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Query: UMLS:C0011570 (depression)
 172,036 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

An "endoneurial" preparation from a rabbit tibial nerve fascicle was used to study the ability of peripheral nerve axons and Schwann cells to derive their composite energy requirements from glucose, D-beta-hydroxybutyrate, or albumin-bound palmitate, and the effects of insulin in vitro on their composite glucose utilization. Samples incubated with 5 mM glucose for 2 h maintained a stable O2 uptake and P-creatine and ATP concentrations, and they exhibited a slight increase in P-creatine/creatine ratio (the electron microscopic appearance of the preparation was previously shown to be unaltered under these conditions). The rate of glucose oxidation required to account for the O2 uptake accounted for 61% of the glucose uptake. In samples incubated without substrate for 2 h, a marked fall in tissue glucose was associated with a 50% decrease in O2 uptake and with decreases in P-creatine, ATP, and in the P-creatine/creating ratio. In medium lacking glucose but containing 5 mM DL-beta-hydroxybutyrate, a stable rate of D-beta-hydroxybutyrate uptake was observed, and acetoacetate production accounted for only a small fraction; significant decreases in O2 uptake or ATP were prevented, and, although P-creatinde and the P-creatine/creatine ratio fell, they remained significantly higher than after incubation without substrate. An efficient blood-nerve barrier to albumin is known to exist. Medium containing albumin-bound palmitate with molar ratios or palmitate/albumin of 1 or 2 (highest FFA concentration, 1.32 meq/L) failed to prevent decreases in P-creatine, ATP, and in the P-creatine/creatine ratio during incubations without glucose; the associated O2 uptakes suggested that the tissue is susceptible to respiratory uncoupling and depression son exposure to albumin-blund palmitate as compared with non-neural tissue. Insulin (100 or 1000 microU/ml) had no detectable effects on glucose utilization in the endoneurial preparation during 2-h incubations with 5 mM glucose or (U-14C) glucose. In contrast, in epineurial tissue from rabbit sciatic nerve, insulin (100 micronU/ml) increased (U-14C) glucose incorporation into CO2 and total lipid. The neural components of peripheral nerve are probably dependent on glucose as their major substrate for energy production and respiration under most physiologic conditions in which elevated plasma ketone body concentrations are absent; their composite glucose utilization is not subject to acute, direct regulation by insulin in concentrations that might reasonably be derived from plasma insulin of pancreatic origin.
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PMID:In vitro studies of the substrates for energy production and the effects of insulin on glucose utilization in the neural components of peripheral nerve. 47 82

Metabolite levels were measured in seven brain regions in cats after 15 or 30 minutes of a severe ischemic insult and after a 90-minute period of recirculation following 15 or 30 minutes of ischemia. Brain levels of phosphocreatine were depleted after a 15- or 30-minute insult, and lactate levels were extremely high at both times. The adenosine triphosphate (ATP) content in many brain areas and the presence of microregions of low reduced nicotinamine-adenine dinucleotide in the brains of the animals that had 15 minutes of ischemia suggested that the ischemia, though severe, was not complete. Recirculation following a 15-minute insult restored brain levels of ATP and phosphocreatine to 70 to 100% of control values in all regions analyzed. In contrast, metabolic recovery from a 30-minute insult was regionally heterogeneous. Thus, there was persistent depression of ATP and phosphocreatine and elevation of lactate, which was localized in discrete cortical foci near the longitudinal midline. The factors governing the localization of metabolic failure must have become manifest during the recirculation period since the ischemic insult itself caused similar metabolic perturbations in all cortical regions.
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PMID:Diffuse cerebral ischemia in the cat: II. Regional metabolites during severe ischemia and recirculation. 67 15

Hypotension may be expected to produce less perturbation of metabolism in the brain when cerebral metabolic rate is lowered by deep anesthesia. Male Wistar rats having unilateral carotidartery ligation were exposed to mean arterial pressure (MAP) of 40 torr for 22 min by an intravenous infusion of trimethaphan during anesthesia with halothane, 0.6 or 2 per cent, in oxygen. Cortical tissue metabolite levels on the side of the ligated carotid artery were more abnormal in rats receiving halothane, 0.6 per cent, than in those receiving halothane, 2 per cent. Values at halothane, 0.6 per cent, were adenosine triphosphate (ATP), 1.71 +/- 0.05 (+/-SEM) mumol/g, phosphocreatine (PCr) 1.97 +/- 0.07 mumol/g. and lactate 16.5 +/- 5.1 mumol/g; corresponding values at halothane, 2 per cent, were ATP 2.27 +/- 0.02, PCr 4.02 +/- 0.23, and lactate 4.75 +/- 0.9 mumol/g. ATP and PCr values were significiantly lower (P less than 0.05) and the lactate value was significantly higher with halothane, 0.6 per cent, than with halothane 2 per cent. Cerebral oxygen consumption decreased 47 per cent in rats anesthetized with halothane, 2 per cent. Preservation of cortical metabolite levels in deeply anesthetized animals suggests a protective effect of cerebral metabolic depression.
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PMID:Cerebral energy levels during trimethaphan-induced hypotension in the rat: effects of light versus deep halothane anesthesia. 76 Jun 1

Exposure of resting rat diaphragm for one hour in vitro to halothane (1-1.5, 2-2.5 and 4-4.5 per cent in oxygen) produced significant alterations of intracellular glucose disposition. Glycolysis (as measured by lactate production) increased, while glycogen formation was inhibited in a dose-related fashion. Net glucose uptake was unaffected by the anesthetic except during exposure to 4-4.5 per cent halothane, when 14 per cent depression of uptake was found. Total glycogen content decreased, due mainly to the inhibition of glycogen synthesis and to some extent to a stimulation of glycogenolysis. The anesthetic did not interfere with the effect of insulin on glucose uptake or the intracellular disposition of glucose. Creatine phosphate concentrations decreased following exposure of diaphragm to 1-1.5, 2-2.5 and 4-4.5 per cent halothane, while the adenosine triphosphate concentration declined after exposure to 4-4.5 per cent only. Although the mechanism(s) whereby halothane alters glucose and glycogen metabolism are unknown, it is possible that the anesthetic acts primarily by affecting membranes containing enzymes involved in the metabolism of glycogen.
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PMID:Alteration by halothane of glucose and glycogen metabolism in rat skeletal muscle. 85 Dec 40

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

The ampullar endolymphatic potential (AEP) was studied in the guinea pig during ischemia and asphyxia and following systemic application of ethacrynic acid. In addition the specialized and nonspecialized portions of the ampullar wall were analyzed for ATP and P-creatine at different conditions of metabolic interference. Under control conditions the AEP amounted to + 4.6 +/- 1.2 mV. In both types of hypoxia the decline of the AEP proceeded on a much slower time scale than that of the cochlear endolymphatic potential (CEP), and the maximum negativity reached was considerably less. Quantitative analysis of both types of ampullar wall tissue indicated a much slower decline in hypoxia of ATP levels than in the stria vascularis. Changes in P-creatine levels were considerably more rapid. The AEP became reduced and changed polarity also by intoxication with ethacrynic acid (EA), but higher dosages (above 70 mg/kg) were necessary than for effects upon the CEP and much longer time periods were required for attainment of maximum negativity. The maximum negativity of the AEP was significantly greater at a dosage of 100 mg/kg of EA than during ischemia. At the point of maximum depression of the AEP P-creatine levels in both types of ampullar tissue were unchanged, but ATP levels were significantly reduced in the specialized portions of ampullar wall.
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PMID:Effects of anoxia and ethacrynic acid upon ampullar endolymphatic potential and upon high energy phosphates in ampullar wall. 125 96

The combined effects of inspiratory resistive loaded breathing (IRL) and hypoxemia on transdiaphragmatic pressure (Pdi) in nine 1-mo-old Yorkshire piglets were studied. IRL was adjusted to increase spontaneously generated Pdi five to six times above baseline but maintain arterial PCO2 < 70 Torr to prevent hypercapnic depression of diaphragmatic contractility. Measurements of ventilation, blood gases and pH, Pdi, diaphragmatic electromyogram, Pdi during phrenic nerve stimulation, diaphragmatic blood flow, and end-expiratory lung volume were obtained at baseline, after 2 h of IRL, and then after 1 h of hypoxemia (arterial PO2 approximately 40 Torr) combined with IRL. Diaphragmatic muscle samples were obtained after study completion and immediately frozen in liquid nitrogen for determination of tissue ATP, phosphocreatine, lactate, and glycogen levels. Ten 1-mo-old piglets were subjected to IRL alone and served as controls. IRL alone resulted in significant impairment of Pdi generation. The addition of hypoxemia for 1 h did not further compromise Pdi in comparison to control animals who were subjected to IRL alone. Blood flow to both the costal and crural segments of the diaphragm increased significantly during IRL; the addition of the hypoxemic stress resulted in further significant augmentation of blood flow to both segments of the diaphragm. No differences were noted in diaphragmatic muscle tissue ATP, phosphocreatine, or glycogen between control and IRL animals or between control and IRL plus hypoxemia animals. Muscle lactate levels increased significantly in the IRL plus hypoxemia animals only. The data from this study suggest that moderate hypoxemia during resistive-loaded breathing in the piglet does not accentuate diaphragmatic fatigue.
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PMID:Effect of inspiratory resistive loaded breathing and hypoxemia on diaphragmatic function in the piglet. 147 65

Brief episodes of myocardial ischemia are known to cause reversible depression of regional myocardial contraction after reperfusion. One of the mechanisms of this persistent regional dysfunction has been proposed to be depletion of high-energy phosphate compounds. Eight cats were prepared with a reversible snare occluder around the left anterior descending artery (LAD); a surface coil sutured to the epicardial surface over the LAD territory for measurement of 31-phosphorus (31P) magnetic resonance spectroscopy (MRS) spectra; and a pair of ultrasonic crystals implanted in the mid-myocardium for measurement of regional segment length shortening. The baseline value of percent segment length shortening (%SS) was 12.8 +/- 1.4%. Increased afterload did not significantly alter high-energy phosphate levels or %SS. All animals exhibited passive systolic bulging during occlusion (-8.4 +/- 3.6% systolic shortening) as well as reduced phosphocreatine (PRc, 30 +/- 3% of control) and increased inorganic phosphorus (Pi) (239 +/- 18%), but there was no change in adenosine triphosphate (ATP). During reflow, %SS did not completely recover (4.0 +/- 2.9%, P less than .05 versus baseline). PCr and Pi returned to control levels during the first 30 minutes of reperfusion. Increased afterload had no significant effect on high-energy phosphates or %SS in stunned hearts. These findings indicate a lack of correlation between recovery of high-energy phosphate stores and regional myocardial contractility in stunned myocardium. High-energy phosphate reserves are preserved in stunned myocardium and are unlikely to be a direct cause of myocardial dysfunction.
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PMID:Preservation of high-energy phosphate reserves in a cat model of post-ischemic myocardial dysfunction. 160 6

The hippocampus exhibits a post-ictal phenomenon in which it is unresponsive to further stimulation. It has been suggested that this loss of excitability is the basis of post-seizure amnesia. The biochemical events associated with this phenomenon are unclear. In the present study, energy metabolites were measured in the stratum oriens, stratum pyramidale and stratum radiatum in rat hippocampus, and correlated with field potential recordings. Wistar rats were anesthetized and the calvarium removed. Following removal of the cortex by aspiration, the hippocampus was covered with oil, and stimulating and recording electrodes were placed. Stimulation consisted of a train of stimuli at 100 Hz (10-20 m Amps). This stimulation was found to be effective in evoking self-sustaining after-discharges and post-ictal depression. Tissues for metabolite analysis were taken from a series of controls, from animals during active self-sustaining seizures, and from animals which were totally unresponsive to further electrical stimulation. Hippocampal tissue for metabolite analysis was obtained by pouring liquid N2 on the exposed tissue, then removing the frozen tissue. Glucose, ATP, and phosphocreatine were measured in hippocampal layers of CA1 using fluorescence techniques and enzymatic cycling. Results showed that during seizure activity, glucose, ATP, and phosphocreatine were all decreased from 40-80% in the three layers of the hippocampus, whereas from 60 seconds after the onset of hippocampal shutdown, energy metabolites had returned toward normal. Thus, at a time when the hippocampus was unresponsive, energy metabolites were at control levels. These data suggest that the shutdown phenomenon occurs in the presence of adequate energy stores.
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PMID:Energy metabolism in rat hippocampus during and following seizure activity. 174 67

Freezing lesions have been shown to cause a depression in glucose use, particularly in cortical areas of the brain ipsilateral to the lesion, and this effect was interpreted to be caused by a depressed functional activity in these regions. The metabolic status of the affected areas has not been previously examined and could be a factor in the observed changes in local CMRglc. In frozen-cut and dried sections taken from brains 3 days after freeze lesioning, discrete pieces of the median and lateral parietal cortex, striatum, hippocampus, and hypothalamus were dissected and analyzed for ATP, P-creatine, glucose, and lactate. CMRglc measurements were also made in the same animals. The concentrations of the four metabolites were significantly increased in the lesioned hemisphere, with the most predominant effects observed in the cortical areas that exhibited the greatest depression in CMRglc. The enriched metabolite profile, particularly in the cortical areas, is consistent with the hypothesis that decreased glucose use in the traumatized brain is caused by diminished need rather than by decreased supply of energy. Because the lumped constant in the operational equation of the deoxyglucose method for determination of CMRglc is a function of brain glucose content and decreases gradually in hyperglycemia, the degree of metabolic depression in cortical areas of lesioned hemisphere probably have been somewhat overestimated in this and previous publications. However, provisionally recalculated local CMRglc in the lesioned hemisphere remain significantly lower than in the contralateral hemisphere and in the normal brain.
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PMID:Effects of focal cortical freezing lesion on regional energy metabolism. 187 17


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