Aminoacid recovery via microdialysis and photoinduced focal cerebral ischemia in brain cortex of rats

Systemic osmotic manipulations modulate ethanol-induced taurine release: a brain microdialysis study

In recent microdialysis studies, increased extracellular concentrations of taurine after high ethanol dose administration were identified in various rat brain regions. The mechanisms by which ethanol caused these increases in extracellular taurine concentration remained unclear but could be related to ethanol-induced cell swelling. The aim of the current study was to investigate whether changes in the body osmotic state modulate the effects of ethanol on brain extracellular taurine concentrations. In several groups of rats, brain hypoosmotic or hyperosmotic states were superimposed on acute ethanol (2.0-g/kg) injections, and extracellular taurine concentrations within the nucleus accumbens were assessed by using an intracerebral microdialysis procedure. A hypoosmotic state was obtained by systemic administration of water while hyperosmotic states were induced by intraperitoneal injections of hypertonic saline solutions (1.8% or 3.6% saline). In isoosmotic conditions, ethanol induced an immediate and significant increase in taurine microdialysate content, confirming results of previous studies. However, the effects of ethanol on taurine concentrations were modulated by osmotic manipulations. Hypoosmotic conditions significantly potentiated ethanol-induced taurine release. In contrast, ethanol-induced increases in extracellular taurine levels were attenuated by 1.8% saline injection and totally prevented by 3.6% saline administration. These results strongly argue in favor of a primary role of osmoregulation in ethanol-induced taurine release. Ethanol-induced cell swelling probably activates volume-sensitive channels, and taurine passively diffuses outside the cells along its concentration gradient.

Ischemia-induced glutamate release in rat frontoparietal cortex after chronic alcohol and withdrawal

High doses of ethanol increase stroke risk: in this context, a role for excitatory amino acids has been proposed. The present results show that, in frontoparietal cerebral cortex, chronic ethanol treatment (10% v/v in drinking water for 28 days) was able to slightly reduce glutamate release (evaluated through transdialysis coupled with high-pressure liquid chromatography) following focal ischemia as regards non-treated ischemic rats. This reduction was, however, not associated with decreased cerebral damage. In 24-h withdrawing rats, histological and morphometric analyzes showed an exacerbated cerebral damage coupled with higher glutamate and aspartate release compared to controls. These results suggest that adaptive changes following chronic ethanol consumption lead to an increased excitotoxicity that is particularly evident during the withdrawal condition.

Acute cerebral focal ischaemia alters the adrenergic and NANC responses in the bisected rat vas deferens

1. Disturbances of the autonomic nervous system are common in right hemisphere stroke patients, including a marked decline in male sexual functions. There is a lack of information on the influence of stroke on male secondary sex organs such as the vas deferens. 2. This study investigates the effect of right brain focal ischaemia on the adrenergic and purinergic responses in isolated epididymal and prostatic portions of rat vas deferens. 3. In both epididymal and prostatic portions the concentration-response curves to noradrenaline are flattened resulting in a reduction (up to 67 - 76%) of the maximum contractile response in the tissue from ischaemic rats compared to the controls. In the prostatic portion from ischaemic rats the concentration-response curve to alpha,beta-methylene ATP was also depressed. 4. The first purinergic and the second delayed adrenergic phase to single pulse was not modified by brain ischaemia. In contrast both phasic and tonic components of the electrically induced contractions by trains of stimuli at high frequencies (2 - 30 Hz) were significantly depressed in the epididymal and prostatic portions from ischaemic rats. 5. These results demonstrate an autonomic imbalance at the level of male sexual secondary organs which may contribute to sexual impairment after stroke.

Cortical spreading depression and the pathogenesis of brain disorders: a computational and neural network-based investigation

This paper reviews our recent studies of the role of cortical spreading depression (CSD) in the pathogenesis of brain disorders. Our investigation is a computational one, involving the development and utilization of a complex neuro-metabolic model of the interactions assumed to occur in the cortex during the passage of multiple CSD waves. Incorporating these neuro-metabolic changes of CSD within a neural network model of normoxic cortex produces cortical activation patterns during the passage of a CSD wave that, projected onto the visual fields, resemble the visual hallucinations observed during the migraine aura. When focal ischemia is simulated with the model, the evoked CSD waves are found to affect the expansion of the infarction into the ischemic penumbra. Our findings support the hypothesis that CSD does play an important pathogenic role in these and other neurological disorders, and suggest additional experimental studies that may further substantiate it.

The Cycloxygenase-2 inhibitor SC58236 is neuroprotective in an in vivo model of focal ischemia in the rat

Focal ischemia was induced in the fronto-parietal region of rat brain, by injection of Rose Bengal, followed by light activation. Focal ischemia was accompanied by formation of PGD(2) peaking 60-90 min post irradiation and declining thereafter. Increased Cycloxygenase-2 (COX-2) expression was also observed. Control ischemic rats showed distinct morphological alterations with necrosis of neurons, glial cells and blood vessels, surrounded by a halo with pyknotic cells with cytoplasm swelling and vacuolization. Compound SC58236, a selective COX-2 inhibitor, dose-dependently prevented, ischemia-induced eicosanoid formation (area under the curve (AUC) of controls: 3.11 +/- 0.87; AUC of 20 mg/kg SC58236: 0.39 +/- 0.24), and caused significant reduction of damaged area (30.7 and 18.9% at SC58236 20 and 6.6 mg/kg), suggesting that selective inhibitors of COX-2 are neuroprotective.

Effect of acute alcohol on ischemia-induced glutamate release and brain damage

Epidemiological studies show that chronic ethanol consumption at high doses enhances the risk of cerebral stroke. The mechanisms responsible for the greater vulnerability of alcoholics' brains to stroke have to be completely understood, but a role for excitatory amino acids has been suggested. In order to study the interaction between alcohol and ischemia, we investigated the effect of acute alcohol administration in a model of focal cerebral ischemia. In particular, we evaluated the release of glutamate and aspartate from the cerebral frontal cortex by a transdialysis technique. Alcohol was acutely administered at 1.5 and 3.0 g/kg ip. During the period of maximal alcoholemia, ethanol almost abolished the ischemia-induced release of glutamate leading to glutamate values around or below the basal. Aspartate levels were unaltered both following ischemia and alcohol+ischemia. The decrease in glutamate release, however, was not accompanied by a significant reduction of the extension of the damaged area assessed by histological analysis.

Influence of different anaesthetics on extracellular aminoacids in rat brain

We used different anaesthetic procedures to study the possible effects of anaesthesia on extracellular aminoacid concentration in rat brain. Glutamate, aspartate and glycine concentrations were determined by HPLC in samples collected from the right fronto-parietal region of the rat brain cortex by transcerebral microdialysis before and up to 2 h following anaesthesia induction. Anaesthesia induced by ketamine, alone or in association with xylazine, caused a significant decrease in the levels of glutamate, aspartate and glycine, compared to before anaesthesia values (range: 27-72% according to the time of sampling and to the anaesthetic used). Inhalation anaesthesia with halothane (3%) in N2O/O2 mixture produced no significant effects on aminoacid levels. Equitensine (pentobarbital in association with chloral hydrate and ethanol) and pentobarbital also had no significant effect on glutamate, aspartate and glycine levels during anaesthesia. This demonstrates that some anaesthetics alter excitatory aminoacid release and suggests that Equitensine may represent an easy and reliable method to induce a long lasting anaesthesia associated without changes in excitatory aminoacid extracellular concentration.

Pathogenic mechanisms in ischemic damage: a computational study

The pathogenesis of penumbral tissue infarction during acute ischemic stroke is controversial. This peri-infarct tissue may subsequently die, or survive and recuperate, and its preservation has been a prime goal of recent therapeutic trials in acute stroke. Two major hypotheses currently under consideration are that penumbral tissue is recruited into an infarct by cortical spreading depression (CSD) waves, or by a non-wave self-propagating process such as glutamate excitotoxicity (GE). Careful experimental attempts to discriminate between these two hypotheses have so far been quite ambiguous. Using a computational metabolic model of acute focal stroke we show here that the spatial patterns of tissue damage arising from artificially induced foci of infarction having specific geometric shapes are inherently different. This is due to the distinct propagation characteristics underlying self-regenerating waves and non-wave diffusional processes. The experimental testing of these predicted spatial patterns of damage may help determine the relative contributions of the two pathological mechanisms hypothesized for ischemic tissue damage.

Inhibition of prostanoid synthesis protects against neuronal damage induced by focal ischemia in rat brain

Changes in prostanoids concentration and effects of the non-specific COX inhibitor indomethacin on prostanoids levels and extension of tissue damage were studied following focal ischemia induction in the fronto-parietal region of rat brain. Ischemia was induced in animals bearing a transcerebral microdialysis probe by injection of Rose Bengal, a photosensitive dye, followed by light activation. Prostanoid levels were determined in the dialysate using immunoenzymatic techniques. PGD2 levels rose significantly up to 237+/-22 pg/ml compared to a basal level measured before ischemia induction which was below the detection limit. TXB2 changes were smaller and had a different time course. Treatment with indomethacin abolished the ischemia-induced PGD2 release and reduced the extent of injury to the area by 43+/-3.7%. These results suggest that prostanoid release may play an important role in neurodegenerative processes and that cyclooxygenase inhibitors may contribute to protect against cerebral tissue damage.

Hypoxia-induced apoptosis: effect of hypoxic severity and role of p53 in neuronal cell death

In various animal models of cerebral hypoxia-ischemia, it is not clear whether neuronal apoptosis results from hypoxia alone or whether other factors mediate this process. We hypothesized that (1) hypoxia alone can induce neuronal apoptosis, (2) hypoxic severity alters the time course of neuronal apoptosis, (3) hypoxia increases neuronal p53, and this increase in p53 is critical for neuronal apoptosis. Embryonic neocortical neurons cultured for 7-10 days were placed in an incubator with levels set at 0.1%, 1%, and 3% O2 and were removed at 24-h intervals for study. Under all hypoxic conditions, observed changes in cellular morphology and DNA fragmentation, detected by the TUNEL method and gel electrophoresis, were consistent with apoptosis. These alterations were seen after a shorter period with increasing hypoxic severity. Immunoblot analysis revealed an increase in p53 protein in hypoxia-exposed neurons. Analysis of immunofluorescence-stained neurons revealed increases in p53 with increased duration and severity of hypoxia. Antisense oligonucleotides for p53 significantly increased the number of surviving neurons during hypoxic exposure. We conclude that hypoxia-induced neuronal apoptosis is, in part, a p53-dependent process whose time course is influenced by hypoxic severity and duration.

Nitrite/nitrate balance during photoinduced cerebral ischemia in the rat determined by high-performance liquid chromatography with UV and electrochemical detection

A specific and simple method for the direct simultaneous detection of extracellular nitrite (NO2-) and nitrate (NO3-) has been developed, using high-performance liquid chromatography separation with UV and electrochemical detection in series. These stable endproducts of nitric oxide (NO.) were determined in dialysis perfusate obtained through in vivo brain microdialysis during and after experimental photoinduced cerebral ischemia in rats. The chromatographic conditions were optimized with a reversed-phase column (250 x 46 mm) using 10 mM n-octylamine pH 6.0 as a mobile phase. Absorbance was measured at 220 nm for NO3- detection; electrochemical detection was performed at +0.7 V for NO2- evaluation. This assay system holds the advantages of in vivo consecutive measurements, high precision, good reproducibility, technical simplicity, fast response (about 7 min), and wide availability.