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Query: UMLS:C0022116 (ischemia)
91,303 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Numerous laboratories have shown that hyperglycemia increases cerebral ischemic damage. This presumably results from increased lactate production and accumulation during ischemia. Although increased tissue lactic acidosis is associated with increased ischemic brain damage, this damage has not been directly linked to glycolytic flux. Because 2-deoxyglucose (2-DG) is a competitive inhibitor of glycolysis we tested its ability to reduce hyperglycemia-exacerbated ischemic brain damage. Severe forebrain ischemia was produced by the four-vessel occlusion model in rats. Four rats received 3 g/kg glucose and saline while a second group (n = 5) was injected with 3 g/kg glucose plus 1.6 g/kg 2-DG. A third group (n = 5) was treated with 1 g/kg glucose plus saline and a fourth group (n = 5) received 1 g/kg glucose and 1.6 g/kg 2-DG. All rats were injected i.p. 10 minutes prior to the ischemic insult with the same volume/kg body weight. All rats receiving the high dose of glucose alone (3 g/kg) were dead within 24 hours postischemia. Rats who received 2-DG in addition to 3 g/kg glucose showed only 40% mortality (p = 0.119 Fisher's Exact). 2-DG completely eliminated convulsions during the initial two hours of recovery which was significant (p = 0.008), however, all rats in both groups showed some convulsions by 24 hours postischemia. Among rats receiving the low glucose dose (1 g/kg), none of the rats receiving 2-DG died or convulsed by 24 hours postischemia.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Glycolytic inhibition by 2-deoxyglucose reduces hyperglycemia-associated mortality and morbidity in the ischemic rat. 376 73

The time course of structural change in epilepsy-induced necrosis of the substantia nigra was studied by light and electron microscopy, and was correlated with previous metabolic studies. By light microscopy, tinctorial pallor appeared early, followed by pan-necrosis and macrophage infiltration. Mild lesions showed neuropil vacuolation but sparing of neurons, rather than a selective neuronal vulnerability. Electron microscopy of the evolving necrosis revealed an orderly sequence of structural damage involving first axons, then dendrites, neurons, and glia. No necrotic endothelial cells could be found, even in areas of apparent pan-necrosis by light microscopy. Pericytes near the vascular lumen were spared, whereas those in outer locations were necrotic. Edema, measured densitometrically, was absent. Previous metabolic studies of this lesion have demonstrated a pronounced focal lactic acidosis due to anaerobic hypermetabolism. Although the lesions resemble infarcts, hypermia rather than ischemia has been shown to accompany their development. Structural preservation of endothelial cells and inner pericytes likely stems from proximity to the moving blood stream, away from the site of lactic acid production in the neuropil. The findings indicate that the perfusion of necrotic tissue occurs via a persisting, intact microcirculation. The relative neuronal sparing and the early axonal rather than dendritic lesion show a clear distinction from excitotoxic pathology.
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PMID:Early axonal lesion and preserved microvasculature in epilepsy-induced hypermetabolic necrosis of the substantia nigra. 379 37

Excessive tissue lactic acidosis is considered to be detrimental to the central nervous system (CNS) and may adversely affect recovery from anoxia, ischemia, trauma and epilepsy. Since astrocytes are believed to play a role in pH regulation in the CNS, we studied the effect of this acid on primary astrocyte cultures. Cells exposed to lactic acid showed chromatin clumping, an increase of lipid and dense bodies, a loss of polyribosomal clusters, slightly increased cytoplasmic lucency, swollen mitochondria and tangled intermediate filaments. These alterations progressed with lower pH and longer exposure. Irreversible changes occurred one to two hours after exposure at pH 6; after 30 to 60 minutes (min) at pH 5.5 and after ten to 30 min at pH 5. Comparable results were obtained with the use of other weak acids indicating that the observed changes were due to increased hydrogen ion concentration rather than secondary to lactate per se. Additionally, various concentrations of lactic acid adjusted to identical pH produced similar morphologic alterations. Thus, while lactic acid caused marked and at times irreversible alterations in astrocytes, severe and prolonged acidosis was required to produce such injurious effects. This relative resistance of astrocytes to acidosis is in keeping with their potential role in pH regulation in brain.
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PMID:Effects of lactic acid on astrocytes in primary culture. 381 73

The study describes a reproducible model of complete brain ischemia in rats. Rats with different plasma glucose concentrations were exposed to 10 min of complete cerebral ischemia achieved by compression of neck vessels by a pneumatic cuff. All 30 rats, except one, in which pre-ischemic plasma glucose level were lower than 22 mM (range 1.6-22) survived 10 min complete ischemia and made a similar recovery. Ten rats with pre-ischemic plasma glucose levels above 22 mM (range 22-47.2) died from seizures in the post-ischemic period. Post-ischemic treatment of seizures and hyperglycemia in the hyperglycemic rats significantly improved recovery. In conclusion, pre-ischemic hyperglycemia above 22 mM impairs recovery after complete ischemia by inducing seizures, post-ischemic hyperglycemia and lactic acidosis.
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PMID:The effect of glucose upon restitution after transient cerebral ischemia: a summary. 389 8

Brain tissue acidosis is a result of either an increase in tissue PCO2 or an accumulation of acids produced by metabolism. Severe hypercapnia (arterial PCO2 around 300 mm Hg) may cause a fall in tissue pH to around 6.6 without any deterioration of the cerebral energy state or morphologic evidence of irreversible cell damage. In severe ischemia and tissue hypoxia, anaerobic glycolysis leads to lactic acid accumulation. This is aggravated by hyperglycemia and by a (trickling) residual blood flow. Under such circumstances lactate concentration in the tissue may increase to levels above 20 to 25 mumol/g (tissue wet weight), causing a decrease in pH to around 6.0. If lactic acidosis during ischemia or hypoxia reaches these excessive levels, metabolic and functional restitution is severely hampered upon subsequent recirculation and reoxygenation. In these circumstances cell morphology shows signs of irreversible damage. Conversely there is less damage if severe tissue lactic acidosis can be hindered. The deleterious effect of excessive lactic acidosis may be related to an influence on the following: synthesis and degradation of cellular constituents; mitochondrial function; cell volume control; postischemic blood flow; and stimulation of pathologic free radical reactions. Possibilities for therapeutic interventions include the avoidance of hyperglycemia, inhibition of glycolysis, and measures for increasing the buffer capacity of the brain.
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PMID:Brain acidosis. 392 94

Cerebral ischemic insult is one of the most clinically significant conditions leading to irreversible brain cell damage and death. Animal studies have suggested that lowered intracellular pH due to the severe brain lactic acidosis following ischemia interferes with normal cell structure and function and leads to brain cell necrosis. Therefore, efforts directed to decreasing brain lactate may be beneficial in preventing brain cell damage and death. The goal of our study was to evaluate the effectiveness of postinsult treatment with dichloroacetate (DCA) in controlling increases in brain lactate following partial global ischemia (PGI) in rats. PGI was induced by bilateral carotid artery occlusion and induced hypotension. Animals that received DCA immediately after a 30-minute ischemic insult (n = 5) or 15 minutes after the end of an ischemic insult (n = 5) had cortical lactate levels that were significantly lower (P less than .005) than lactate levels in untreated insulted animals and that were not significantly different than those previously obtained with preinsult DCA treatment in rats subjected to 30 minutes of PGI. Treatment of rats with DCA following PGI may be effective in reducing cortical lactate levels and hence may limit irreversible damage to brain cells following cerebral ischemia.
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PMID:Postinsult treatment of ischemia-induced cerebral lactic acidosis in the rat. 395 71

Regional cerebral blood flow (rCBF), cerebral metabolic rate of oxygen (CMRO2), intraventricular pressure, and lactate/pH levels in the cerebrospinal fluid (CSF) were measured in 38 patients with ruptured intracranial aneurysms between the 3rd and 13th day after subarachnoid hemorrhage (SAH). Angiography was performed following the rCBF study and the degree of vasospasm was measured on the angiograms. The patients were graded clinically according to the system of Hunt and Hess. Cerebral vasospasm significantly influenced rCBF: global reductions and focal changes (ischemia, hyperemia, and tissue peaks) were commonly associated with vasospasm. Patients with severe diffuse spasm always had global ischemia (21 +/- 5 ml/100 gm/min), and cerebral infarctions were demonstrated subsequently, The CMRO2 was more reduced than rCBF, indicating an uncoupling between flow and metabolism. This relative luxury perfusion was associated with CSF lactic acidosis and intracranial hypertension. The arteriovenous difference of oxygen was equally reduced in all categories of patients, probably due to the primary insult of SAH. The CMRO2 decreased concomitantly with arterial caliber, indicating a secondary impairment of cerebral metabolism due to vasospasm.
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PMID:Regional CBF, intraventricular pressure, and cerebral metabolism in patients with ruptured intracranial aneurysms. 396 55

The recovery of the EEG and somatosensory evoked responses (SER) as compared with recovery of the cerebral energy state was studied in rats during recirculation following different degrees of brain ischemia with varying tissue lactic acidosis. Reversible complete and incomplete ischemia was induced either by increasing the intracranial pressure (compression ischemia) or by carotid artery clamping combined with arterial hypotension. In incomplete ischemia the degree of tissue lactic acidosis was varied by manipulations of blood and brain glucose levels. Animals with an increase in brain lactate to about 25 mumol X g-1 (whole brain wet weight) during ischemia showed persistent failure of both cerebral energy metabolism and neurophysiologic restitution during the recirculation phase; if less than 20 mumol X g-1 metabolic recovery was almost complete. Despite a similar restitution of tissue energy metabolism in these animals, neurophysiologic recovery was inversely proportional to brain lactate concentrations during ischemia. At similar levels of ischemic tissue lactic acidosis, and despite a similar recovery of cortical energy state, the neurophysiologic restitution was clearly inferior after complete ischemia to that following incomplete ischemia. Three conclusions were drawn: (i) neurophysiologic variables were more sensitive indicators of postischemic persistent cerebral dysfunction than the cerebral energy state; (ii) the degree to which lactate accumulated in the ischemic brain influenced neurophysiologic restitution even if concentrations critical for metabolic recovery were not attained; and (iii) incomplete ischemia was less harmful than complete ischemia provided that tissue lactic acidosis was not excessive.
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PMID:Effect of different degrees of brain ischemia and tissue lactic acidosis on the short-term recovery of neurophysiologic and metabolic variables. 397 49

The effect of different degrees of lactic acidosis on the recovery of brain mitochondrial function, measured as respiratory activity in isolated mitochondria or cortical concentrations of labile phosphates and carbohydrate substrates, was studied during 30 min of recirculation following 15 min of near-complete forebrain ischemia in rats. During ischemia, there was a marked decrease in mitochondrial State 3 respiration in vitro and a depletion of energy stores (i.e., phosphocreatine, ATP, glucose, and glycogen) in vivo that was similar in the high- and low-lactate ischemia groups. However, lactate concentrations differed markedly (20 and 10 mumol g-1, respectively). During recirculation, there was a near-complete recovery of both respiratory activity in vitro and adenylate energy charge (EC) in vivo regardless of the differences in lactic acidosis during ischemia. Respiratory activity and EC were well correlated. The changes in Ca2+ homeostasis during ischemia, an increase in tissue and a decrease in mitochondrial Ca2+ content, were reversed rapidly after ischemia in both high- and low-lactate ischemia animals and did not hinder an early recovery of mitochondrial function. It is concluded that lactic acidosis, with lactate levels reaching 20 mumol g-1 during 15-min ischemia, does not adversely affect early postischemic recovery of mitochondrial function.
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PMID:Lactic acidosis and recovery of mitochondrial function following forebrain ischemia in the rat. 398 25

Levels of energy metabolites were measured in forebrain regions in fasted rats subjected to 4-h recirculation after 1 h of either incomplete or complete ischemia. Both models of ischemia were produced by a procedure combining bilateral common carotid artery occlusion, systemic hypotension, and CSF pressure elevation; the degree of intracranial hypertension was varied to produce incomplete and complete ischemia. Levels of brain lactate at the end of ischemia ranged from 16 to 19 mmol/kg in incomplete ischemia and from 11 to 13 mmol/kg in complete ischemia. Energy metabolism recovered evenly in the neocortical and subcortical regions with recirculation after incomplete ischemia. The metabolic recovery in the cerebral cortex after complete ischemia was similar to that observed after incomplete ischemia; however, recovery in the subcortical regions after complete ischemia was less extensive, NADH fluorescence remained high, and there was a fall in total creatine. Intracellular pH in the dorsal thalamus was more alkalotic after complete than incomplete ischemia. Thus, in the absence of profound tissue lactic acidosis, residual CBF during prolonged ischemia helps postischemic restitution of brain energy metabolism in subcortical regions. The pattern of poor recovery in these regions after complete ischemia suggests inadequate reperfusion. The decreased total creatine and the severe tissue alkalosis may be biochemical markers of advanced tissue injury during reflow.
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PMID:Regional brain energy metabolism after complete versus incomplete ischemia in the rat in the absence of severe lactic acidosis. 405 23


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