Investigation into the Role of N-Acetylaspartate in Cerebral Osmoregulation

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.     

Transient Elevation of Interstitial N-Acetylaspartate in Reversible Global Brain Ischemia

Abstract: We evaluated the changes of interstitial N -acetylaspartate (NAA) concentration ([NAA]_e) in rat striatum by microdialysis following transient global ischemia and depolarization. The dialysate NAA concentration ([NAA]_d) values were corrected for the in vivo recovery to obtain [NAA]_e, by the use of [³H]mannitol in the perfusion fluid. During global ischemia the relative loss (RL) of [³H]mannitol decreased to 40% of preischemic values, reflecting the decrease in extracellular volume fraction. During reperfusion RL of [³H]mannitol quickly normalized. The [NAA]_d doubled during transient ischemia, which, after correction for in vivo recovery, corresponds to a fivefold increase in [NAA]_e ( p < 0.05). Reperfusion induced a >10-fold increase of [NAA]_e ( p < 0.01) with subsequent normalization after 45 min. KCI at 100 m M caused a reversible 50% reduction in RL of [³H]mannitol and a three times increase in [NAA]_e ( p < 0.05) but no further increase when normal perfusate was reintroduced. The mechanisms of NAA release from neurons are unknown but may involve the activation of unknown channels/carriers—possibly in relation to a volume regulatory response. The present study shows that the distribution of NAA in brain is dynamically regulated in acute ischemia and suggests that changes of NAA levels could be caused by other means than neuronal loss.     

Extracellular N-Acetylaspartate in the Rat Brain: In Vivo Determination of Basal Levels and Changes Evoked by High K+

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.     

Effects of Methylprednisolone on Extracellular Lactic Acidosis and Amino Acids After Severe Compression Injury of Rat Spinal Cord

Abstract: We evaluated in rats with severe spinal cord compression at T8–9 the influence of methylprednisolone (MP) on lactic acidosis and extracellular amino acids, which may cause secondary, perifocal injuries of the cord. MP (30 mg/kg) was given intravenously 30 min before compression and hourly thereafter (15 mg/kg). Other rats with compression, given saline, served as controls. Samples from the extracellular fluid of one dorsal horn were collected by microdialysis and analyzed by HPLC. Microdialysis was performed for 1.5 h to establish basal levels. Samples were collected for 3 h after compression. MP-treated rats showed a reduction of dialysate lactic acid and arginine levels during the first 1–2 h after trauma. The mean dialysate levels of glutamate in MP-treated rats were lower than those of the controls, but the difference was not statistically significant. MP treatment did not influence dialysate levels of aspartate, glutamine, histidine, glycine, threonine, taurine, alanine, GABA, and tyrosine. Our study shows that MP has several effects, including reduced lactic acid formation, reduced levels of arginine (the substrate for nitric oxide production), and a trend toward decreased extracellular accumulation of the excitotoxic amino acid glutamate. We conclude that MP has the capacity to change the composition of the extracellular edema fluid after trauma to the spinal cord. These changes may counteract free radical formation and may be important mechanisms by which MP exerts its beneficial actions.     

In Vivo Microdialysis of 2-Deoxyglucose 6-Phosphate into Brain

Abstract : A unique method for simultaneously measuring interstitial (pH_e) as well as intracellular (pH_i) pH in the brains of lightly anesthetized rats is described. A 4-mm microdialysis probe was inserted acutely into the right frontal lobe in the center of the area sampled by a surface coil tuned for the collection of ³¹P-NMR spectra. 2-Deoxyglucose 6-phosphate (2-DG-6-P) was microdialyzed into the rat until a single NMR peak was detected in the phosphomonoester region of the ³¹P spectrum. pH_e and pH_i values were calculated from the chemical shift of 2-DG-6-P and inorganic phosphate, respectively, relative to the phosphocreatine peak. The average in vivo pH_e was 7.24 ± 0.01, whereas the average pH_i was 7.05 ± 0.01 (n = 7). The average pH_e value and the average CSF bicarbonate value (23.5 ± 0.1 mEq/L) were used to calculate an interstitial Pco₂ of 55 mm Hg. Rats were then subjected to a 15-min period of either hypercapnia, by addition of CO₂ (2.5, 5, or 10%) to the ventilator gases, or hypocapnia (Pco₂ < 30 mm Hg), by increasing the ventilation rate and volume. pH_e responded inversely to arterial Pco₂ and was well described (r² = 0.91) by the Henderson-Hassel-balch equation, assuming a pK_a for the bicarbonate buffer system of 6.1 and a solubility coefficient for CO₂ of 0.031. This confirms the view that the bicarbonate buffer system is dominant in the interstitial space. pH_i responded inversely and linearly to arterial Pco₂. The intracellular effect was muted as compared with pH_e (slope = -0.0025, r² = 0.60). pH_e and pH_i values were also monitored during the first 12 min of ischemia produced by cardiac arrest. pH_e decreases more rapidly than pH_i during the first 5 min of ischemia. After 12 min of ischemia, pH_e and pH_i values were not significantly different (6.44 ± 0.02 and 6.44 ± 0.03, respectively). The limitations, advantages, and future uses of the combined microdialysis/³¹P-NMR method for measurement of pH_e and pH_i are discussed.     

Time Course of Changes in Extracellular Lactate Evoked by Transient K+-Induced Depolarisation in the Rat Striatum

Abstract: The purpose of this study was to establish whether excessive lactate production associated with local application of K⁺ is reflected at the extracellular level during or after the K⁺ challenge. Changes in extracellular lactate were continuously monitored by microdialysis coupled to on-line fluorimetric analysis. K⁺-induced changes in dialysate lactate were closely related to those of the direct current potential. High K⁺ evoked a large and sustained negative shift of direct current potential onto which were superimposed a variable number of transient peaks of further depolarisation. The initial negative shift in direct current potential was associated with a decrease in dialysate lactate, but after each transient depolarisation, the positive shift in direct current potential indicating cell repolarisation was associated with a marked increase in extracellular lactate. When repetitive transient depolarisations occurred during a stimulus, only a small increase after each depolarisation was observed. However, recordings consistently revealed a marked and rapid increase in extracellular lactate after the K⁺ stimulus. These data indicate that extracellular lactate mostly increased during periods of repolarisation. This suggests strongly that lactic acid transport out of brain cells may be impaired when their transmembrane ionic gradients are disrupted.     

Hypoosmolarity Induces an Increase of Extracellular N-Acetylaspartate Concentration in the Rat Striatum

We previously showed that extracellular levels of N-acetylaspartate (NAA) increase when a medium with reduced NaCl concentration is perfused through a microdialysis probe, and proposed that NAA may be released during hypoosmotic swelling. Here, we demonstrate that this effect is due to hypoosmolarity of the perfusion medium, and not to low NaCl. NAA changes in the dialysate were compared with those of taurine as the osmoregulatory role of this amino acid is established. Reduction of the NaCl concentration in the perfusion medium increased the dialysate levels of NAA and taurine, but this effect was abolished when NaCl was replaced by sucrose to maintain isosmolarity. The NAA response to hypoosmolarity was smaller than that of taurine, but it may still be important to neurons as NAA is predominantly neuronal in the mammalian CNS.     

One-Line Monitoring of Extracellular Brain Glucose Using Microdialysis and a NADPH-Linked Enzymatic Assay

A method to monitor extracellular glucose in freely moving rats, based on intracerebral microdialysis coupled to an enzyme reactor is described. The dialysate is continuously mixed with a solution containing the enzymes hexokinase and glucose-6-phosphate dehydrogenase, and the fluorescence of NADPH formed enables the on-line registration of extracellular glucose. The method is applied to monitor changes in extracellular brain glucose during the infusion of glucose, electrically induced seizure, immobilization stress, and repetitive hypoxia. After glucose loading or after seizure, hippocampus dialysate glucose concentration was increased transiently. During immobilization, there was a short-lasting decrease and, thereafter, an increase in the extracellular hippocampus glucose. During repetitive hypoxia in rats with a unilaterally occluded carotid artery, the content of glucose of striatal dialysates followed closely changes in blood pressure. These results illustrate the usefulness of the method in studying changes in brain glucose concentrations under pathological and physiological conditions.     

NMR-Based Identification of Intra- and Extracellular Compartments of the Brain Pi Peak

Abstract: The P_i peak in a ³¹P NMR spectrum of the brain can be deconvoluted into six separate Lorentzian peaks with the same linewidth as that of the phosphocreatine peak in the spectrum. In an earlier communication we showed that the six P_i peaks in normal brain represent two extracellular and four intracellular compartments. In that report we have identified the first of the extracellular peaks by marking plasma with infused P_i, thereby substantially increasing the amplitude of the single peak at pH 7.35. 2-Deoxyglucose-6-phosphate (2-DG-6-P) was placed in the brain interstitial space by microdialysis. The resulting 2-DG-6-P peak was deconvoluted into three separate peaks. The chemical shift of the principle 2-DG-6-P peak gave a calculated pH of 7.24 ± 0.02 for interstitial fluid pH, a value that agreed well with the pH of the second extracellular P_i peak at pH 7.25 ± 0.01. We identified the intracellular compartments by selectively stressing cellular energy metabolism in three of the four intracellular spaces. A seizure-producing chemical, flurothyl, was used to activate the neuron, thereby causing a demand for energy that could not be completely met by oxidative phosphorylation alone. The resulting loss of high-energy phosphate reserves caused a significant increase in intracellular P_i only in those cells associated with the P_i peak at pH 6.95 ± 0.01. This suggests that this compartment represents the neuron. Ammonia is detoxified in the astrocyte (glutamine synthetase) by incorporating it into glutamine, a process that requires large amounts of glucose and ATP. The intraarterial infusion of ammonium acetate into the brain stressed astrocyte energy metabolism resulting in an increase in the P_i of the cells at pH of 7.05 ± 0.01 and 7.15 ± 0.02. This finding, coupled with our observation that these same cells take up infused P_i probably via the astrocyte end-foot processes, lead us to conclude that these two compartments represent two different types of astrocytes, probably protoplasmic and fibrous, respectively. As a result of this study, we now believe the brain contains four extracellular and four intracellular compartments.     

Extracellular Glucose Concentrations in the Rat Hippocampus Measured by Zero-Net-Flux

Abstract : The concentration of glucose in the brain's extracellular fluid remains controversial, with recent estimates and measurements ranging from 0.35 to 3.3 m M . In the present experiments, we used the method of zero-net-flux microdialysis to determine glucose concentration in the hippocampal extracellular fluid of awake, freely moving rats. In addition, the point of zero-net-flux was measured across variations in flow rate to confirm that the results for glucose measurement were robust to such variations. In 3-month-old male Sprague-Dawley rats, the concentration of glucose in the hippocampal extracellular fluid was found to be 1.00 ± 0.05 m M , which did not vary with changes in flow rate. Three-month-old and 24-month-old Fischer-344 rats both showed a significantly higher hippocampal extracellular fluid glucose concentration, at 1.24 ± 0.07 and 1.21 ± 0.04 m M , respectively ; there was no significant difference between the two age groups. The present data demonstrate variation in extracellular brain glucose concentration between rat strains. When taken together with previous data showing a striatal extracellular glucose concentration on the order of 0.5 m M , the data also demonstrate variation in extracellular glucose between brain regions. Traditional models of brain glucose transport and distribution, in which extracellular concentration is assumed to be constant, may require revision.     

Direct Measurement of Extracellular Lactate in the Human Hippocampus During Spontaneous Seizures

Abstract: The effect of clinical, spontaneous-onset seizures on extracellular fluid lactate was investigated by the method of lactography, the in vivo on-line measurement of lactate levels using microdialysis. Studies of experimental animals have suggested that generation of extracellular lactate as measured by microdialysis is an index of local glucose utilization and is dependent on the activity of neurons under physiological conditions. Patients with medically refractory complex partial epilepsy underwent stereo-tactic implantation of combination depth electrode/micro-dialysis probes into both hippocampi for 7–16 days. During spontaneous complex partial seizures with secondary generalization, extracellular lactate levels rose by 91 β 32%. Moreover, this increase persisted for 60–90 min. During a unilateral hippocampal seizure that did not propagate to the contralateral hippocampus, the increase in lactate content was restricted to the side of seizure activity. Between seizures, extracellular lactate levels correlated with the frequency of interictal spikes. In summary, these data suggest that brief clinical seizures increase nonoxidative glucose metabolism significantly as measured by the generation of extracellular lactate. Furthermore, the increase in extracellular lactate level is limited to the site of seizure activity. Lactate is transported extracellularly via a lactate/proton cotransporter; therefore, the rise in extracellular lactate level may mediate the drop in pH_o associated with seizure activity. As acidification of the extracellular compartment has an inhibitory effect on neuronal excitability, the rise in extracellular lactate content may be a mechanism of seizure arrest and postictal refractoriness. Moreover, extracellular lactate may also mediate the decreased seizure susceptibility associated with frequent interictal spikes.     

Protective Effects of Extracellular Acidosis and Blockade of Sodium/Hydrogen Ion Exchange During Recovery from Metabolic Inhibition in Neuronal Tissue Culture

Abstract: Acidosis is a universal response of tissue to ischemia. In the brain, severe acidosis has been linked to worsening of cerebral infarction. However, milder acidosis can have protective effects. As part of our investigations of the therapeutic window in our neuronal tissue culture model of ischemia, we investigated the effects of acidosis during recovery from brief simulated ischemia. Ischemic conditions were simulated in dissociated cortical cultures by metabolic inhibition with potassium cyanide to block oxidative metabolism and 2-deoxyglucose to block glycolysis. Lowering the extracellular pH (pH_e) to 6.2 during metabolic inhibition had no effect on injury, as measured by lactate dehydrogenase release from cultures after 24 h of recovery. Lowering the pH_e during the first hour of recovery, in contrast, had profound protective effects. When the duration of metabolic inhibition was lengthened to 30 min, most of the protective effects of the NMDA receptor antagonist MK-801 were lost. However, the protective effects of acidosis were unchanged. This suggested that the protective effects of extracellular acidosis could be due to more than blockade of NMDA receptors. Intracellular acidosis might be responsible. To test this, recovery of intracellular pH (pH_i) was slowed by incubation with blockers of Na⁺/H⁺ exchangers at normal pH_e. The two compounds tested, dimethylamiloride and harmaline, had protective effects when present during recovery from metabolic inhibition. Measurements of pH_i confirmed that the blockers slowed recovery from intracellular acidosis; more rapid pH_i recovery was correlated with injury. The protective effects of acidosis could be reversed by brief incubation with the protonophore monensin, which rapidly normalized pH_i. These results are the first demonstration of the protective effects of blocking Na⁺/H⁺ exchange in a model of cerebral ischemia. The protective effects of acidosis appear to arise either from suppressing pH-sensitive mechanisms of injury or from blocking sodium entry due to Na⁺/H⁺ exchange.     

Influence of Perfusate Glucose Concentration on Dialysate Lactate, Pyruvate, Aspartate, and Glutamate Levels Under Basal and Hypoxic Conditions: A Microdialysis Study in Rat Brain

Abstract: The aim of this study was to evaluate the influence of perfusion media with different glucose concentrations on dialysate levels of lactate, pyruvate, aspartate (Asp), and glutamate (Glu) under basal and hypoxic conditions in rat brain neocortex. Intracerebral microdialysis was performed with the rat under general anesthesia using bilateral probes (o.d. 0.3 mm; membrane length, 2 mm) perfused with artificial CSF containing 0.0 and 3.0 m M glucose, respectively. Basal dialysate levels were obtained 2 h after probe implantation in artificially ventilated animals. Dialysate levels of glucose were also measured for the two different perfusion fluids. The mean absolute extracellular concentration of glucose was estimated by a modification of the no-net-flux method to be 3.3 mmol/L, corresponding to an average in vivo recovery of 6% for glucose. Hypoxia was induced by lowering the inspired oxygen concentration to 3%. Hypoxia caused a disturbance of cortical electrical activity, evidenced by slower frequency and lower amplitudes on the electroencephalogram compared with prehypoxic conditions. This was associated with significant elevations of lactate, Asp, and Glu levels. There were no statistically significant differences in dialysate metabolite levels between the two perfusion fluids, during either normal or hypoxic conditions. We conclude that microdialysis with glucose-free perfusion fluid does not drain brain extracellular glucose in anesthetized rats to the extent that the dialysate lactate, pyruvate, Asp, and Glu levels during basal or hypoxic conditions are altered.     

Effects of In Vitro Anoxia and Low pH on Acetylcholine Release by Rat Brain Synaptosomes

Acetylcholine and choline release from rat brain synaptosomes have been measured using a chemiluminescent technique under a variety of conditions set up to mimic anoxic insult, including conditions of low pH (6.2) and the presence of lactate plus pyruvate as substrate. Lactate plus pyruvate as substrate consistently gave higher respiration rates than glucose alone, but with either substrate (glucose or lactate plus pyruvate) the omission of Ca2+ caused an increase in respiration whereas a low pH caused a decreased respiration. Acetylcholine release under control conditions (glucose, pH 7.4) was Ca2+-dependent, stimulated by high K+ concentrations, and decreased significantly during anoxia but recovered fully after a period of postanoxic oxygenation. Low pH (6.2) suppressed K+ stimulation of acetylcholine release, and after a period of anoxia at low pH the recovery of acetylcholine release was only partial. With lactate plus pyruvate as substrate, the effects of anoxia and/or low pH on acetylcholine release and its subsequent recovery were exacerbated. Choline release from synaptosomes, however, was not affected by anoxic/ionic conditions in the same way as acetylcholine release. At low pH (6.2) there was a marked reduction in choline release both under aerobic and anoxic conditions. These results suggest that acetylcholine release per se from the nerve is very sensitive to anoxic insult and that the low pH occurring during anoxia may be an important contributory factor.     

Simultaneous Measurement of Extracellular Morphine and Serotonin in Brain Tissue and CSF by Microdialysis in Awake Rats

In this report, we describe an HPLC with electrochemical detection assay for the simultaneous measurement of levels of morphine, serotonin, 5-hydroxyindole-3-acetic acid, and homovanillic acid in dialysates of various brain areas and CSF in the awake rat. Morphine could be detected in the dialysates after a single intraperitoneal injection, with doses as low as 1.0 mg/kg. The time course of extracellular morphine content in the lateral hypothalamus, striatum, cerebellum, periaqueductal gray, and dorsal horn of the spinal cord and in CSF, from the ventricles and cisterna magna, was similar. We detected morphine in the first 15-min sample, and levels peaked 45-60 min after injection. Maximal dialysate levels, however, varied with the type of dialysis probe used and the area sampled. The most efficient in vivo recovery was in CSF dialysates from the cisterna magna, presumably because of minimal tissue interference with the dialysis probe. For this reason, the cisterna is an ideal region for sampling CSF. Morphine had no significant effect on the extracellular concentrations of serotonin in any of the areas studied and did not modify or only slightly increased levels of tissue metabolites; however, morphine markedly increased the CSF levels of 5-hydroxyindole-3-acetic acid and homovanillic acid. Because microdialysis in freely moving animals permits assessment of the behavioral effects of morphine while continuously monitoring the drug levels in discrete brain regions, this approach will greatly facilitate future studies of the neurochemical basis of morphine's effects in the brain.     

Proteins of the Brain Extracellular Fluid: Evidence for Release of S-100 Protein

Abstract: Extracellular protein fractions were obtained (1) by mild, isotonic irrigation of freshly perfused brain tissue; (2) by collection of proteins released into super-fusing medium by physiologically viable slices of rat hippocampus; and (3) by sampling the CSF of anesthetized rats. Analysis of the S-100 protein content of these fractions gave values of 2.8, 4.2, and 1.8 μg S-100/mg protein, respectively. These values were three- to sixfold higher than the S-100 content of the soluble cytoplasmic protein fractions from the same tissue. This several-fold higher S-100 content of the extracellular protein fractions relative to the intracellular cytoplasmic protein fractions indicates that S-100 is selectively released into the extracellular spaces of the brain. We suggest that the biological function of this CNS protein may involve intercellular transfer.     

Evidence Disputing the Link Between Seizure Activity and High Extracellular Glutamate

Abstract: As seizures in experimental models can be induced by the activation and suppressed by the inhibition of glutamate receptors, it is often proposed that a high extracellular glutamate level subsequent to excessive presynaptic release and/or altered glutamate uptake is epileptogenic. The purpose of this study was to ascertain the link between seizure activity and high extracellular glutamate. To assist the detection of any putative rise in extracellular glutamate during seizures, microdialysis was coupled to enzyme-amperometric detection of glutamate, which provides maximal sensitivity and time resolution. Electrical activity and field potential were also recorded through the dialysis membrane to confirm that epileptic activity was present at the sampling site. No increase in dialysate glutamate content was detected during picrotoxin-induced seizures, even when the K⁺ concentration in the perfusion medium was raised to 50% above that measured previously during paroxysmal activity. In addition, sustained inhibition of glutamate uptake by l - trans -pyrrolidine-2,4-dicarboxylate increased the extracellular glutamate level >20-fold but did not produce electrophysiological changes indicative of excessive excitation. These findings indicate that seizures are not necessarily accompanied by an increased extracellular glutamate level and that increased glutamatergic excitation in epilepsy may result from other abnormalities such as increased density of glutamate receptors, enhanced activation subsequent to reduced modulation, or sprouting of glutamatergic synapses.     

Changes in Extracellular and Rat Brain Tissue Concentrations of D-β-Hydroxybutyrate After 1, 3-Butanediol Treatment

Abstract: 1, 3-Butanediol (BD) treatment was previously shown to produce a dose-related increase of the plasma levels of D-β-hydroxybutyrate (BHB) and to protect brain tissue against hypoxia and ischemia. The purpose of this study was to test whether BD-induced hyperketonemia was associated with changes in brain extracellular and tissue concentrations of BHB. Changes in extracellular levels of BHB were continuously monitored in anesthetized rats before and after intraperitoneal injection of BD (25 mmol/kg), using intracerebral microdialysis coupled to online analysis of BHB in the dialysate. Cortical tissue concentrations of BHB were determined in control and BD- treated rats (25 and 50 mmol/kg, i.p.) after freezing of the brain in situ. Butanediol produced a rapid increase in dialysate levels of BHB, with a linear relationship between dialysate and plasma BHB concentrations ( r = 0.81, p < 0.001). In contrast, and although brain tissue levels of BHB were markedly increased after BD treatment, they were not related to the plasma concentration of BHB. Our results suggest that BHB produced from BD did not accumulate in brain and that BD protects against hypoxia or ischemia by increasing brain BHB availability.     

Extracellular Concentration and In Vivo Recovery of Dopamine in the Nucleus Accumbens Using Microdialysis

The present study compared two different in vivo microdialysis methods which estimate the extracellular concentration of analytes at a steady state where there is no effect of probe sampling efficiency. Each method was used to estimate the basal extracellular concentration of dopamine (DA) in the nucleus accumbens of the rat. In the first method, DA is added to the perfusate at concentrations above and below the expected extracellular concentration (0, 2.5, 5, and 10 nM) and DA is measured in the dialysate from the brain to generate a series of points which are interpolated to determine the concentration of no net flux. Using this method, basal DA was estimated to be 4.2 +/- 0.2 nM (mean +/- SEM, n = 5). The slope of the regression gives the in vivo recovery of DA, which was 65 +/- 5%. This method was also used to estimate a basal extracellular 3,4-dihydroxyphenylacetic acid (DOPAC) concentration in the nucleus accumbens of 5.7 +/- 0.6 microM, with an in vivo recovery of 52 +/- 11% (n = 5). A further experiment which extended the perfusate concentration range showed that the in vivo recovery of DA is significantly higher than the in vivo recovery of DOPAC (p less than 0.001), whereas the in vitro recoveries of DA and DOPAA are not significantly different from each other. The in vivo difference is thought to be caused by active processes associated with the DA nerve terminal, principally release and uptake of DA, which may alter the concentration gradient in the tissue surrounding the probe.(ABSTRACT TRUNCATED AT 250 WORDS)     

Physiological Stimulation Increases Nonoxidative Glucose Metabolism in the Brain of the Freely Moving Rat

Abstract: The effects of mild stress on nonoxidative glucose metabolism were studied in the brain of the freely moving rat. Extracellular lactate levels in the hippocampus and striatum were monitored at 2.5-min intervals with microdialysis coupled with an enzyme-based flow injection analysis system. Ten minutes of restraint stress led to a 235% increase in extracellular lactate levels in the striatum. A 5-min tail pinch caused an increase of 193% in the striatum and 170% in the hippocampus. Local application of tetrodotoxin in the striatum blocked the rise in lactate following tail pinch and inhibited the subsequent clearance of lactate from the extracellular fluid. Local application of the noncompetitive N -methyl- d -aspartate receptor antagonist MK-801 had no effect on the tail pinch-stimulated increase in lactate in the striatum. These results show that mild physiological stimulation can lead to a rapid increase in nonoxidative glucose metabolism in the brain.