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Notes: The quantitative relationship between phos-phoinositides and free fatty acids (FFAs) in brain ischemia was studied by measuring contents of individual fatty acids in phosphatidylinositol 4,5-bisphosphate (PIP2), phosphatidylinositol 4-phosphate (PIP), phosphatidylinositol (PI), phosphatidic acid (PA), diacylglycerol (DAG), and the FFA pool. Various periods of complete ischemia (1, 3, 10, and 30 min) were produced by decapitation. Ischemia of 1-3 min caused rapid decreases in PIP2 and PIP content together with preferential production of stearic and arachidonic acids in the DAG and FFA pools. The decrement in levels of these fatty acid residues in polyphosphoinositides was sufficient to account for their increment in levels in the enlarged DAG and FFA pools. After 10 min of ischemia, levels of PIP2, PIP, and DAG approached plateau values, but levels of all FFAs continued to increase. The increases in content of DAG and FFAs at later ischemic periods could not be accounted for by the decreases in content of PIP2 and PIP. PI and PA levels showed only transient and subtle changes. These results indicate that, at the onset of ischemia, phosphodiesteric cleavage of PIP2 and PIP and subsequent deacylation by lipases are primarily responsible for the preferential increase in levels of free stearic and arachidonic acids and that, later, hydrolysis of other phospholipids plays a major role in the continuous accumulation of FFAs.

Notes: Abstract: It is well established that ischemia-induced release of glutamate and the subsequent activation of postsynaptic glutamate receptors are important processes involved in the development of ischemic neuronal damage. Moderate intraischemic hypothermia attenuates glutamate release and confers protection from ischemic damage, whereas mild intraischemic hyperthermia increases glutamate release and augments ischemic pathology. As protein kinase C (PKC) is implicated in neurotransmitter release and glutamate receptor-mediated events, we evaluated the relationship between intraischemic brain temperature and PKC activity in brain regions known to be vulnerable or nonvulnerable to transient global ischemia. Twenty minutes of bilateral carotid artery occlusion plus hypotension were induced in rats in which intraischemic brain temperature was maintained at 30°C, 37°C, or 39°C. Prior to and following ischemia, brain temperature was 37°C in all groups. Cytosolic, membrane-bound, and total PKC activities were determined in hippocampal, striatal, cortical, and thalamic homogenates at the end of ischemia and at 0.25–24 h of recirculation. PKC activity of control rats varied by region and were affected by altered brain temperature. For both membrane-bound and cytosolic PKC, there was a significant temperature effect, and for membrane-bound PKC there was also a significant effect of region. Rats with normothermic ischemia (37°C) showed extensive depressions of all PKC fractions. Hippocampus and striatum were noteworthy for depressions in PKC activity extending from the earliest (15 min) to the latest (24 h) recirculation times studied, whereas cortex showed PKC depressions chiefly during the first hour of recirculation, and the thalamic pattern was inconsistent. In contrast, in rats with hypothermic ischemia (30°C), significant overall effects were noted only for total PKC in thalamus, which showed depressed levels at both 1 and 24 h of recirculation. Rats with hyperthermic (39°C) ischemia also showed significant overall effects for the time course of membrane-bound, cytosolic, and total PKC activities in the hippocampus, striatum, and cortex. However, no significant reductions in PKC indices were observed in the thalamus. For membrane-bound PKC, significant temperature effects were noted for hippocampus, striatum, and cortex, but not for thalamus. For cytosolic, as well as total PKC, activity, significant temperature effects were noted for all four brain regions. Our results indicate that ischemia, followed by reperfusion, induces a significant reduction in PKC activity and that this process is highly influenced by the brain temperature during ischemia. Furthermore, our data also establish that differences exist in the response of PKC to ischemia/recirculation in vulnerable versus non-vulnerable brain regions. These results suggest that PKC alterations may be an important factor involved in the modulatory effects of temperature on the outcome following transient global ischemia.

Notes: Abstract: We tested whether cerebral noradrenaline (NA) may play a central role in mediating the increased production of free fatty acids (FFAs) during cerebral ischemia. Levels of FFAs, cyclic AMP, and NA, as well as ATP, ADP, and AMP, were measured in cerebral cortex during decapitation ischemia in rats 2 weeks after unilateral locus ceruleus lesion. Comparisons were made between the results obtained from the contralateral cortex with normal NA content and the NA-depleted ipsilateral cortex. Although NA depletion was associated with a diminished transient rise of cyclic AMP in response to ischemia, it failed to influence the magnitude of FFA increase or the decline of energy state within the 15-min period of ischemia. A more than twofold increase of total FFAs (sum of palmitic, stearic, oleic, arachidonic, and docosahexaenoic acids) was observed in both hemispheres at 1 min after decapitation, when energy failure became manifest. The increased production of FFAs continued throughout the 15 min of ischemia, with a preferential rise in the levels of stearic and arachidonic acids. There was an inverse correlation between FFA levels and total adenylate pool. The results do not support a major role for NA and cyclic AMP in increasing cortical FFAs during complete ischemia. Instead, they are consistent with the view that impaired oxidative phosphorylation activates deacylating enzymes. Disturbance of reacylation due to energy depletion is probably another factor contributing to the continuous increase of FFAs during prolonged ischemia.

Notes: Abstract: During and after insulin-induced hypoglycemia, changes in levels of cerebral phosphatidylinositol (PI), phosphatidylinositol 4-phosphate (PIP), phosphatidylinositol 4,5-bisphosphate (PIP2), phosphatidic acid (PA), triacylglycerol (TAG), diacylglycerol (DAG), and free fatty acids (FFAs) as well as the cerebral energy state were studied in relation to the EEG. In hypoglycemic rats with an EEG pattern of quasiperiodic sharp or slow sharp waves, which preceded the development of an isoelectric EEG, PIP2 levels increased significantly, together with a slight decrease in PI content. Levels of the other lipids did not change during this period. The cerebral energy state was affected only slightly in spite of profound decreases in plasma and tissue glucose levels. With 30 min of an isoelectric EEG, levels of all phos-phoinositides and PA decreased significantly; total FFA and DAG contents increased seven-and twofold, respectively; the TAG-palmitate level decreased, and that of TAG-arachidonate increased. Plasma and tissue glucose were nearly depleted, and the cerebral energy state deteriorated severely. The increment in fatty acids in the DAG and FFA pools was less than their loss from phosphoinositides and PA, an observation suggesting vascular washout or oxidation of a portion of the FFAs produced. Following 90 min of glucose infusion, PIP and PA levels recovered to control values; however, the PIP2 content exceeded control levels, and that of PI remained below control levels. DAG and FFA contents returned to normal. The data suggest that PIP2 synthesis is increased or PIP2 degradation is blocked because of disturbed neurotransmission during the preisoelectric and recovery periods, at a time when the tissue energy state is minimally affected, and that all phosphoinositides are degraded during the period of isoelectric EEG, probably owing to energy shortage.

Notes: Abstract: The purpose of this investigation was to investigate pathomechanisms responsible for the deleterious effects of repeated episodes of brief forebrain ischemia. Halothane-anesthetized male Wistar rats were subjected to either (a) a single 15-min period or (b) three 5-min periods (separated by 1 h) of global forebrain ischemia by bilateral carotid artery occlusions plus hypotension (50 mm Hg), followed by various periods of recirculation. Brain temperature was normothermic throughout. In one series of rats, extracellular levels of glutamate, glycine, and γ-aminobutyric acid (GABA) were measured in the dorsolateral striatum (n = 6–8 per group) and lateral thalamus (n = 4–6 per group) by microdialysis and HPLC before and during ischemia and during 3–5 h of recirculation. In a parallel series of rats (n = 6 per group), ischemic cell change was quantified at 2 (dark neurons), 24, or 72 h following either single or multiple ischemic insults. A single 15-min ischemic period led to massive glutamate release (13-fold increase; p= 0.001), which returned to normal by 20–30 min of recirculation and remained normal thereafter. By contrast, in rats with three 5-min periods of ischemia, the glutamate level rise with each repeated insult (four- to 4.5-fold; p〈inlineGraphic alt="leqslant R: less-than-or-eq, slant" extraInfo="nonStandardEntity" href="urn:x-wiley:00223042:JNC2213:les" location="les.gif"/〉 0.02) was smaller than that observed during the single 15-min insult, but a late sustained rise (five- to six-fold; p 〈 0.05) occurred at 2–3 h of recirculation. Brief ischemia-induced elevations of glycine and GABA levels were detected in both the single- and multiple-insult groups, with normalization during recirculation. In contrast, the excitotoxic index, a composite measure of neurotransmitter release ([glutamate] X [glycine]/[GABA]), differed markedly following single versus multiple insults (p= 0.002 by repeated-measures analysis of variance) and increased by seven- to 12-fold (p 〈 0.05) at 1–3 h following the third insult. The total amount of glutamate released was 3.3-fold higher in the multiple-insult than in the single-insult group (p 〈 0.02). At 2 h of recirculation, histopathological analysis of dorsolateral striatum showed a significantly greater frequency of dark neurons in the multiple- than in the single-insult group (p 〈 0.05 by analysis of variance). In the thalamus, a higher frequency of ischemic neurons was seen in the multiple- than in the single-insult group at all intervals studied. Thus, in rats with multiple ischemic insults, accelerated ischemic damage was found in the striatum, and severe ischemic injury was documented in the thalamus. These results demonstrate that multiple ischemic insults lead to a massive, sustained glutamate accumulation and to a major increase in the excitotoxic index during early recirculation, which is not seen following a single brief ischemic episode. These neurochemical changes correlate with our histopathological data showing an accelerated evolution of striatal pathology at 2 h following multiple ischemic insults.

Notes: We evaluated whether regional differences in the magnitude of glutamate, γ-aminobutyric acid (GABA), and glycine release could explain why some regions are vulnerable to ischemia whereas others are spared. By means of the microdialysis technique, the temporal profile of ischemia-induced changes in extracellular levels of glutamate, GABA, and glycine was compared in regions that demonstrate differing susceptibilities to a 10- and 20-min ischemic insult (dorsal hippocampus, anterior thalamus, somatosensory cortex, and dorsolateral striatum). The degree of ischemia (as established by local cerebral blood flow reduction) and the magnitude of histopathoiogical neuronal damage were also evaluated in these regions. The blood flow reduction was severe and uniform in all regions; however, the histopathoiogical outcome illustrated a different pattern. Whereas the CA1 sector of the hippocampus was severely damaged, the thalamus and cortex were relatively spared from both 10 and 20 min of ischemia. Striatal neurons were resistant to a 10-min insult but severely damaged after 20 min of ischemia. Ischemia-induced increases in glutamate and GABA content were of a similar magnitude and temporal profile in all four brain regions. A uniform increase in extracellular glycine levels was also observed in all four brain structures. The postischemic response, however, was different Glycine levels remained twofold higher than baseline in the hippocampus but fell to baseline in the cortex and thalamus after both 10- and 20-min insults. In the striatum, glycine levels returned to baseline after 10 min of ischemia but remained relatively high after a 20-min insult Although ischemic neuronal damage was not related to glutamate release, it correlated with the „excitotoxic index,” whose value was derived from the following equation: [glutamate] X [glycine]/[GABA]. No significant changes were observed in the excitotoxic index during ischemia. However, a significant increase in the index was observed in vulnerable brain regions during the early and late recirculation periods. These results suggest that the imbalance between excitation and inhibition, reflected by changes in the excitotoxic index, may account for regional vulnerability to ischemia.

Notes: Abstract: We have previously described a marked attenuation of postischemic striatal neuronal death by prior substantia nigra (SN) lesioning. The present study was carried out to evaluate whether the protective effect of the lesion involves changes in the degree of local cerebral blood flow (1CBF) reduction, energy metabolite depletion, or alterations in the extracellular release of striatal dopamine (DA), glutamate (Glu), or γ-aminobutyric acid (GABA). Control and SN-lesioned rats were subjected to 20 min of forebrain ischemia by four-vessel occlusion combined with systemic hypotension. Levels of 1CBF, as measured by the autoradiographic method, and energy metabolites were uniformly reduced in both the ipsi- and contralateral striata at the end of the ischemic period, a finding implying that the lesion did not affect the severity of the ischemic insult itself. Extracellular neurotransmitter levels were measured by microdialysis; the perfusate was collected before, during, and after ischemia. An ∼ 500-fold increase in DA content, a 7-fold increase in Giu content, and a 5-fold increase in GABA content were observed during ischemia in nonlesioned animals. These levels gradually returned to baseline by 30 min of reperfusion. In SN-lesioned rats, the release of DA was completely prevented, the release of GABA was not affected, and the release of Glu was partially attenuated. However, excessive extracellular Glu concentrations were still attained, which are potentially toxic. This, taken together with the previous neuropathological findings, suggests that excessive release of DA is important for the development of ischemic cell damage in the striatum.

Notes: Abstract: Levels of phosphatidylinositol 4,5-bisphosphate (PIP2), phosphatidylinositol 4-phosphate (PIP), phosphatidylinositol (PI), phosphatidic acid, diacylglycerol (DAG), triacylglycerol (TAG), and free fatty acids (FFAs), as well as their fatty acid composition, were determined in rat forebrain during ischemia and postischemic recirculation. Cerebral energy state and electroencephalograms (EEGs) were also studied. Fifteen minutes of ischemia resulted in a decrease in PIP2 and PIP contents but not in PI content, concurrent with an enlargement of the FFA and DAG pools. The latter were enriched in stearate and arachidonate. Prolongation of ischemia did not produce further changes in content of any of the inositol phosphalipids, but the increase in levels of FFAs and DAG continued. At the end of 45 min of ischemia, levels of both PIP2 and PIP decreased by 45–50%, and the total phosphoinositide content (PIP2+ PIP + PI) decreased by 21%, whereas levels of FFAs and DAG increased to 14– and 3.6-fold of control levels, respectively. During ischemia, the TAG-palmitate level decreased, but the TAG-arachidonate level increased; the tissue energy state deteriorated severely; and the EEG was suppressed. A 30-min recirculation period after 15 or 45 min of ischemia led to increases in PIP2, PIP, and total phosphoinositide contents, whereas levels of FFAs and DAG promptly decreased toward control values. The TAG-arachidonate level peaked and the TAG-palmitate level returned to a low control value during early recirculation. The ischemic changes in tissue lipids were completely reversed within 3 h of recirculation after both periods of ischemia. Adenylates were fully phosphorylated with as little as 30 min of reflow. The EEG activity partially recovered during reflow after 15 min of ischemia, whereas it remained depressed after prolonged ischemia. Thus, phosphodiesteric cleavage of PIP2 and PIP followed by deacylation of DAG is likely to contribute to the production of FFAs in early ischemia. Deacylation of undetermined lipids plays a role for the increment in levels of FFAs in the later period of ischemia. The rapid postischemic increase in levels of PIP2 and PIP indicates active synthesis not only from existing PI, but probably also by means of accumulated FFAs and DAG. These results indicate that the impaired resynthesis of inositol phospholipids cannot be a cause of the poor EEG activity after prolonged ischemia. Degradation and resynthesis of polyphosphoinositides and formation of TAG-arachidonate may be important for modulation of free arachidonic acid levels in the brain during temporary ischemia.

Notes: Abstract: Using an in vitro system, we studied the effect of postischemic reoxygenation on cerebral lipid peroxidation in relation to the dietary intake of vitamin E (VE) in rats. Homogenates prepared from VE-deficient, -normal, and -supplemented brains, which were previously rendered ischemic for 30 min by decapitation, were incubated under air or nitrogen gas for 60 min. The extent of peroxidation in brain tissue was estimated by a thiobarbituric acid (TBA) test and by diene conjugation in total lipid extracts. The brain levels of α-tocopherol and of total and free fatty acids (FAs) were also determined. Aerobic incubation increased TBA reactants in all dietary groups; the effect was largest in the VE-deficient group, intermediate in the VE-normal group, and smallest in the VE-supplemented group. In contrast, nitrogen incubation did not alter the basal levels of TBA reactants except for a small rise associated with VE deficiency. Conjugated dienes changed in parallel with TBA reactants. α-Tocopherol decreased after aerobic incubation and also, to a lesser degree, after nitrogen incubation in each dietary group. Only in the reoxygenated samples of the VE-deficient group was there a significant fall in total polyunsaturated FAs. The levels of free FAs continuously increased throughout ischemia and subsequent incubation. However, the level of free polyunsaturated FAs was similar after aerobic and nitrogen incubation in each dietary group, and was not affected by VE. Thus, cerebral reoxygenation after ischemia propagates peroxidative reactions within esterified polyunsaturated FAs. The modification by VE of reoxygenation-induced lipid peroxidation suggests free radical mediation.