Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0599766 (functional recovery)
 13,441 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Adult rhesus monkeys were subjected to complete cerebral ischemia for one hour and subsequent recirculation for up to 24 h. Animals with signs of functional recovery (e.g. spontaneous EEG activity) exhibited a partial replenishment of cellular energy sources (ATP, phosphocreatine) and a progressive normalization of cerebral lactate levels. Glucose and pyruvate concentrations showed a transient increase over control values during the early stages of postischemic recirculation. Monkeys without functional recovery lacked a significant resynthesis of energy-rich compounds; adenine nucleotides continued to decrease and lactate concentrations were higher than in animals subjected to ischemia without recirculation. Cerebral polysome profiles remained unaltered during the ischemic period but in all animals a marked disaggregation of polyribosomes with a concomitant increase in ribosomal subunits occurred after the onset of recirculation. In monkeys with indications of functional recovery these changes were reversible but a normal polysome profile was only observed after 24 h of recirculation. The results obtained indicate a postischemic depression of protein synthesis due to an inhibition of peptide chain initiation. After recirculation of the brain for 3-6 h there was evidence for an induction of enzymes involved in polyamine synthesis (ornithine decarboxylase and S-adenosylmethionine decarboxylase). No changes in the activity of these enzymes were observed at the end of the ischemic period, indicating that during complete cerebral ischemia not only the synthesis but also the catabolism of proteins is inhibited.
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PMID:Resuscitation of the monkey brain after one hour complete ischemia. III. Indications of metabolic recovery. 115 69

Isolated perfused working rat hearts were subjected to elective cardiac arrest for 20 or 30 min. Various methods of arrest were studied, either singly or in combination and with or without coronary perfusion. The functional recovery of the heart following the termination of arrest was found to be related to the concentration of ATP and creatine phosphate in the myocardium at the end of the period of arrest. In turn, these concentrations were dependent upon the method used to induce arrest. Normothermic ischemic arrest led to a marked reduction in high energy phosphates and a poor functional recovery. In contrast, coronary perfusion with hypothermic solutions or solutions containing high concentrations of potassium, induced arrest without depleting ATP or creatine phosphate. These procedures conferred considerable protection on the myocardium and thus permitted good recoveries. The energy status and recovery associated with ischemic arrest could be improved by combining the ischemia with hypothermia or potassium arrest. The latter, while increasing recovery significantly, still failed to afford complete protection to the myocardium. Potassium chloride gave greater protection than potassium citrate. When topical hypothermia was combined with ischemia, a time and temperature relationship was demonstrated but effective protection could only be obtained with severe topical hypothermia over a relatively short time period. The results stress the importance of maintaining high energy phosphates during arrest, and this requires the provision of a continuous supply of oxygen and nutrient, which may perhaps be best achieved by ensuring continuous and adequate coronary perfusion.
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PMID:Ischemic damage and metabolism during elective cardiac arrest. 120 80

Pharmacological modulation of [K+]o accumulation and action potential changes during acute myocardial ischemia is under evaluation as a promising new antiarrhythmic and cardioprotective strategy during myocardial ischemia and reperfusion. We studied the effects of cromakalim, a K+ channel opener that activates ATP-sensitive K+ channels, in isolated arterially perfused rabbit interventricular septa subjected to ischemia and reperfusion and, through use of the patch clamp technique, in inside-out membrane patches excised from guinea pig ventricular myocytes. During aerobic perfusion, 5 microM cromakalim shortened action potential duration (APD) from 217 +/- 7 to 201 +/- 10 msec, had no effect on [K+]o, and reduced tension by 17 +/- 3% (n = 11). During ischemia, pretreatment with 5 microM cromakalim resulted in 1) more rapid APD shortening (71 +/- 9 versus 166 +/- 7 msec at 10 minutes and 63 +/- 12 versus 122 +/- 8 msec at 30 minutes), 2) similar [K+]o accumulation after 10 minutes (8.9 +/- 0.3 versus 9.6 +/- 0.5 mM) but a trend toward increased [K+]o accumulation after 30 minutes (11.0 +/- 1.7 versus 9.6 +/- 1.0 mM), and 3) similar times for tension to decline to 50% of control (2.14 +/- 0.16 versus 2.14 +/- 0.19 minutes) but shorter time to fall to 20% of control (4.34 +/- 0.33 versus 4.90 +/- 0.22 minutes; p = 0.003). After 60 minutes of reperfusion following 30 minutes of ischemia, recovery of function was similar, with a trend toward better recovery of developed tension (to 58 +/- 9% versus 39 +/- 10% of control; p = 0.18) and tissue ATP levels in cromakalim-treated hearts but no differences in APD or rest tension. Thus, 5 microM cromakalim had mild effects in normal heart but greatly accelerated APD shortening during ischemia without markedly increasing [K+]o accumulation, possibly because the more rapid APD shortening reduced the time-averaged driving force for K+ efflux through ATP-sensitive K+ channels. A significant cardioprotective effect during 30 minutes of ischemia plus 60 minutes of reperfusion could not be demonstrated in this model. In excised membrane patches studied at room temperature, the ability of cromakalim to activate ATP-sensitive K+ channels was significantly potentiated by 100 microM but not 15 microM cytosolic ADP, suggesting that in addition to the modest fall in cytosolic ATP during early ischemia, the rapid increases in cytosolic ADP may further sensitize cardiac ATP-sensitive K+ channels to activation by cromakalim.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Activation of ATP-sensitive K+ channels by cromakalim. Effects on cellular K+ loss and cardiac function in ischemic and reperfused mammalian ventricle. 142 30

Cells subjected to increases in temperature induce the expression of several proteins known as heat shock or stress proteins. This process enhances the cell's ability to overcome the effects of further stress. In this respect, the effects of heat stress have been reported to protect the hearts of rats following ischaemia and reperfusion. We have confirmed and extended this observation, not only using different indices of myocardial injury but also in another species, namely the rabbit. Animals were anaesthetized and the body temperature raised to 42 degrees C for a 15-min period. Controls were treated in the same way but without heating. Twenty-four hours later the rabbits were re-anaesthetized and the hearts removed for either heat stress protein analysis or perfusion with Krebs buffer using an isolated perfused heart apparatus. Hearts were subjected to 60 min of low flow (1 ml/min) ischaemia followed by 30 min of reperfusion. All hearts subjected to heat stress showed an enhanced recovery of function upon reperfusion as measured by improvements in developed pressure (27.3 +/- 3.6 vs 16.3 +/- 3.0 mmHg) and diastolic pressure (37.3 +/- 7.4 vs 54.7 +/- 3.1 mmHg). In addition, creatine kinase release, associated with reperfusion, was significantly reduced in the heat-stressed hearts (532 +/- 102 vs 1138 +/- 73 mU/min/g wet wt). Myocardial accumulation and release of oxidized glutathione, an index of oxidative stress, was significantly reduced in the heat-stressed group (0.003 +/- 0.003 vs 0.376 +/- 0.113 nmol/min/g wet wt). The improved metabolic status of the reperfused heat-stressed hearts was further demonstrated by a significant conservation in the levels of ATP (6.1 +/- 0.9 vs 2.8 +/- 0.8 mumol/g dry wt) and CP (36.9 +/- 6.4 vs 16.4 +/- 5.1 mumol/g dry wt). Finally, isolated mitochondrial function in terms of respiratory control index (RCI) was maintained in the heat-stressed hearts (9.2 +/- 0.9 vs 5.7 +/- 0.2) and overloading with calcium was reduced. These data extend the hypothesis that heat stress protects the heart following ischaemia and reperfusion in this in vitro model, in a way as yet undetermined.
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PMID:The protective role of heat stress in the ischaemic and reperfused rabbit myocardium. 143 16

The success of heart transplantation is limited by the negative correlation between the length of the cold ischemic storage period and the quality of functional recovery. We use 23Na, 31P NMR spectroscopy, and hemodynamic parameters to describe temperature-dependent changes in sodium influx and the concentration of phosphorus high-energy compounds during different storage periods. Perfusion with Krebs-Henseleit solutions containing Dy(TTHA)3- permitted discrimination of intra- and extracellular sodium during cold ischemic storage. The 23Na NMR visibilities under the acquisition and processing parameters used in our experiments were 40 +/- 4% for the intracellular compartment and 97 +/- 11% for the extracellular compartment. At 4 degrees C, the intracellular Na+ accumulation exceeded that observed at 15 and 22 degrees C. The ATP and PCr depletion rates were much lower at 4 degrees C and the left ventricular contractility was higher after longer periods of storage, as the storage temperature decreased. The intracellular Na+ concentration cannot serve as a marker for the postischemic recovery probability. The relative activity of the Na/K ATPase pumps is not correlated with the preservation success. However, intracellular sodium ion accumulation is a major factor in the time lag of the reperfusion recovery.
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PMID:Sodium ion transport in rat hearts during cold ischemic storage: 23Na and 31P NMR study. 146 Nov 25

In this study we determined the effects of high levels of fatty acids on recovery of heart function when present either during or after ischemia. Isolated working hearts from 6-wk streptozotocin diabetic and control rats perfused with 11 mM glucose were subjected to 25 min of global ischemia followed by 30 min of aerobic reperfusion. Four groups were studied: 1) 1.2 mM palmitate present before, during, and after ischemia; 2) 1.2 mM palmitate present before and during ischemia, followed by reperfusion in the absence of palmitate; 3) no palmitate before and during ischemia, followed by 1.2 mM palmitate during reperfusion; and 4) no palmitate before and during ischemia or during reperfusion. In control hearts, palmitate during reperfusion depressed recovery of function regardless of whether palmitate was present or absent during ischemia. In contrast, palmitate present during reperfusion did not depress recovery of mechanical function in the diabetic rat hearts. However, the presence of palmitate during ischemia itself in diabetic rat hearts was detrimental to recovery of mechanical function. The presence of palmitate during ischemia resulted in an accelerated rate of ATP loss and a decreased rate of lactate accumulation during ischemia, although this effect was similar in control and diabetic rat hearts. Our results demonstrate that high concentrations of fatty acids depress functional recovery of control rat hearts during the reperfusion period but depress recovery of function in diabetic rat hearts when present during ischemia itself.
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PMID:Effects of high levels of fatty acids on functional recovery of ischemic hearts from diabetic rats. 147 76

Depletion of high-energy phosphates, accumulation of inorganic phosphate and intracellular acidosis have each been proposed as important events in the transition from reversible to irreversible ischemic injury. To assess whether each variable is predictive of functional recovery on reperfusion, these were measured in the isolated isovolumic rat heart using 31P NMR. Perfused hearts were subjected to either 10, 12 or 40 min of normothermic ischemia followed by 40 min of reperfusion. Hearts were then freeze-clamped for further analysis of phosphate metabolites by NMR and ion chromatography. High-energy phosphates, Pi, phosphomonoesters and pH were measured by 31P NMR spectroscopy at 2 minute intervals. Heart rate and developed pressure were monitored simultaneously. All hearts undergoing 10 min of ischemia and 40% of hearts subjected to 12 min of ischemia demonstrated good functional recovery. The remainder of hearts ischemic for 12 min went into contracture on reperfusion with little return of function. Hearts subject to 40 min of ischemia went into ischemic contracture and showed no recovery on reperfusion. Intracellular pH, [ATP], and [Pi] measured prior to reperfusion did not predict the extent of recovery. However, phosphomonoesters were detected prior to reperfusion in all hearts that did not recover well, but were not observed in hearts that showed good mechanical recovery. Analysis of tissue extracts by 31P NMR and ion chromatography indicated that the most prominent components of the phosphomonoesters were glucose 6-phosphate, alpha-glycerol phosphate and AMP. In conclusion, of the various phosphorus metabolites that can be measured by 31P NMR, only one group, the phosphomonoesters, was predictive of functional recovery.
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PMID:Predicting functional recovery from ischemia in the rat myocardium. 148 87

It was examined whether lactate influences postischaemic hemodynamic recovery as a function of the duration of ischaemia and whether changes in high-energy phosphate metabolism under ischaemic and reperfused conditions could be held responsible for impairment of cardiac function. To this end, isolated working rat hearts were perfused with either glucose (11 mM), glucose (11 mM) plus lactate (5 mM) or glucose (11 mM) plus pyruvate (5 mM). The extent of ischaemic injury was varied by changing the intervals of ischaemia, i.e. 15, 30 and 45 min. Perfusion by lactate evoked marked depression of functional recovery after 30 min of ischaemia. Perfusion by pyruvate resulted in marked decline of cardiac function after 45 min of ischaemia, while in glucose perfused hearts hemodynamic performance was still recovered to some extent after 45 min of ischaemia. Hence, lactate accelerates postischaemic hemodynamic impairment compared to glucose and pyruvate. The marked decline in functional recovery of the lactate perfused hearts cannot be ascribed to the extent of degradation of high-energy phosphates during ischaemia as compared to glucose and pyruvate perfused hearts. Glycolytic ATP formation (evaluated by the rate of lactate production) can neither be responsible for loss of cardiac function in the lactate perfused hearts. Moreover, failure of reenergization during reperfusion, the amount of nucleosides and oxypurines lost or the level of high-energy phosphates at the end of reperfusion cannot explain lactate-induced impairment. Alternatively, the accumulation of endogenous lactate may have contributed to ischaemic damage in the lactate perfused hearts after 30 min of ischaemia as it was higher in the lactate than in the glucose or pyruvate perfused hearts. It cannot be excluded that possible beneficial effects of the elevated glycolytic ATP formation during 15 to 30 min of ischaemia in the lactate perfused hearts are counterbalanced by the detrimental effects of lactate accumulation.
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PMID:The nucleotide metabolism in lactate perfused hearts under ischaemic and reperfused conditions. 148 52

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 role of nucleoside uptake in the enhanced metabolic recovery seen with postischemic ATP.MgCl2 was assessed by determining the effect of S-(p-nitrobenzyl)-6-thioinosine (NBTI) on postischemic ATP recovery in rats given normal saline (NS), ATP.MgCl2, or adenosine after 45 min of bilateral renal ischemia. In NS-infused animals, postischemic administration of NBTI (250 nmol) had no significant effect on the pattern of ATP recovery. In animals given 50 mumol ATP.MgCl2, coinfusion of NBTI significantly reduced the renal ATP content 2 h after reperfusion but blocked only one-half of the enhancement in renal ATP content compared with animals given ATP.MgCl2 alone. In animals postischemically infused with [2,5,8-3H]ATP.MgCl2 (50 mumol) there was significant labeling of nucleotides, nucleosides, and bases after 2 h of reperfusion. The specific activity of the adenosine pool was consistent with significant label uptake in the form of adenosine. Coinfusion of NBTI led to a significant reduction in label incorporation into renal ATP and total adenine nucleotide pools. These data are consistent with an important role for an NBTI-sensitive nucleoside uptake mechanism in the enhanced metabolic and functional recovery observed in ischemically injured kidney treated by postischemic infusion of ATP.MgCl2.
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PMID:Role of nucleoside uptake in renal postischemic ATP synthesis. 162 13


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