Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: DrugBank:EXPT02288 (NADH)
 21,914 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Using NADH fluorometry to monitor myocardial metabolism, the mechanism of reperfusion injury was investigated after the delivery of an experimental reperfusate. Using an isolated working heart preparation, rat hearts underwent 15 min of global ischemia at 37 degrees C. Following the ischemic insult, an oxygenated enriched reperfusion solution was given for 5 min. The hearts were then returned to a working state and aortic flow recorded to evaluate recovery. NADH levels were monitored throughout the experiment with a fluorometer and glycogen, AMP, ADP, and ATP were measured biochemically pre- and postischemia, after reperfusion and after recovery. In this study, reperfusion injury was best abated by an enriched reperfusate. Our results indicate the mechanism for this amelioration is not high-energy phosphate replenishment. Rather, as indicated by NADH fluorescence, the hearts attain an intermediate level of metabolism that permits glycogen to be restored and functional recovery to be improved.
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PMID:Monitoring myocardial reperfusion injury with NADH fluorometry. 161 62

The purpose of this work was to evaluate the biochemical changes in the myocardial cell using cardioplegia supplemented with creatine phosphate (CP). Many previous studies have demonstrated the beneficial effect of CP on the ischemic myocardium and its mechanism of action has been assumed to be mainly extracellular. Based on the assumption that CP could also exert some influence on myocardial cellular metabolism, this investigation was carried out. Forty patients undergoing mitral valve replacement were divided into two groups: group 1 was treated with standard cardioplegic solution, and group 2 was treated with cardioplegic solution enriched with CP at a concentration of 10 mmol/L. Samples of papillary muscle, obtained from the removed valve, were studied by means of biochemical methods in order to assess the enzyme activities and the metabolites of the different biochemical pathways related to energy metabolism in the myocardial cell. One papillary muscle sample was used to determine enzyme activities spectrophotometrically; another was used to evaluate metabolite concentrations by spectrophotometric or spectrophotofluorimetric methods. The rate of spontaneous functional recovery after rewarming and weaning from cardiopulmonary bypass (CPB) also was evaluated. In group 2, the Vmax of enzymatic activities was significantly greater (hexokinase, malate dehydrogenase, glutamate dehydrogenase, total NADH cytochrome c reductase) and a better functional state of the heart was observed after CPB. On the basis of the clinical and biochemical data, it is concluded that the myocardium was better preserved when CP was added to the cardioplegic solution. Therefore, the results suggest a possible interaction of exogenous CP with cellular metabolism.
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PMID:Biochemical changes induced in the myocardial cell during cardioplegic arrest supplemented with creatine phosphate. 193 52

The detrimental effect of exogenous lactate during ischaemia on post-ischaemic contractile function may be mediated either by a lactate-induced intracellular H+ load or by an increase in intracellular lactate. To distinguish between these two mechanisms, isolated rat hearts were perfused with lactate or pyruvate during low flow ischaemia, the rationale being that both would decrease H+ efflux via lactate/H+ cotransport and lead to decreased pH, but only exogenous lactate would decrease lactate efflux and lead to increased intracellular lactate. 31P NMR spectra were acquired sequentially while hearts were subjected to 32 min low flow (0.5 ml/min) ischaemia and 32 min reperfusion. During ischaemia, hearts were perfused with Krebs-Henseleit buffer containing 11 mM glucose (controls) or 11 mM glucose plus either 10 mM lactate or 10 mM pyruvate. Reperfusion of all hearts was with buffer containing only glucose. Intracellular volume, estimated to be 0.52 ml/heart using 31P NMR spectroscopy with phosphonate space markers, did not change under any of the ischaemic conditions during the protocol. Control and pyruvate hearts recovered approximately 85% of pre-ischaemic contractile function, but there was no recovery of function in lactate hearts. This lack of recovery correlated with a 57% loss of ATP during ischaemia, which was significantly greater (P < 0.001) than the 41% loss of ATP in control and pyruvate-perfused hearts. End-ischaemic intracellular pH was 6.60 in both lactate-perfused and control hearts, but significantly lower (P < 0.05) at pH 6.43 in pyruvate-perfused hearts. Both exogenous pyruvate and lactate should have decreased H+ efflux, however the higher pH in the lactate-perfused hearts could be explained by a 60% inhibition of glycolysis, determined by measurement of myocardial lactate production. Thus, the intracellular pH during ischaemia does not necessarily predict the extent of myocardial injury. We propose that lactate-induced damage is a consequence of increased intracellular lactate leading to inhibition of glycolysis, presumably via an increased NADH/NAD ratio. This study highlights the important role of glycolysis in the ischaemic rat heart.
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PMID:Is lactate-induced myocardial ischaemic injury mediated by decreased pH or increased intracellular lactate? 747 83

Rat hearts, arrested in situ after intracaval injection of a cardioplegic solution, were preserved for 15 hours at 4 degrees C either by simple immersion or by low-flow (0.3 mL/min) perfusion. After preservation under both conditions, the left ventricular pressure developed by the reperfused hearts reached 8% and 43% of the control value (80 mm Hg), respectively. The addition of trimetazidine (TMZ; 10(-6) M) to the cardioplegic solution induced an improvement in functional recovery (by 2.4 and 1.5, respectively). This effect of TMZ was accompanied by a better energy profile illustrated by a 2-fold increase in the adenosine triphosphate to inorganic phosphate ratio and a reduction of intracellular acidosis as determined by 31P nuclear magnetic resonance spectroscopy. The function of the mitochondria (state 3, reduced nicotinamide-adenine dinucleotide [NADH] formation) isolated from the preserved hearts was significantly depressed in the stored hearts. The addition of TMZ to the cardioplegic solution partially protected oxoglutarate (and succinate) mitochondrial respiration and induced an increase in Ca2+ triggered NADH formation. These results show that the bioenergy status of the myocardial cell in isolated arrested stored rat heart is improved by the presence of TMZ in the preservation solution. Moreover, the experiments demonstrate that this effect includes protection of mitochondrial function and suggest that the drug could exert some control in the Ca2+ regulation of mitochondria.
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PMID:Improvement of long-term preservation of the isolated arrested rat heart by trimetazidine: effects on the energy state and mitochondrial function. 764 29

The enteric nervous system appears to play a pivotal role in the functional recovery of the gastrointestinal tract after partial resection and reanastomosis, but the structural changes following surgery are not fully understood. The present study was designed to clarify the processes of myenteric plexus regeneration up to one year after transection and reanastomosis of the ileum of the guinea pig. The following techniques were used: nicotinamide adenine dinucleotide (NADH) diaphorase histochemistry, immunostaining of neuron-specific enolase (NSE) in whole-mount preparations, and transmission electron microscopy. Two months after transection and reanastomosis, myenteric ganglion cells with NADH diaphorase reactions were scarce in the center of the lesion, and were less numerous in adjacent areas (3 mm in width) than in the control ileum. In the areas adjacent to the lesion, a few large extraganglionic neurons that did not completely compensate for the loss of ganglion neurons were observed. The remaining ileum showed no changes in NADH diaphorase staining pattern at this stage. Two to 12 months after transection and reanastomosis, ectopic large neurons gradually increased in number not only in the areas adjacent to the lesion but also in part of the remaining ileum, up to 10 cm from the lesion. Concomitantly, large ganglion neurons decreased in number in these areas. In other ileal regions (more than 10 cm distant from the site of transection), no obvious changes in NADH diaphorase staining were noted throughout the observation period. The outgrowth of NSE-containing nerve fibers from the severed stumps was seen two weeks after transection. Six weeks later, numerous bundles of fine nerve fibers with NSE were shown to interconnect the oral and anal cut ends of the myenteric plexus, but they exhibited no subsequent alterations. Transmission electron microscopy revealed that regenerating nerve fiber bundles appeared initially among irregularly arranged smooth muscle cells eight weeks after the operation, as expected from light-microscopic observations. These findings suggest that myenteric ganglion cell bodies, unlike myenteric nerve fibers, require a longer term of reconstruction than previously believed after transection and reanastomosis of the ileum of the guinea pig.
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PMID:Progressive reorganization of the myenteric plexus during one year following reanastomosis of the ileum of the guinea pig. 808 20

Experimentally, enhanced glycolytic flux has been shown to confer many benefits to the ischemic heart, including maintenance of membrane activity, inhibition of contracture, reduced arrhythmias, and improved functional recovery. While at moderate low coronary flows, the benefits of glycolysis appear extensive, the controversy arises at very low flow rates, in the absence of flow; or when glycolytic substrate may be present in excess, such that high glucose concentrations with or without insulin overload the cell with deleterious metabolites. Under conditions of total global ischemia, glycogen is the only substrate for glycolytic flux. Glycogenolysis may only be protective until the accumulation of metabolites (lactate, H+, NADH, sugar phosphates and Pi ) outweighs the benefit of the ATP produced. The possible deleterious effects associated with increased glycolysis cannot be ignored, and may explain some of the controversial findings reported in the literature. However, an optimal balance between the rate of ATP production and rate of accumulation of metabolites (determined by the glycolytic flux rate and the rate of coronary washout), may ensure optimal recovery. In addition, the effects of glucose utilisation must be distinguished from those of glycogen, differences which may be explained by functional compartmentation within the cell.
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PMID:Glucose and glycogen utilisation in myocardial ischemia--changes in metabolism and consequences for the myocyte. 954 26

This study concerns functional recovery of zebrafish following spinal cord transection. Spinal cords were transected at the level of the 14th vertebra, just rostral to the dorsal fin. Recovery was tested at one month after transection when descending fibers start to regrow across the transection site and at three months after transection when fish perform kick and glide swimming. To estimate the rate of regrowth across the lesion site we analysed the tyrosine hydroxylase (TH) and dorsal 5-hydroxytryptamine (5-HT) systems in distal parts of lesioned cords. Both systems have cell bodies in the brainstem and in control fish TH- and dorsal 5-HT-containing fibers descend to all spinal segments. Swimming performance was studied by subjecting lesioned fish to endurance tests in a swimming tunnel with water flowing at a constant rate of 2 or 4.5 body lengths per second (BL/s). At 2 BL/s slow myotomal muscles are active whereas at 4.5 BL/s fast myotomal muscles are recruited. Control fish endured sustained swimming at both speeds for at least 3 hours. As a measure for the condition of the neuromuscular system in trunk and tail, we analysed aerobic metabolic capacities, assessed by NADH-tetrazolium reductase (NADH-TR) histochemistry of myotomal muscle fibers and spinal lateral neuropil. We found that TH- and dorsal 5-HT-immunoreactive fibers were absent in the entire distal part of lesioned cords at one month but at two months after transection they were present at approximately 6000 microns caudally to the site of the lesion. Thus the rate of outgrowth of these fibers is at least 200 microns per day. Sustained swimming at the slow speed (2 BL/s) could be endured for about 14.4 min at one month and for 23.5 min at two months after transection; there was no further improvement in the period that followed. In contrast, in the 10 weeks following transection, fast swimming (4.5 BL/s) could be endured for about 5 to 6 minutes. A significant improvement was gained in the period of 10 to 12 weeks after transection when fish could endure the high speed for almost 15 min. The aerobic capacity of muscle fibers in distal parts of the body was not strongly affected by the lesion. The only important change in aerobic capacity was observed in the neuropil of distal parts of the cords where, at three months after transection, NADH-TR activity was increased to approximately 150% of control values. On the basis of our findings, we assume that it is not the condition of the neuromuscular system, but rather a deficient co-ordination between proximal and distal body parts of lesioned fish that accounts for the relatively poor performances in endurance tests. Furthermore, differences in timing of improvements in swimming at 2 and 4.5 BL/s indicate that the spinal circuitries serving the slow parts of the neuromuscular system recover at an earlier stage than those serving the fast parts.
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PMID:Long term effects of spinal cord transection in zebrafish: swimming performances, and metabolic properties of the neuromuscular system. 958 24

Several studies have shown that maintenance of glycolysis limits the metabolic and functional consequences of low-flow ischemia. Because diabetic animals are known to have impaired glycolytic metabolism coupled with increased flux through the aldose reductase (AR) pathway, we hypothesized that inhibition of AR would enhance glycolysis and thereby improve metabolic and functional recovery during low-flow ischemia. Hearts (n = 12) from nondiabetic control and diabetic rats were isolated and retrograde perfused using 11 mM glucose with or without the AR inhibitor zopolrestat (1 microM). Hearts were subjected to 30 min of low-flow ischemia (10% of baseline flow) and 30 min of reperfusion. 31P NMR spectroscopy was used to monitor time-dependent changes in phosphocreatine (PCr), ATP, and intracellular pH. Changes in the cytosolic redox ratio of NADH to NAD+ were obtained by measuring the ratio of tissue lactate to pyruvate. Effluent lactate concentrations and oxygen consumption were determined from the perfusate. AR inhibition improved functional recovery in both control and diabetic hearts, coupled with a lower cytosolic redox state and greater effluent lactate concentrations during ischemia. ATP levels during ischemia were significantly higher in AR-inhibited hearts, as was recovery of PCr. In diabetic hearts, AR inhibition also limited acidosis during ischemia and normalized pH recovery on reperfusion. These data demonstrate that AR inhibition maintains higher levels of high-energy phosphates and improves functional recovery upon reperfusion in hearts subjected to low-flow ischemia, consistent with an increase in glycolysis. Accordingly, this approach of inhibiting AR offers a novel method for protecting ischemic myocardium.
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PMID:Metabolic effects of aldose reductase inhibition during low-flow ischemia and reperfusion. 968 14

Nicotinic acid (niacin) has been shown to decrease myocyte injury. Because interventions that lower the cytosolic NADH/NAD(+) ratio improve glycolysis and limit infarct size, we hypothesized that 1) niacin, as a precursor of NAD(+), would lower the NADH/NAD(+) ratio, increase glycolysis, and limit ischemic injury and 2) these cardioprotective benefits of niacin would be limited in conditions that block lactate removal. Isolated rat hearts were perfused without (Ctl) or with 1 microM niacin (Nia) and subjected to 30 min of low-flow ischemia (10% of baseline flow, LF) and reperfusion. To examine the effects of limiting lactate efflux, experiments were performed with 1) Ctl and Nia groups subjected to zero-flow ischemia and 2) the Nia group treated with the lactate-H(+) cotransport inhibitor alpha-cyano-4-hydroxycinnamate under LF conditions. Measured variables included ATP, pH, cardiac function, tissue lactate-to-pyruvate ratio (reflecting NADH/NAD(+)), lactate efflux rate, and creatine kinase release. The lactate-to-pyruvate ratio was reduced by more than twofold in Nia-LF hearts during baseline and ischemic conditions (P < 0.001 and P < 0.01, respectively), with concurrent lower creatine kinase release than Ctl hearts (P < 0.05). Nia-LF hearts had significantly greater lactate release during ischemia (P < 0.05 vs. Ctl hearts) as well as higher functional recovery and a relative preservation of high-energy phosphates. Inhibiting lactate efflux with alpha-cyano-4-hydroxycinnamate and blocking lactate washout with zero flow negated some of the beneficial effects of niacin. During LF, niacin lowered the cytosolic redox state and increased lactate efflux, consistent with redox regulation of glycolysis. Niacin significantly improved functional and metabolic parameters under these conditions, providing additional rationale for use of niacin as a therapeutic agent in patients with ischemic heart disease.
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PMID:Niacin protects the isolated heart from ischemia-reperfusion injury. 1092 76

Understanding transcriptional changes in brain after ischemia may provide therapeutic targets for treating stroke and promoting recovery. To study these changes on a genomic scale, oligonucleotide arrays were used to assess RNA samples from periinfarction cortex of adult Sprague-Dawley rats 24 h after permanent middle cerebral artery occlusions. Of the 328 regulated transcripts in ischemia compared with sham-operated animals, 264 were upregulated, 64 were downregulated, and 163 (49.7%) had not been reported in stroke. Of the functional groups modulated by ischemia: G-protein-related genes were the least reported; and cytokines, chemokines, stress proteins, and cell adhesion and immune molecules were the most highly expressed. Quantitative reverse transcription polymerase chain reaction of 20 selected genes at 2, 4, and 24 h after ischemia showed early upregulated genes (2 h) including Narp, Rad, G33A, HYCP2, Pim-3, Cpg21, JAK2, CELF, Tenascin, and DAF. Late upregulated genes (24 h) included Cathepsin C, Cip-26, Cystatin B, PHAS-I, TBFII, Spr, PRG1, and LPS-binding protein. Glycerol 3-phosphate dehydrogenase, which is involved in mitochondrial reoxidation of glycolysis derived NADH, was regulated more than 60-fold. Plasticity-related transcripts were regulated, including Narp, agrin, and Cpg21. A newly reported lung pathway was also regulated in ischemic brain: C/EBP induction of Egr-1 (NGFI-A) with downstream induction of PAI-1, VEGF, ICAM, IL1, and MIP1. Genes regulated acutely after stroke may modulate cell survival and death; also, late regulated genes may be related to tissue repair and functional recovery.
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PMID:Genomics of the periinfarction cortex after focal cerebral ischemia. 1284 83


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