Lifelong Consumption of Sodium Selenite: Gender Differences on Blood–Brain Barrier Permeability in Convulsive,Hypoglycemic Rats

The aim of this study was to compare the effects of hypoglycemia and induced convulsions on the blood-brain barrier permeability in rats with or without lifelong administration of sodium selenite. There is a significant decrease of the blood-brain barrier permeability in three brain regions of convulsive, hypoglycemic male rats treated with sodium selenite when compared to sex-matched untreated rats (p<0.05), but the decrease was not significant in female rats (p>0.05). The blood-brain barrier permeability of the left and right hemispheres of untreated, moderately hypoglycemic convulsive rats of both genders was better than their untreated counterparts (p<0.05). Our results suggest that moderate hypoglycemia and lifelong treatment with sodium selenite have a protective effect against blood-brain barrier permeability during convulsions and that the effects of sodium selenite are gender-dependent.     

Blood–Brain Barrier Permeability to Sodium. Modification by Glucose or Insulin?

In order to explore the pathogenetic mechanism underlying the changes in blood-brain barrier sodium transport in experimental diabetes, the effects of hyperglycemia and of hypoinsulinemia were studied in nondiabetic rats. In untreated diabetes, the neocortical blood-brain barrier permeability for sodium decreased by 20% (5.6 +/- 0.7 versus 7.0 +/- 0.8 X 10(5) ml/g/s) as compared to controls. Intravenous infusion of 50% glucose for 2 h was associated with a decrease in the blood-brain barrier permeability to sodium (5.4 +/- 1.2 X 10(5) ml/g/s), whereas rats treated with an inhibitor of insulin-secretion (SMS 201-995, a somatostatin-analogue) had normal sodium permeability (7.3 +/- 2.0 X 10(5) ml/g/s). Acute insulin treatment of diabetic rats normalized the sodium permeability within a few hours as compared to a separate control group (7.7 +/- 1.1 versus 6.9 +/- 1.4 X 10(5) ml/g/s). To elucidate whether the abnormal blood-brain barrier passage is caused by a metabolic effect of glucose or by the concomitant hyperosmolality, rats were made hyperosmolar by intravenous injection of 50% mannitol. Although not statistically significant, blood-brain barrier sodium permeability increased in hyperosmolar rats as compared to the control rats (8.3 +/- 1.0 and 7.0 +/- 1.9 X 10(5) ml/g/s, respectively). It is concluded that either hyperglycemia per se or a glucose metabolite is responsible for the blood-brain barrier abnormality which occurs in diabetes. Further, we suggest that the specific decrease of sodium permeability could be the result of glucose-mediated inhibition of the Na+K+-ATPase localized at the blood-brain barrier.     

Influence of surgical pain stress on the blood-brain barrier permeability in rats

Effect of surgical pain stress on the blood-brain barrier permeability was investigated in rats. The animals were divided into four groups: Group 1: control, Group 2: immobilization stress, Group 3: acute hypertension, Group 4: immobilization stress + surgical pain stress.Bilateral hid paw surgical wounds for cannulations were applied in animals' inguinal regions under diethyl-ether anesthesia, then the animals were awaken from anesthesia to produce surgical pain stress. Evans-blue was used as a blood-brain barrier tracer. There is no significantly blood-brain barrier breakdown after short-time immobilization stress, but after adrenalin hypertension blood-brain barrier permeability was increased especially on frontal and occipital cortices in 50% of the animals. Surgical pain stress increased blood-brain barrier permeabiliy in comparison to acute adrenalin-induced hypertension (p < 0.01). In surgical pain stress-induced animals distinct Evans-blue leakage was observed in the occipital, frontal and parieto-temporal cortices.     

In Vivo Distribution of CGS-19755 Within Brain in a Model of Focal Cerebral Ischemia

The blood-brain barrier permeability of the competitive N-methyl-D-aspartate receptor antagonist CGS-19755 [cis-4-(phosphonomethyl)-2-piperidine carboxylic acid] was assessed in normal and ischemic rat brain. The brain uptake index of CGS-19755 relative to iodoantipyrine was assessed using the Oldendorf technique in normal brain. The average brain uptake index in brain regions supplied by the middle cerebral artery was 0.15 +/- 0.35% (mean +/- SEM). The unidirectional clearance of CGS-19755 from plasma across the blood-brain barrier was determined from measurements of the volume of distribution of CGS-19755 in brain. These studies were performed in normal rats and in rats with focal cerebral ischemia produced by combined occlusion of the proximal middle cerebral artery and ipsilateral common carotid artery. In normal rats the regional plasma clearance across the blood-brain barrier was low, averaging 0.015 ml 100 g-1 min-1. In ischemic rats this clearance value averaged 0.019 ml 100 g-1 min-1 in the ischemic hemisphere and 0.009 ml 100 g-1 min-1 in the nonischemic hemisphere. No significant regional differences in plasma clearance of CGS-19755 were observed in either normal or ischemic rats except in cortex injured by electrocautery where a 14-fold increase in clearance across the blood-brain barrier was measured. We conclude that CGS-19755 crosses the blood-brain barrier very slowly, even in acutely ischemic tissue.     

Development of central and peripheral serotonin-producing systems in rats in ontogenesis

The work deals with study of development of central and peripheral serotonin-producing systems in rat ontogenesis before and after formation of the blood-brain barrier. By the method of highly efficient liquid chromatography it has been shown that the serotonin level in peripheral blood before formation of the blood-brain barrier (in fetuses and neonatal rats) is sufficiently high for realization of physiological effect on target cells and organs. At the period of formation of the blood-brain barrier the serotonin level in brain sharply rises, whereas the serotonin concentration and amount in blood plasma and duodenum increase insignificantly. Completion of formation of the blood-brain barrier is accompanied by a significant increase of the serotonin content in duodenum, probably for maintenance of the high serotonin level in blood. To evaluate secretory activity, the mean rate of daily serotonin increment in the studied tissues was calculated. In brain, this parameter was maximal at the period of formation of the blood-brain barrier-from the 4th to the 16th postnatal days. This allows thinking hat brain before formation of the blood-brain barrier is the most important source of serotonin in peripheral blood.     

The brain is one of the most important sources of dopamine in general circulation during perinatal ontogenesis in rats

This study was aimed to test our hypothesis that dopamine synthesized in the neurons of the brain is delivered to the general circulation in rats during prenatal and early postnatal periods, i.e. before the establishment of the blood-brain barrier. Using the high performance liquid chromatography, it was demonstrated that the dopamine concentration and content in the peripheral blood in fetuses and neonatal rats (i.e. before the establishment of the blood-brain barrier) greatly exceeded those in adult rats. Moreover, the establishment of the blood-brain barrier was accompanied by the significant increase of the dopamine concentration in the brain. A drop of the dopamine concentration in fetal plasma after the microsurgical lesion of the forebrain and mesencephalon (encephalectomy) are considered as direct evidence in favour of our hypothesis.     

Lack of effects of 1439 MHz electromagnetic near field exposure on the blood-brain barrier in immature and young rats

Possible effects of 1439 MHz electromagnetic near field (EMF) exposure on the blood-brain barrier (BBB) were investigated using immature (4 weeks old) and young (10 weeks old) rats, equivalent in age to the time when the BBB development is completed and the young adult, respectively. Alteration of BBB related genes, such as those encoding p-glycoprotein, aquaporin-4, and claudin-5, was assessed at the protein and mRNA levels in the brain after local exposure of the head to EMF at 0, 2, and 6 W/kg specific energy absorption rates (SARs) for 90 min/day for 1 or 2 weeks. Although expression of the 3 genes was clearly decreased after administration of 1,3-dinitrobenzene (DNB) as a positive control, when compared with the control values, there were no pathologically relevant differences with the EMF at any exposure levels at either age. Vascular permeability, monitored with reference to transfer of FITC-dextran, FD20, was not affected by EMF exposure. Thus, these findings suggest that local exposure of the head to 1439 MHz EMF exerts no adverse effects on the BBB in immature and young rats.     

Blood–Brain Transfer of Glucose and Glucose Analogs in Newborn Rats

Little is known of the selectivity of the blood-brain barrier at birth. Hexoses are transported through the barrier by a facilitating mechanism. To study the capacity of this mechanism to distinguish between analogs of D-glucose, we compared the transport of fluorodeoxyglucose, deoxyglucose, glucose, methylglucose, mannose, galactose, mannitol, and iodoantipyrine across the cerebral capillary endothelium in newborn Wistar rats. Cerebral blood flow, glucose consumption, and the blood-brain permeabilities of the hexoses were 25-50% of the adult values but the ratios between the permeabilities of the individual hexoses were similar to the ratios observed in adult rats. The mannitol clearance into brain was considerably higher than in adult rats (about 10-fold), indicating a higher endothelial permeability to small polar nonelectrolytes. The brain water content was higher in newborn than in adult rats and was associated with a higher steady-state distribution of labeled methylglucose between brain and blood. Hexose concentrations were determined relative to whole blood because the apparent erythrocyte membrane permeability to glucose was as high as in humans and thus considerably higher than in adult rats. The half-saturation concentration of glucose transport across the blood-brain barrier was considerably higher than in adult rats, about three-fold, suggesting that net blood-brain glucose transfer is less sensitive to blood glucose fluctuation in newborn than in adult rats.     

Locus ceruleus: the regulation of hemato-encephalic barrier function normally and under emotional stress

To study the role of locus ceruleus in maintaining the blood-brain barrier function in conditions of emotional stress, the blood-brain barrier permeability was estimated after locus ceruleus damaging with DSP4 (N-2-chloroethyl-N-ethyl-2-bromobenzylamine). The importance of locus ceruleus for the integrity of blood-brain barrier functions in control animals and especially in rats exposed to emotional stress was revealed. The data obtained prove the homeostatic role of locus ceruleus, which is the most prominent in conditions of emotional stress.     

Long-term L-NAME treatment potentiates the blood-brain barrier disruption during pentylenetetrazole-induced seizures in rats

We investigated whether the severity of blood-brain barrier disruption caused by pentylenetetrazole-induced seizures is modified by long-term nitric oxide synthase inhibition in rats. Rats were given N-omega-nitro-L-arginine methyl ester (L-NAME), a nitric oxide synthase inhibitor, in drinking water for 4 weeks, and then treated with pentylenetetrazole to induce seizures. Damage to the blood-brain barrier was investigated using Evans blue dye extravasation. Serum nitric oxide concentration was decreased in L-NAME-treated rats (P<0.01). L-NAME and/or pentylenetetrazole treatments elevated systolic blood pressure of animals (P<0.01). L-NAME caused an increase in the mortality rate after pentylenetetrazole injection leading to the death of animals at about 15 min after the onset of the seizure. Pentylenetetrazole-induced seizures in rats treated with L-NAME caused a significant increase in Evans blue dye extravasation into cerebral cortex, diencephalon and cerebellum, as compared with seizures evoked by pentylenetetrazole injection to L-NAME-untreated rats (P<0.01). Data presented here suggest that the degree of blood-brain barrier disruption induced by seizures is more pronounced in long-term nitric oxide deficiency.     

艾灸对阿尔茨海默病模型大鼠血脑屏障结构与学习记忆功能的影响*

目的:探讨艾灸对阿尔茨海默病(AD)模型大鼠血脑屏障结构与学习记忆功能的影响。方法:48只SD大鼠随机分为4组:正常对照组、假手术组、模型组、艾灸组,模型组和艾灸组大鼠采用双侧海马一次性注射聚集态Aβ_25-35的方法建立AD大鼠模型,假手术组双侧海马区注射等量生理盐水,正常组不做处理。造模成功后,在艾灸组大鼠的“百会”、“肾俞”、“印堂”穴上方2～3 cm处施予艾条温和灸治疗,每穴10 min,每天1次,持续治疗21 d。采用Morris水迷宫实验评估各组大鼠的学习与记忆能力,伊文思蓝法检测血脑屏障通透性,电镜下观察血脑屏障的超微结构,免疫组化法检测海马区MMP-2和MMP-9阳性细胞数。结果:与正常对照组和假手术组比较,模型组大鼠逃避潜伏期时间显著增加(P＜0.01),空间探索时间显著下降(P＜0.01),学习记忆功能严重受损,脑内伊文思蓝含量显著增加(P＜0.01),血管周围水肿变大,血脑屏障结构功能受损,同时海马MMP-2和MMP-9阳性表达均显著增加(P＜0.01);与模型组比较,艾灸治疗组大鼠的学习与记忆能力均有所增强(P＜0.05),脑内伊文思蓝含量显著下降(P＜0.05),血管周围水肿程度减轻,血脑屏障损伤情况得到改善,海马MMP-2和MMP-9阳性表达显著降低(P＜0.05或P＜0.01)。结论:艾灸能减轻AD模型大鼠血脑屏障结构的损伤程度,从而改善大鼠的学习记忆能力,其机制可能与MMP-2和MMP-9被抑制有关。     

Methionine Sulfoximine Prevents the Accumulation of Large Neutral Amino Acids in Brain of Portacaval-Shunted Rats

Portal-systemic shunting and hyperammonemia lead to an accumulation of the large neutral amino acids in brain and apparently alter transport of neutral amino acids across the blood-brain barrier. It has been proposed that portal-systemic shunting leads to a high brain concentration of glutamine, a product of cerebral ammonia detoxification, and thereby affects the transport of other neutral amino acids across the blood-brain barrier. To test this hypothesis, rats with a portacaval shunt were treated with L-methionine-dl-sulfoximine (MSO), an inhibitor of glutamine synthesis. Treatment with MSO resulted in lower concentrations of the neutral amino acids in brain of portacaval-shunted rats and a higher brain ammonia concentration, compared with untreated shunted rats. These results suggest that the accumulation of neutral amino acids in brain after portacaval shunt depends on the increased synthesis of glutamine in brain.     

Phenylalanine transport at the human blood-brain barrier. Studies with isolated human brain capillaries

The exquisite sensitivity of brain amino acid availability to changes in plasma amino acid composition arises from the uniquely high affinity (low Km) of blood-brain barrier transport sites as compared to cell membrane transport systems in nonbrain tissues. The extension of this paradigm from rats to man assumes that the Km of blood-brain barrier amino acid transport in the human is low as in the rat. This hypothesis is tested in the present studies wherein isolated human brain capillaries are used as a model system for the human blood-brain barrier. Capillaries were obtained from autopsy brain between 20 and 45 h after death and were isolated in high yield and free of adjoining brain tissue. [3H]Phenylalanine transport into the isolated human, rabbit, or rat brain capillary was characterized by two saturable transport systems and a nonsaturable component. The Km values of phenylalanine transport into brain capillaries via the two saturable systems averaged 0.26 +/- 0.08 and 22.3 +/- 7.1 microM for five human subjects. These studies provide the first evidence for a very high affinity (Km = 0.26 microM) neutral amino acid transport system at the blood-brain barrier, and it is hypothesized that this system is selectively localized to the brain side of the blood-brain barrier. The results also show that the transport Km values for phenylalanine transport are virtually identical at both the rat and human blood-brain barrier.     

Damage to the hemato-encephalic barrier during one-time immobilization stress

Intravenous injection of trypan blue followed by treatment of the brain according to the Falc-Hillarp was used for morphological study of the blood-brain barrier in control rats and in animals exposed to the 6.5-hour stress. The density of the blood-brain barrier as regards the macromolecules in control animals was found to be liable to noticeable areal variations. The zones of primary increased barrier permeability were found near the basal surface of the brain. Prolonged single immobilization stress gave rise to destructive changes in the blood-brain barrier in the reticular formations of the midbrain and medulla oblongata. Besides, in control animals, there was a slight increase in permeability of the brain areas marked by the reduced barrier density.     

Immunoenzymatic detection of specific brain antigens as a criterion of the permeation of blood-brain barrier in rats with acute cerebral ischemia

EIA detection system for the measurement of alpha 2 M globulin and GFAP antigen has been developed. The limit of the sensibility was only 1 ng/ml for alpha 2M and 0.8 ng/ml for GFAP. The system was used for the studies of the penetration through the blood-brain barrier in rats with experimental acute brain ischemia. The measurement of alpha 2M and GFAP antigens by EIA technique 16-20 hours after the occlusion of the carotid artery has revealed disturbances in the blood-brain barrier permeability for specific brain proteins. The method is recommended for indirect evaluation of the blood-brain barrier functional disorders.     

Glucose Transporter of the Blood-Brain Barrier and Brain in Chronic Hyperglycemia

The effect of chronic hyperglycemia on the glucose transporter moiety of the blood-brain barrier and cerebral cortex was studied in rats 3 weeks after the administration of a single intravenous dose of streptozotocin (60 mg/kg), using specific [3H]cytochalasin B binding methods. Streptozotocin-treated rats developed hyperglycemia, as well as polydipsia and polyuria, and failed to gain weight. The density of D-glucose-displaceable cytochalasin B binding sites in the brain microvessels of streptozotocin-treated hyperglycemic rats was increased by about 30% compared with those of control rats, without change in the affinity of binding. Chronic hyperglycemia had no effect on the density or affinity of specific binding of cytochalasin B to cerebral cortical membranes. These findings do not support the hypothesis that glucose transporters in brain microvessels comprising the blood-brain barrier are "down-regulated" in chronic hyperglycemia.     

Abdominal vagal mediation of the satiety effects of CCK in rats

CCK type 1 (CCK1) receptor antagonists differing in blood-brain barrier permeability were used to test the hypothesis that satiety is mediated in part by CCK action at CCK1 receptors on vagal sensory nerves innervating the small intestine. Devazepide penetrates the blood-brain barrier; A-70104, the dicyclohexylammonium salt of N alpha-3-quinolinoyl-D-Glu-N,N-dipentylamide, does not. At dark onset, non-food-deprived control rats and rats with subdiaphragmatic vagotomies received a bolus injection of devazepide (2.5 micromol/kg i.v.) or a 3-h infusion of A-70104 (3 micromol.kg(-1).h(-1) i.v.) either alone or coadministered with a 2-h intragastric infusion of peptone (0.75 or 1 g/h). Food intake was determined from continuous computer recordings of changes in food bowl weight. In control rats both antagonists stimulated food intake and attenuated the anorexic response to intragastric infusion of peptone. In contrast, only devazepide was effective in stimulating food intake in vagotomized rats. Thus endogenous CCK appears to act both at CCK1 receptors beyond the blood-brain barrier and by a CCK1 receptor-mediated mechanism involving abdominal vagal nerves to inhibit food intake.     

Domperidone elevates rat plasma beta-endorphin-immunoreactivity when administered peripherally but not intracerebroventricularly

Domperidone, a dopamine receptor antagonist which apparently does not penetrate the blood-brain barrier in rats was administered to adult males. Domperidone 500 micrograms and 100 micrograms, given through intracarotid cannula, significantly elevated plasma beta-endorphin-immunoreactivity (beta-EP-I) at +15 min. To show that only a peripheral site(s) of action is implicated, domperidone was given to rats by cannulae implanted into both lateral ventricles. Plasma beta-EP-I was unaffected by this route of administration. These results suggest that plasma beta-EP-I is tonically inhibited by dopamine acting at site(s) outside of the blood-brain barrier.     

Blood-brain barrier to 6-hydroxydopamine: uptake by heart and brain.

The presumed blood-brain barrier to 6-OH-DA was studied in 25–36 day old rats with high (30 mg/kg) and low (0.14 mg/kg) dose intravenous 6-OH-DA-1-¹⁴C. From measurements of radioactivity in heart, brain and plasma, the authors conclude that a blood-brain barrier to 6-OH-DA exists in this species.     

Structuro-functional organization of the blood-brain barrier

The analysis of the authors and published data allowed to conclude that the blood-brain barrier was a complex structural-functional system. Its basic components are endothelial cells, basal membrane, pericytes, tissue basophils, and astrocytes. The role of these structural elements in the permeability of blood-brain barrier has been studied. Organ-specific peculiarities of the brain tissue basophils have been established in rats, cats, and dogs. The astrocyte-capillary complexes were found to be very reactive, and at the same time, very plastic CNS structures.