Bibliothek

Notizen: Abstract: Marked abnormalities of the magnetic resonance intensity of N-acetylaspartate (NAA) have been reported in patients with various neurological disorders, but the neurochemical consequences of these alterations are difficult to assess because the function of NAA remains speculative. The purpose of this study was to examine whether NAA plays a role in protecting neurons against osmotic stress. Intracerebral microdialysis was used to expose a small region of the rat dorsolateral striatum to an increasingly hyposmotic environment and to measure resulting changes in NAA extracellular concentrations. NAA changes in the extracellular fluid (ECF) were compared with those of the amino acids, in particular, taurine, known to be involved in brain osmoregulation. Stepped increases in cellular hydration produced by hyposmotic perfusion media induced a marked increase in ECF NAA, reflecting a redistribution of NAA from intra-to extracellular space. Parallel experiments showed that, of all the extracellular amino acids measured, only taurine markedly increased with hyposmolar perfusion medium, indicating that the ECF NAA increase associated with hyposmotic stress was a specific response and not passive leakage out of the cells. As NAA is predominantly neuronal, it may contribute to the protection of neurons against swelling (i.e., regulatory volume decrease). In conditions with impaired blood-brain barrier and cytotoxic oedema, efflux of intracellular NAA subsequent to sustained cellular swelling might lead to a reduction in total brain NAA detectable by magnetic resonance spectroscopy. Alternatively, redistribution of NAA from intra-to extracellular space implies changes in its chemical environment that may alter its magnetic resonance visibility.

Notizen: Abstract: The time course of changes in extracellular glutamic acid levels and their Ca2+ dependency were studied in the rat striatum during focal cerebral ischaemia, using microdialysis. Ischaemia-induced changes were compared with those produced by high K+-evoked local depolarization. To optimize time resolution, glutamate was analysed continuously as the dialysate emerged from the microdialysis probe by either enzyme fluorimetry or biosensor. The Ca2+ dependency of glutamate changes was examined by perfusing the probe with Ca2+-free medium. With normal artificial CSF, ischaemia produced a biphasic increase in extracellular glutamate, which started from the onset of ischaemia. During the first phase lasting ∼10 min, dialysate glutamate level increased from 5.8 ± 0.9 µM· min−1 to 35.8 ± 6.2 µM where it stabilized for ∼3 min. During the second phase dialysate glutamate increased progressively to its maximum (82 ± 8 µM), reached after 55 min of ischaemia, where it remained for as long as it was recorded (3 h). The overall changes in extracellular glutamate were similar when Ca2+ was omitted from the perfusion medium, except that the first phase was no longer detectable and, early in ischaemia, extracellular glutamate increased at a significantly slower rate than in the control group (2.2 ± 1 µM· min−1; p 〈 0.05). On the basis of these data, we propose that most of the glutamate released in the extracellular space in severe ischaemia is of metabolic origin, probably originating from both neurons and glia, and caused by altered glutamate uptake mechanisms. Comparison with high K+-induced glutamate release did not suggest that glutamate “exocytosis,” early after middle cerebral artery occlusion, was markedly limited by deficient ATP levels.

Notizen: Abstract: The purpose of this study was to determine the extracellular concentrations of N-acetylaspartate (NAA) in the rat cerebral cortex, striatum, and hippocampus of halo-thane-anaesthetised rats by intracerebral microdialysis, and to examine the effects of high K+-induced local depolarisation, which provokes synchronous neurotransmitter release, cell swelling, and acid-base changes. Basal levels of NAA in the extracellular fluid (EOF) were determined by the zero net flux method. Tissue levels of NAA in the cortex, striatum, and hippocampus were 8.4, 5.7, and 7.2 mmol/kg, respectively. The corresponding extracellular concentrations of NAA were much lower (35.1, 83.7, and 23.0 tiM). High tissue/ECF concentration ratios may suggest little release or leakage of NAA under basal conditions, and potent reuptake mechanisms for NAA in the cellular membrane of CNS cells. There was no change in ECF NAA during K+-induced local depolarising stimuli produced in the striatum, but NAA levels consistently increased after the K+ stimuli, irrespective of whether or not Ca2+ was present in the perfusion medium. These data confirm that NAA is not a neurotransmitter and suggest strongly that NAA is not directly involved in the release and reuptake or metabolism of neuroactive compounds. The increase of NAA in the ECF immediately after K+ stimulation may reflect an involvement in brain osmoregulation and/or acid-base homeostasis.

Notizen: Abstract: Changes in the extracellular levels of excitatory and inhibitory amino acid transmitters were studied in the rat striatum during penumbral ischaemia using intracerebral microdialysis. Effects of penumbral forebrain ischaemia were compared with those of ischaemia with sustained anoxic depolarisation and K+ (100 mM). Comparisons were also made between different groups of animals at 2 and 24 h after dialysis probe implantation. The K+ stimulus did not provoke any release of excitatory amino acids in the 24-h group, probably reflecting a decrease of functional synapses adjacent to the probe. During 30 min of penumbral ischaemia, excitatory amino acids did not reach critical concentrations in the extracellular fluid, and increases in levels of inhibitory/modulatory amino acids were similar. On the other hand, severe transient ischaemia resulted in massive synchronous release of many neuroactive excitatory and inhibitory compounds, in both the 2- and 24-h groups. These and other data suggest that changes during severe ischaemia may arise from both neurotransmitter and metabolic pools. It is concluded that is- chaemic damage in the penumbra may not be related to extracellular neuroactive amino acid changes generated within this region.

Notizen: Abstract: Severe cerebral ischaemia has been repeatedly shown to provoke a massive increase in striatal extracellular dopamine (DA). These experiments were undertaken to determine the duration of the DA increase produced by transient ischaemia, and the fate of the released DA during recirculation. Experiments were performed in anaesthetised rats subjected to 20 min of cerebral ischaemia, followed by 80 min of reperfusion, before cardiac arrest. Measurements of catechols were made in the striatum using in vivo differential pulse voltammetry (DPV), each 4 min, throughout the experiment and for 60 min after cardiac arrest. DPV data were substantiated with intracerebral dialysis; 20-min dialysate samples were analysed for DA and homovanillic acid (HVA) using HPLC. In 6 of 11 rats, ischaemia induced a massive DA release in the striatum, resulting in a marked increase in extracellular levels (350–1,200%), which persisted throughout ischaemia. DPV and intracerebral dialysis demonstrated that DA was totally cleared from the extracellular space within minutes of reperfusion, whereas both its acidic metabolites (3,4-dihydroxyphenylacetic acid and HVA) increased slightly. These results indicate that DA released during 20-min ischaemia is rapidly cleared during reperfusion, mainly via reuptake. In the five other rats, only a relatively small and transient increase in the DPV catechol peak was detectable, cleared before the end of ischaemia, probably reflecting less severe ischaemia; small or no changes were detectable in the corresponding dialysate. The latter data suggest that different change(s) in the nigrostriatal dopaminergic system may occur, according to the severity of ischaemia.

Notizen: Abstract: In the cerebral cortices of rats, during insulininduced hypoglycemia, changes in the concentrations of labile phosphate compounds [ATP, ADP, AMP, and phosphocreatine (PCr)] and glycolytic metabolites (lactate, pyruvate, and glucose) as well as phospholipids and free fatty acids (FFAs) were studied in relation to extracellular potassium and calcium activities. Changes in extracellular calcium and potassium activities occurred at approximately the onset of isoelectricity. The extracellular calcium activity dropped from 1.17 ± 0.14 mM to 0.18 ± 0.28 mM and the potassium activity rose from 3.4 ± 0.94 mM to 48 ± 12 mM (means ± SD). Minutes prior to this ionic change the levels of ATP, PCr, and phospholipids were unchanged while the levels of FFAs remained unchanged or slightly elevated. Following the first ionic change the steady-state levels of ATP decreased by 40%, from 2.42 to 1.56 μmol/g. PCr levels decreased by 75%, from 4.58 to 1.26 μmol/g. Simultaneously, the levels of FFAs increased from 338 to 642 nmol/g, arachidonic acid displaying the largest relative increase, 33 to 130 nmol/g. The first ionic change was followed by a short period of normalization of ionic concentrations followed by a sustained ionic change. This was accompanied by a small additional decrease in ATP (to 1.26 μmol/g). The FEA levels increased to 704 nmol/g. There was a highly sig nificant negative correlation between the levels of FFAs and the energy charge of the tissue. The formation of FFAs was accompanied by a decrease in the phospholipid pool. The largest relative decrease was observed in the inositol phosphoglycerides, followed by serine and ethanolamine phosphoglycerides. After 10 min of isoelectricity the levels of phospholipids had decreased by 5.12 μmol/g while the levels of FFAs had increased by 0.46 μmol/g, indicating oxidative metabolism or washout of the released FFAs. The attenuation of the rapid initial changes in the levels of the energy metabolites and FFAs as well as the correlation between the energy charge and the levels of FFAs suggests that a new steady state is established following the first ionic change. The importance of these reactions for the development of hypogiycemic neuronal damage is discussed.