We conclude that the proportion of force-generating nonphosphorylated (AMdp) relative to phosphorylated cross-bridges is higher on the Ca2+-descending than on the Ca2+-ascending force curve in tonic smooth muscle, that this population of positively strained dephosphorylated cross-bridges has a high affinity for MgADP, and that the dephosphorylated AMdp . MgADP state makes a significant contribution to force maintenance at low levels of MLC20 phosphorylation.     

A histometrical study on the globus pallidus in Huntington''s disease

Adenosine is recognised as an important regulator of myocardial function and coronary vascular tone in the ischaemic myocardium. It is produced by the enzymatic dephosphorylation of 5'-AMP by 5'-nucleotidase and the hydrolysis of SAH by SAH-hydrolase. 5'-Nucleotidase is thought to contribute to adenosine production aside from the accumulation of 5'-AMP in the ischaemic myocardium, while the hydrolysis of SAH plays a major role in adenosine production in the normoxic myocardium. 5'-Nucleotidase activity is reported to increase adenosine production through accumulation of ATP, ADP, H+, Mg2+ and inorganic phosphate during ischaemia. In addition, we have found that alpha 1 adrenergic receptors, activated in ischaemic hearts, increase both 5'-nucleotidase activity and adenosine production. Inactivation of adenosine deaminase and adenosine kinase may also contribute to adenosine production. On the other hand, the major role of endogenous adenosine is to increase coronary blood flow. This adenosine induced coronary vasodilatation is amplified by alpha 2 adrenoceptor stimulation. Adenosine induced vasodilatation is also enhanced by increasing H+ and opening ATP sensitive K+ channels, which occurs in the ischaemic myocardium. However, coronary vasodilatation is not the only effect of adenosine in the ischaemic myocardium. Stimulation of adenosine A2 receptors coupled to Gs proteins attenuates both free radical generation by activated leucocytes and aggregation of platelets. Adenosine A1 receptor activation coupled to G(i) proteins attenuates beta adrenoceptor mediated increases in myocardial contractility, Ca2+ influx into myocytes, and noradrenaline release from the presynaptic nerves. Any or all of these effects may attenuate ischaemic and reperfusion injury.(ABSTRACT TRUNCATED AT 250 WORDS)     

Attenuation of myocardial reperfusion injury by reducing intracellular calcium overloading with dihydropyridines

The effects of three different dihydropyridine (DHP) calcium channel antagonists, nisoldipine, nimodipine, and nifedipine, on myocardial ischemic and reperfusion injury were studied using isolated rat hearts subjected to ischemia and reperfusion. Hearts were perfused with Krebs-Henseleit bicarbonate buffer containing 0, 4, 16, 64 and 100 nM concentrations of the above dihydropyridines for 15 min. Global ischemia was then induced by terminating the aortic flow for 30 min at 37 degrees, followed by 30 min of reperfusion. Left ventricular (LV) functional (LV developed pressure, its first derivative and coronary flow) and biochemical parameters (creatine kinase release) were monitored prior to ischemia and during reperfusion. In separate group of hearts, intracellular free Ca2+ ([Ca2+]i) was monitored with an intracellular calcium analyzer using a fluorescent Ca2+ indicator (Fura-2 AM). Tissue Ca2+ was also measured by atomic absorption spectroscopy after perfusing the hearts with ion-free cold buffer to wash out extracellular Ca2+. Significant recovery of the coronary flow was observed in all hearts treated with a high concentration (100 nM) of DHPs compared with the control group (P < 0.05), while a lower dose of nisoldipine (16 nM) and nifedipine (64 nM) also improved the coronary flow effectively. Reduction of myocardial creatine kinase release and improvement of the recovery of LV developed pressure, dp/dtmax, were achieved by DHPs in a concentration-dependent manner. A higher concentration of DHPs also decreased the formation of myocardial thiobarbituric acid reactive substances, although these compounds did not possess direct free radical scavenging effects in vitro. Tissue Ca2+ content was reduced significantly in treated groups. The rise of [Ca2+]i during ischemia and reperfusion appeared to be attenuated by these DHPs. The concentration-response study of the three DHPs showed the effective concentrations for reducing [Ca2+]i to be 16, 64 and 100 nM nisoldipine, nifedipine and nimodipine, respectively, in this experimental setting. The above results indicate that pretreatment with DHPs can attenuate the myocardial reperfusion injury by modulating Ca2+ overloading and decreasing the susceptibility of the membrane to free radical attack.     

Dihydropyridines and verapamil inhibit voltage-dependent K+ current in isolated outer hair cells of the guinea pig

Dihydropyridines and verapamil are widely used as blockers of voltage-dependent Ca++ channels. In this work we show that these compounds can have a direct blocking action on a class of voltage-activated potassium channels. Voltage-dependent whole-cell currents were recorded from isolated guinea-pig outer hair cells (OHCs) under conditions such that the free Ca++ concentration in both the internal and external solutions was minimized. A substantial Ca(++)-independent K+ current was revealed by this procedure. Both conventional K+ and Ca++ channel ligands inhibited this current. The order of potency (in terms of the half inhibitory concentrations (IC50) of channel inhibitors) was: nimodipine (6 microM) > Bay K 8644 (8 microM) > verapamil (11 microM) > 4-aminopyridine (22 microM) > nifedipine (32 microM) > quinine (49 microM) > TEA (10236 microM). Except for verapamil, these channel ligands reduced the size of the K+ currents without much alteration of the time course of the currents. In contrast, verapamil caused a more than 10-fold increase in the apparent inactivation rate of the K+ currents without significantly altering the activation of the currents. The observation that relatively low concentrations of calcium channel ligands can directly inhibit potassium currents in isolated OHCs indicates that caution should be taken when these pharmacological agents are used as tools for studying cochlear hair cell physiology.     

Plasma MB creatine kinase activity and other conventional enzymes. Comparison in patients with chest pain and tachyarrhythmias

We studied 67 patients with tachycardia and chest pain admitted with suspected myocardial infarction; 29 had myocardial infarction (20 transmural, nine subendocardial) with elevated MB creatine kinase (CK) activity, as well as elevated total CK and lactate dehydrogenase (LDH) levels. However, hydroxybutyric dehydrogenase and SGOT activity remained normal in three and four patients, respectively. Despite abnormal ECGs in 84% and typical chest pain in 54%, 38 patients had normal MB CK activity. However, 15 of them had elevated MM CK levels, presumably due to release from skeletal muscle. In total, 29 patients had elevated activity of MM, CK, LDH, or SGOT, but 72% of these patients had cardiac failure, hypotension, or skeletal muscle trauma due to cardioversion. Eleven patients with normal MB CK had elevated hydroxybutyric dehydrogenase activity. Despite elevated activity of other enzymes, MB CK remained normal. Thus, elevated plasma MB CK activity appears to remain a good diagnostic marker of myocardial necrosis in patients with tachyarrhythmias.     

Hibernating myocardium: a review

Within a few seconds after a sudden reduction of coronary blood flow regional contractile dysfunction ensues. The mechanisms responsible for the rapid reduction in contractile function during acute myocardial ischemia remain unclear, but may involve a rise in inorganic phosphate. When severe ischemia, such as resulting from a sudden and complete coronary artery occlusion, is prolonged for more than 20-40 min, myocardial infarction develops, and there is irreversible loss of contractile function. When myocardial ischemia is less severe but nevertheless prolonged, the myocardium is dysfunctional but can remain viable. In such ischemic and dysfunctional myocardium, contractile function is reduced in proportion to the reduction in regional myocardial blood flow; i.e. a state of "perfusion-contraction matching" exists. The metabolic status of such myocardium improves over the first few hours, as myocardial lactate production is attenuated and creatine phosphate, after an initial reduction, returns towards control values. Ischemic myocardium, characterized by perfusion-contraction matching, metabolic recovery and lack of necrosis, has been termed "short-term hibernating myocardium". Short-term hibernating myocardium can respond to an inotropic stimulation with increased contractile function, however, at the expense of a renewed worsening of the metabolic status. This situation of an increased regional contractile function at the expense of metabolic recovery during inotropic stimulation can be used to identify short-term hibernating myocardium. When inotropic stimulation is prolonged, the development of short-term hibernation is impaired and myocardial infarction develops. The mechanisms responsible for the development of short-term myocardial hibernation remain unclear at present; a significant involvement of adenosine and of activation of ATP-dependent potassium channels has been excluded. Whereas short-term hibernation is well characterized in animal experiments, the existence of hibernation over weeks or months (long-term hibernation) can only be inferred from clinical studies. Hibernation, as defined by Rahimtoola, is a state of chronic contractile dysfunction which is fully reversible upon reperfusion. Clinical syndromes consistent with the existence of myocardial hibernation include unstable and stable angina, acute myocardial infarction and left ventricular dysfunction and/or congestive heart failure. In long-term hibernating myocardium morphological alterations occur; the myofibrils are reduced in number and disorganized and myocardial glycogen content as well as the extracellular collagen network are increased. Thus, despite the fact that the myocardium remains viable during persistent ischemia and contractile dysfunction is reversible upon reperfusion, there are severe morphological alterations. Understandably, full functional recovery following reperfusion might therefore require weeks or even months.     

Non-invasive magnetic-resonance detection of creatine depletion in non-viable infarcted myocardium

BACKGROUND: Preserved energy metabolism is essential for myocardial viability and the creatine kinase reaction is central to energy production and reserve. Although the appearance of myocardial creatine kinase enzyme in the blood is widely used to diagnose cardiac necrosis, there are no non-invasive ways to measure local creatine concentrations in the healthy and diseased human heart. METHODS: We measured total myocardial creatine by spatially-localised, water-suppressed hydrogen magnetic-resonance spectroscopy (1H-MRS) on a clinical (1.5 T) magnetic-resonance-imaging system in ten healthy volunteers (controls) and ten patients with a history of myocardial infarction. We validated this technique by comparison of 1H-MRS values of creatine with biopsy assays in an animal model of infarction. FINDINGS: Total creatine was measured in the posterior and anterior left ventricle and septum, and was significantly lower in regions of infarction (10 [9] SD micromol/g wet weight) than in non-infarcted regions (26 [11] micromol/g, p=0.001) of myocardium in patients or in the myocardium of healthy controls (28 [6] micromol/g, p<0.0001). INTERPRETATION: Spatially localised 1H-MRS can be used to measure total creatine non-invasively throughout the human heart. The detection of regional creatine depletion may provide a metabolic means to distinguish healthy from infarcted non-viable myocardium.     

Effects of alpha 1-adrenoreceptor subtype blockade on ischemia-reperfusion injury

To clarify the roles of subclasses of alpha 1-adrenoreceptors in ischemic-reperfused myocardium, we compared the effect of the nonselective alpha 1-blocker bunazosin with that of the alpha 1A-blocker WB4101 and the alpha 1B-blocker chlorethylclonidine (CEC) in isolated rat hearts. After 30 min of preperfusion, Langendorff-perfused hearts were subjected to 25 min of global ischemia followed by 30 min of reperfusion. Hearts were randomly divided into 4 groups, with one of the following substances being added to the perfusate: buffer alone (control), 10(-6) mol/L bunazosin, 10(-7) mol/L WB4101, or 10(-7) mol/L CEC. Bunazosin had a negative inotropic effect and preserved the postischemic ATP content, reduced the postischemic increase in intracellular Na+ content and then enhanced postreperfusion recovery of creatine phosphate. Bunazosin also reduced myocardial 45Ca2+ uptake during reperfusion (control 5.2 vs bunazosin 2.5 mumol/g dry weight of tissue (dwt), p < 0.01). However, the recovery of left ventricular developed pressure (DP) was not improved when bunazosin was added to the perfusate during reperfusion. WB4101 had neither a negative inotropic nor an energy-sparing effect, but it improved the recovery of DP (control 43% vs WB4101 56% of preischemic value, p < 0.05) with no reduction in myocardial 45Ca2+ uptake. CEC had a negative inotropic and energy-sparing effect and then reduced myocardial 45Ca2+ uptake (CEC 3.1 mumol/g dwt, p < 0.05), but it did not improve the recovery of DP. These results suggest that the preischemic administration of an alpha 1B-adrenoreceptor subtype blocker protected ischemic-reperfused myocardium via reduction of Ca2+ overload, whereas the selective blockade of the alpha 1A-adrenoreceptor subtype reduced myocardial damage via mechanism(s) other than Ca2+ metabolism.