Amygdala Kindling Modifies Extracellular Opioid Peptide Content in Rat Hippocampus Measured by Microdialysis

Abstract: Opioid peptide release in the hippocampus was shown to be increased immediately following amygdala kindling stimulation in freely moving rats using microdialysis combined with a universal opioid peptide radioimmunoassay (RIA). Extracellular opioid peptide levels were elevated (55% above basal levels) within the first 10 min after electrical stimulation-induced partial seizures in previously nonkindled animals. Fully kindled rats showed lower extracellular opioid peptide levels (40% reduction) during the interictal period [16 ± 2.1 days (mean ± SEM) after the last stage V seizure], in comparison with values obtained from the sham-kindled group under basal conditions. However, opioid peptide release in fully kindled rats increased above 152% of interictal levels within the first 20 min after onset of fully kindled seizures, attaining peak levels equal to that of the partial kindled group and returning to prestimulation conditions 40–60 min following the ictal events. The majority of the immunoreactive material recovered from the hippocampus within the first 20 min following partial and generalized kindled seizures coeluted with dynorphin-A (1–6), dynorphin-A (1–8), and Leu-enkephalin by HPLC/RIA analysis. It is proposed that the enhanced opioid peptide release in hippocampus induced by amygdala kindling stimulation might be associated with either enhanced excitability or seizure suppression as seizure susceptibility fluctuates. The reduced interictal opioid peptide levels may also underlie some interictal behavioral disturbances.     

Lactate levels in the brain are elevated upon exposure to volatile anesthetics: a microdialysis study

Anesthetic agents have well-defined pharmacological targets but their effects on energy metabolism in the brain are poorly understood. In this study, we examined the effects of different anesthetics on extracellular lactate and glucose levels in blood, CSF and brain of the mouse. In vivo-microdialysis was used to monitor extracellular energy metabolites in the brain of awake mice and during anesthesia with seven different anesthetic drugs. In separate groups, lactate and glucose concentrations in blood and CSF were measured for each anesthetic. We found that anesthesia with isoflurane caused a large increase of extracellular lactate levels in mouse striatum and hippocampus (300-400%). Pyruvate levels also increased while glucose and glutamate levels were unchanged. This effect was dose-dependent and was mimicked by other gaseous anesthetics such as halothane and sevoflurane but not by intravenous anesthetics. Ketamine/xylazine and chloral hydrate caused 2-fold increases of glucose levels in mouse blood and brain while lactate levels were only moderately increased. Propofol caused a minor increase of extracellular glucose levels while pentobarbital had no effect on either lactate or glucose. Volatile anesthetics also increased lactate levels in blood and CSF by 2-3-fold but had no effect on plasma glucose. Further experiments demonstrated that lactate formation by isoflurane in mouse brain was independent of neuronal impulse flow and did not involve ATP-dependent potassium channels. We conclude that volatile anesthetics, but not intravenous anesthetics, cause a specific, dose-dependent increase in extracellular lactate levels in mouse brain. This effect occurs in the absence of ischemia, is independent of peripheral actions and is reflected in strongly increased CSF lactate levels.     

Lactate levels in the brain are elevated upon exposure to volatile anesthetics: A microdialysis study

Anesthetic agents have well-defined pharmacological targets but their effects on energy metabolism in the brain are poorly understood. In this study, we examined the effects of different anesthetics on extracellular lactate and glucose levels in blood, CSF and brain of the mouse. In vivo-microdialysis was used to monitor extracellular energy metabolites in the brain of awake mice and during anesthesia with seven different anesthetic drugs. In separate groups, lactate and glucose concentrations in blood and CSF were measured for each anesthetic. We found that anesthesia with isoflurane caused a large increase of extracellular lactate levels in mouse striatum and hippocampus (300–400%). Pyruvate levels also increased while glucose and glutamate levels were unchanged. This effect was dose-dependent and was mimicked by other gaseous anesthetics such as halothane and sevoflurane but not by intravenous anesthetics. Ketamine/xylazine and chloral hydrate caused 2-fold increases of glucose levels in mouse blood and brain while lactate levels were only moderately increased. Propofol caused a minor increase of extracellular glucose levels while pentobarbital had no effect on either lactate or glucose. Volatile anesthetics also increased lactate levels in blood and CSF by 2–3-fold but had no effect on plasma glucose. Further experiments demonstrated that lactate formation by isoflurane in mouse brain was independent of neuronal impulse flow and did not involve ATP-dependent potassium channels. We conclude that volatile anesthetics, but not intravenous anesthetics, cause a specific, dose-dependent increase in extracellular lactate levels in mouse brain. This effect occurs in the absence of ischemia, is independent of peripheral actions and is reflected in strongly increased CSF lactate levels.     

Comparison of the effects of volatile anesthetics in varying concentrations on brain energy metabolism with brain ischemia in rats

The effects of varying concentrations and types of volatile anesthetics on neurochemical sequelae of brain ischemia were evaluated in the rat. Rats were assigned to treatment defined by a 3×3 design (anesthetic type and dose) with 5 rats/cell. Each group received halothane, enflurane, or isoflurane 0.5, 1.0, or 2.0 MAC (minimal alevolar concentration). This was followed by preischemic plasma glucose sampling, 5 min hypotension (30 mmHg) and 5 min decapitation cerebral ischemia. Preischemia plasma glucose increased with increasing anesthetic concentration and was highest in the isoflurane groups, varying from a low (±SD) of 7.19±1.79 mol/ml in the 0.5 MAC halothane group to a high of 12.68±3.65 mol/ml in the 2.0 MAC isoflurane group. End-ischemic brain lactate correlated with preischemic plasma glucose (r=0.5, =0.5). We conclude that increasing concentration of volatile anesthesia with iv phenylephrine blood pressure support produces higher levels of plasma glucose and brain lactate with cerebral ischemia.     

Decreased Brain KATP Channel Contributes to Exacerbating Ischemic Brain Injury and the Failure of Neuroprotection by Sevoflurane Post-Conditioning in Diabetic Rats

Diabetes leads to exacerbating brain injury after ischemic stroke, but the underlying mechanisms and whether therapeutic intervention with anesthetic post-conditioning can induce neuroprotection in this population are not known. We tested the hypothesis that alteration of brain mitochondrial (mito) K_ATP channels might cause exacerbating brain injury after ischemic stroke and attenuate anesthetic post-conditioning induced neuroprotection in diabetes. We also examined whether hyperglycemic correction with insulin would restore anesthetic post-conditioning in diabetes. Non-diabetic rats and diabetic rats treated with or without insulin were subjected to focal cerebral ischemia for 2 h followed by 24 h of reperfusion. Post-conditioning was performed by exposure to sevoflurane for 15 min, immediately at the onset of reperfusion. The role of the mitoK_ATP channel was assessed by administration of a selective blocker 5-hydroxydecanoate (5-HD) before sevoflurane post-conditioning or by diazoxide (DZX), a mitoK_ATP channel opener, given in place of sevoflurane. Compared with non-diabetic rats, diabetic rats had larger infarct volume and worse neurological outcome at 24 h after ischemia. Sevoflurane or DZX reduced the infarct volume and improved neurological outcome in non-diabetic rats but not in diabetic rats, and the protective effects of sevoflurane in non-diabetic rats were inhibited by pretreatment with 5-HD. Molecular studies revealed that expression of Kir6.2, an important mitoK_ATP channel component, was decreased in the brain of diabetic rats as compared to non-diabetic rats. In contrast, hyperglycemic correction with insulin in diabetic rats normalized expression of brain Kir6.2, reduced ischemic brain damage and restored neuroprotective effects of sevoflurane post-conditioning. Our findings suggest that decreased brain mitoK_ATP channel contributes to exacerbating ischemic brain injury and the failure of neuroprotection by anesthetic post-conditioning in diabetes. Insulin glycemic control in diabetes may restore the neuroprotective effects of anesthetic post-conditioning by modulation of brain mitoK_ATP channel.     

The Dual Peptidase Inhibitor RB101 Induces a Long-Lasting Increase in the Extracellular Level of Met-Enkephalin-Like Material in the Nucleus Accumbens of Freely Moving Rats

Abstract: This study was carried out to analyze the extracellular levels of Met-enkephalin-like material in the nucleus accumbens, a brain structure involved in the effects of opioids on motor activity and reward processes, using microdialysis in awake and freely moving rats, combined with a sensitive radioimmunoassay. The levels of Met-enkephalin-like material were measured after administration of a dual inhibitor of enkephalin-degrading enzymes, RB101, to evaluate its in vivo protecting effects. The basal levels of Met-enkephalin-like immunoreactivity in the nucleus accumbens were ∼1.2 pg/30 min or 2.2 fmol/30 min (37 p M ). Perfusion of KCl (100 m M ) produced a 17-fold increase in the level of Met-enkephalin-like material in this structure. During the 8-h perfusion, which started at 9 a.m., a spontaneous increase of the basal level of Met-enkephalin-like material in the nucleus accumbens occurred between 4 and 4:30 p.m., suggesting the existence of variation in opioid peptide secretion, at least in this structure. Intraperitoneal injection of RB101 induced a dose-dependent and long-lasting (210-min) increase in the extracellular levels of Met-enkephalin-like material. A prolonged effect was also observed in the behavioral studies in which the inhibitor increased global motor activity of rats 210 min after injection. These data represent the first direct evidence that dual inhibitors of enkephalin-degrading enzymes increase in vivo the extracellular levels of Met-enkephalin-like material in awake and freely moving rats.     

Sevoflurane-induced delayed neuroprotection involves mitoK<Subscript>ATP</Subscript> channel opening and PKC ε activation

There is an increasing body of evidence that a brief exposure to anesthesia induces ischemic tolerance in rat brain (anesthetic preconditioning). However, it is unknown whether preconditioning with sevoflurane, a commonly used volatile anesthetic in current clinical practice, produces a delayed window of neuroprotection against ischemia and what the mechanisms are for this protection. To address these issues, adult male Sprague–Dawley rats were subjected to middle cerebral arterial occlusion (MCAO) for 2 h. Sevoflurane preconditioning was induced 24 h before brain ischemia by exposing the animals to sevoflurane at 1.0 minimum alveolar concentration (2.4%) in oxygen for 60 min. Animals preconditioned with sevoflurane had lower neurological deficit scores and smaller brain infarct volumes than animals with brain ischemia at 6 and 24 h after MCAO, respectively. Application of a selective antagonist for mitochondrial ATP-sensitive potassium (mitoK_ATP) channel, 5-hydroxydecanoate (5-HD, 40 mg/kg i.p.) 30 min before sevoflurane exposure attenuated this beneficial effect. Moreover, protein kinase C ε (PKC ε) was translocated to the membrane fraction at 6 h, but not 24 h, after brain reperfusion in animals preconditioned with sevoflurane and this effect was also abolished by 5-HD. We concluded that sevoflurane preconditioning induces a delayed neuroprotection and that mitochondrial K_ATP channels and PKC ε may be involved in this neuroprotection.     

Effect of hypothermia on brain multi-parametric activities in normoxic and partially ischemic rats

Hypothermia, as well as anesthesia, are known to protect the brain against ischemia, hypoxia and other pathological damages. One of the mechanisms of this improvement could be by lowering brain function, and thereby lowering oxygen demand. We examined the effect of hypothermia on brain function and blood supply in awake and anesthetized rats and studied the interaction between partial ischemia and the responses to hypothermia. The brain function multiprobe (BFM) used enabled simultaneous measurements of cerebral blood flow (CBF), mitochondrial NADH redox state, extracellular K(+) concentration, DC potential and ECoG from the cerebral cortex in rats whose brain temperature was lowered by 5 degrees C. Hypothermia was induced in awake, anesthetized and brain ischemic-anesthetized rats. In anesthetized and ischemic-anesthetized rats, the time required for lowering the brain temperature by 5 degrees C was five times less than in the normal awake animals. No significant changes in CBF and NADH levels were found in response to hypothermia in the awake animals. In contrast, a significant decrease in extracellular K(+) concentration was recorded under hypothermia, probably due to the lower rate of depolarization. Hypothermia in anesthetized and in ischemic-anesthetized rats did not significantly affect the levels of mitochondrial NADH, CBF and extracellular K(+). Hypothermia under ischemia was expected to be more effective.     

Novel biomarkers to assess in utero effects of maternal opioid use: First steps toward understanding short‐ and long‐term neurodevelopmental sequelae

Maternal opioid use disorder is common, resulting in significant neonatal morbidity and cost. Currently, it is not possible to predict which opioid‐exposed newborns will require pharmacotherapy for neonatal abstinence syndrome. Further, little is known regarding the effects of maternal opioid use disorder on the developing human brain. We hypothesized that novel methodologies utilizing fetal central nervous system‐derived extracellular vesicles isolated from maternal blood can address these gaps in knowledge. Plasma from opioid users and controls between 9 and 21 weeks was precipitated and extracellular vesicles were isolated. Mu opioid and cannabinoid receptor levels were quantified. Label‐free proteomics studies and unbiased small RNA next generation sequencing was performed in paired fetal brain tissue. Maternal opioid use disorder increased mu opioid receptor protein levels in extracellular vesicles independent of opioid equivalent dose. Moreover, cannabinoid receptor levels in extracellular vesicles were upregulated with opioid exposure indicating cross talk with endocannabinoids. Maternal opioid use disorder was associated with significant changes in extracellular vesicle protein cargo and fetal brain micro RNA expression, especially in male fetuses. Many of the altered cargo molecules and micro RNAs identified are associated with adverse clinical neurodevelopmental outcomes. Our data suggest that assays relying on extracellular vesicles isolated from maternal blood extracellular vesicles may provide information regarding fetal response to opioids in the setting of maternal opioid use disorder. Prospective clinical studies are needed to evaluate the association between extracellular vesicle biomarkers, risk of neonatal abstinence syndrome and neurodevelopmental outcomes.     

ATP extracellular concentrations are increased in the rat striatum during in vivo ischemia

Interest is growing in the role of adenosine triphosphate (ATP) on P2 receptors during hypoxic/ischemic events in the brain. However, there is no direct evidence of an increase in extracellular ATP levels during cerebral ischemia in vivo. The aim of the present study was to evaluate ATP outflow from the rat striatum by the microdialysis technique associated with focal cerebral ischemia in vivo by intraluminal occlusion of the right middle cerebral artery (MCA). Between 1 and 4h after ischemia, rats showed a clear turning behavior contralateral to the ischemic side. Twenty-four hour after MCA occlusion, ischemic rats had definite neurological deficit and striatal and cortical damage. The ATP concentration (mean+/-S.E.M.) in the striatum of normoxic rats (n = 8) was 3.10+/-0.34 nM. During 220 min after MCA occlusion, the extracellular ATP levels significantly increased two-fold, being 5.90+/-0.61 nM (p < 0.01 versus normoxic level). ATP outflow showed a tendency to increase over time during the 220 min of ischemia. Since extracellular ATP is rapidly metabolized to adenosine, we also assessed ATP outflow in the presence of the ecto-5'-nucleotidase inhibitor, alpha,beta-methylene-adenosine diphosphate (AOPCP, 1 mM) directly perfused into the striatum. The ATP concentration in normoxic rats (n = 8) was increased three-fold in the presence of the ecto-5'-nucleotidase inhibitor (9.57+/-0.26 nM). During 220 min of ischemia, extracellular ATP levels significantly increased 1.3-fold in AOPCP-treated rats (12.62+/-0.65 nM, p < 0.01 versus normoxic level). The present study confirms that ATP is continuously released in the brain and demonstrates for the first time that ATP outflow increases during ischemia in vivo. These results confirm that ATP may be an important mediator in brain ischemia.     

Leu-enkephalin actions on avoidance conditioning are mediated by a peripheral opioid mechanism

Leu-enkephalin (100 micrograms/kg, i.p.) administered to mice 5 min before training in a one way active avoidance task significantly reduced the number of avoidances observed in the peptide treated animals. This impairing action of Leu-enkephalin was partially attenuated by methylnaloxonium (naloxonium), a quarternary form of naloxone with a limited ability to penetrate the blood brain barrier. Passive immunization (i.v.) of mice with a Leu-enkephalin antiserum 4 hrs before training produced an effect on avoidance conditioning that was the opposite to that observed with Leu-enkephalin alone. That is, passive immunization increased the number of avoidances observed in the treated mice. The results suggest that Leu-enkephalin actions on avoidance conditioning are mediated by a peripheral opioid mechanism, that leu-enkephalin may have a primary site of action outside the blood brain barrier, and that peripheral Leu-enkephalin systems may normally operate to influence conditioned avoidance behavior.     

Comparative study of change in extracellular ascorbic acid in different brain ischemia/reperfusion models with in vivo microdialysis combined with on-line electrochemical detection

Information on the change in extracellular ascorbic acid (AA) during the acute period of cerebral ischemia is of great importance in the early therapeutic intervention of the cerebral ischemic injury since AA is known to be involved into most kinds of neurochemical changes in the cerebral ischemia. This study describes a fast and efficient method through integration of in vivo microdialysis with on-line electrochemical detection for continuous monitoring cerebral AA, allowing comparative study of the change in the extracellular AA level in different brain ischemia/reperfusion models. The method exhibits a high specificity for AA measurements, bearing a good tolerance against the fluctuation in the brain anoxia and acidity induced by cerebral ischemia/reperfusion. In the global two-vessel occlusion (2-VO) ischemia model, the striatum AA did not change with statistic significance until 60 min after occlusion and was decreased to be 91+/-3% (n=5, P<0.05) of the basal level (8.05+/-0.23 microM) at the time point of 60 min after occlusion. In the 2-VO ischemia/reperfusion model, AA remained unchanged during the 10 min of ischemia, and was sharply increased to be 267+/-74% (n=5, P<0.05) of the basal level after the initial 15 min of reperfusion, and then decreased to be 122+/-33% (n=5, P<0.05) of the basal level after 50 min of reperfusion. Extracellular AA was largely increased after 5 min of left middle cerebral artery occlusion (LMCAO) and was then gradually increased to be 257+/-49% (n=5, P<0.05) of the basal level after 60 min of LMCAO ischemia. In the LMCAO ischemia/reperfusion model, AA was greatly increased during 10 min of ischemia and then gradually increased to be 309+/-69% (n=5, P<0.05) of the basal level after the consecutive 50 min of reperfusion. The results demonstrated here may be useful for understanding the neurochemical processes in the acute period of cerebral ischemia and could thus be important for neuroprotective therapeutics for cerebral ischemic injury.     

Do inhalation general anesthetic drugs induce the neuronal release of endogenous opioid peptides?

The antagonism of some effects of inhalation general anesthetic agents by naloxone suggests that there may be an opioid component to anesthetic action. There is evidence that this opioid action component is due to neuronal release of endogenous opioid peptides. The strongest evidence is provided by studies that monitor changes in the concentration of opioid peptides in the perfused brain following inhalation of the anesthetic. Indirect or circumstantial evidence also comes from studies of anesthetic effects on regional brain levels of opioid peptides, antagonism of selected anesthetic effects by antisera to opioid peptides and anesthetic-induced changes radioligand binding to opioid receptors. It is likely that some inhalation general anesthetics (e.g., nitrous oxide) can induce neuronal release of opioid peptides and that this may contribute to certain components of general anesthesia (e.g., analgesia). More definitive studies utilizing in vivo microdialysis or autoradiography in selected areas of the brain during induction and successive states of general anesthesia have yet to be conducted.     

Neuroprotective effects of lactate in brain ischemia: Dependence on anesthetic drugs

Lactate is a major energy source for the brain, especially when glucose is not available in sufficient amounts. In the present study, we administered sodium l-lactate (250 mg/kg) to mice before or after middle cerebral artery occlusion (MCAO) to test whether lactate can be neuroprotective in brain ischemia. Permanent ischemia for 24 h caused a large hemispheric lesion and a severe loss of body weight. Administration of lactate shortly (15–30 min) before MCAO strongly reduced cell death and weight loss, but only when isoflurane was used for anesthesia. Under pentobarbital anesthesia, lactate was inactive. After transient ischemia, when isoflurane or ketamine–xylazine were used as anesthetic drugs, lactate was effective when given immediately after reperfusion. In separate experiments, we found that plasma lactate levels are also strongly influenced by anesthetic drugs. Thus, isoflurane anesthesia as well as lactate administration caused strongly increased plasma levels of lactate whereas pentobarbital anesthesia significantly reduced plasma lactate. We conclude that exogenous lactate is neuroprotective in an in vivo-model of brain ischemia, but that its action is strongly influenced by the type of anesthetic agent used.     

Comparative Effect of Transient Global Ischemia on Extracellular Levels of Glutamate, Glycine, and γ-Aminobutyric Acid in Vulnerable and Nonvulnerable Brain Regions in the Rat

We evaluated whether regional differences in the magnitude of glutamate, gamma-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 histopathological neuronal damage were also evaluated in these regions. The blood flow reduction was severe and uniform in all regions; however, the histopathological 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 increase 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.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hyperosmotic pretreatment reduces infarct size in the rat heart

Preconditioning of the heart can be achieved by an ischemia/reperfusion stimulus, but also by stretching of the heart by an acute volume overload. Since manipulations of the extracellular osmolality affects cell size, we hypothesized that hyperosmotic pretreatment of the isolated perfused rat heart could reduce infarct size following regional ischemia (RI). Langendorff perfused rat hearts were subjected to 30 min RI by ligature of the main branch of the left coronary artery followed by 120 min reperfusion (control group). Ischemic preconditioning (IP-5') was achieved by 5 min total global ischemia and 5 min reperfusion prior to RI. Hyperosmotic pretreatment was accomplished by perfusion with a hyperosmotic buffer (600 mOsm/kg H2O by adding mannitol) for 1 min, 2 min or 5 min. At the end of the experiments, the hearts were cut into 2 mm slices, incubated with triphenyltetrazoliumchloride before scanning and computerized for estimation of infarct size. The average infarct size (as percentage of area at risk) in the control group was 42% and was significantly reduced to 16% by ischemic preconditioning and to 17% by 2 min hyperosmotic pretreatment. Neither 1 min nor 5 min hyperosmotic pretreatment reduced infarct size as compared to the controls. The infarct reducing effect of 2 min hyperosmotic pretreatment was not blunted by inhibition of protein kinase C (chelerytrine chloride), the Na+/H+-exchanger (HOE 694) or stretch-activated anion channels (gadolinium chloride). The results indicate that short-lasting hyperosmotic perturbations of the extracellular environment may precondition the heart to a subsequent ischemic insult.     

Field use of isoflurane as an inhalant anesthetic in the American marten (Martes americana)

We evaluated the effectiveness and practicality of using isoflurane as an inhalation anesthetic with oxygen as a gas carrier for American martens (Martes americana) in a field setting. Sixty-eight martens were trapped in the Waswanipi Cree Model Forest (Québec, Canada) from October to November 2005 and anesthetized with isoflurane in 100% oxygen (1 l/min) using a face mask. Induction setting of isoflurane was 3% for all animals. Mean (+/-SD) length of induction was 1.8+/-1.2 min. Maintenance isoflurane settings ranged from 1% to 4%. Procedures lasted an average of 16.4+/-7.1 min and were uneventful. Length of recovery, defined as the interval between the end of the procedure and animal release, was short (6.3+/-2.8 min), and well below reported lengths of recovery using injectable anesthetics (>/=70 min). As compared to open drop administration of isoflurane described in previous studies, the use of an anesthesia machine prevents the risk of potential fatal anesthetic overdose. We conclude that among anesthesia techniques currently available, isoflurane with oxygen as a gas carrier is a safe and useful field anesthetic in martens, when issues with equipment portability can be overcome.     

Delivery of a lactose derivative of endomorphin 1 to the brain via the olfactory epithelial pathway

The rapid and direct delivery of a neuroactive endomorphin 1 derivative to the brain via nasal delivery is reported. A synthetic derivative of the native opioid peptide, endomorphin 1 bearing a lactose unit on the N-terminus of the peptide has been previously reported to exhibit antinoceceptive activity similar to morphine after both intravenous and oral administration. This compound has been administered nasally to rats and appeared in the olfactory bulb within 10 min of administration with negligible levels appearing in the circulating blood or in the rest of the brain. These results indicate that the peptide is absorbed into the brain via the olfactory epithelial pathway suggesting nasal delivery may be a viable alternative route of delivery in clinical applications.     

Effect of ischemic preconditioning on cerebral blood flow after subsequent lethal ischemia in gerbils

Ischemic tolerance, the phenomenon where a sublethal ischemic preconditioning protects the brain against a subsequent lethal ischemia, has been widely studied. Studies have been done on cerebral blood flow levels prior to the lethal ischemia, but the hemodynamic pattern after global ischemia with ischemic preconditioning has not been reported. Sequential changes in regional cerebral blood flow (rCBF) in gerbil hippocampus after 5 min global ischemia with or without 2 min ischemic preconditioning were studied to determine if ischemic preconditioning affects rCBF. Four different treatments were given: (1) sham-operated, (2) 2 min ischemia, (3) non-preconditioned, and (4) preconditioned. Groups (1) and (2) (both groups n = 5) were given a 24-h recovery period and the rCBF was measured for baseline values. 24 h after sham-operation (3) and 2 min ischemia (4), gerbils were subjected to 5 min ischemia followed by 1 h, 6 h, 1-day or 7-day reperfusion periods (all groups n = 5). Although no regional difference was observed in the recovery pattern of rCBF, the values of rCBF were significantly higher in the preconditioned group throughout whole brain regions including hippocampus. These results indicate that ischemic preconditioning facilitated the recovery of rCBF after 5 min global ischemia. It needs further study to determine whether the protecting effects of preconditioning relate to the early recovery of rCBF or not. However, our results could be interpreted that the early recovery of rCBF may lead to benefits for cell survival in the CA1 neuron, probably facilitating other protecting mechanisms.     

A New Enzymatic Cycling Technique for Glutamate Determination in Brain Microdialysates

A quantitative analysis of glutamate in brain dialysate was made by using an enzymatic cycling technique. This method made it possible to measure the concentration of glutamate in dialysate collected at 30-s intervals. Dialysates were collected from Mongolian gerbil hippocampus before, during, and after two 90-s ischemic insults at an interval of 5 min. An extracellular increase in levels of glutamate was already observed in samples collected during a 30-60 s period after the onset of each ischemia, and the levels of glutamate were maximal at the end of each period of ischemia (approximately a fourfold increase). The increased levels of glutamate rapidly returned almost to preischemic levels by 30 s of recirculation. This method will provide more precise information about temporal changes in the extracellular glutamate concentration in the brain during ischemia.