The influence of chemical sympathectomy on oxygen uptake during development of rat brain cortical tissue

In this study the influence of 6-hydroxydopamine (6-OHDA), in vitro and in vivo, on the oxygen consumption in the rat brain cortical slices was examined. The treatment with 6-OHDA increased the oxygen uptake of brain cortical tissue of young rats. The maximum increase was observed 7 and 14 days after treatment with 6-OHDA. On the contrary, 6-OHDA added in vitro produced very marked depression of oxygen uptake in slices of brain cortical tissue of the tested animals. The addition of isoprenaline in vitro stimulated the respiratory activity in the cerebral tissue of control young rats in all the periods of examination. Thus, 18 days after the birth, the isoprenaline-stimulation of oxygen uptake in brain tissue was 44.3% as compared to the control values. The same degree of stimulation was noted in the cerebral tissue of older animals (25, 32 and 45 days after birth). However, addition of isoprenaline did not influence the respiration of cerebral tissue stimulated by 6-OHDA.     

In vivo oxygen-17 nuclear magnetic resonance for the estimation of cerebral blood flow and oxygen consumption

To explore the feasibility of in vivo 17O NMR for the estimation of cerebral blood flow and oxygen consumption, in vivo 17O NMR spectroscopy and imaging were employed in animal models. In the spectroscopy, the changes in the 17O NMR signal intensity after the injection of H2(17)O and the inhalation of 17O2 gas were obtained every 4 seconds with sufficient signal-to-noise ratios for the quantification of cerebral blood flow and oxygen consumption. In the imaging, although the time and spatial resolutions were insufficient for the quantification of H2(17)O, 17O NMR images of rabbit brain could be obtained, indicating that it is possible to map cerebral blood flow and oxygen consumption by 17O NMR imaging.     

The Significance of Anoxæmia in Modern Psychiatric Treatment: (Section of Psychiatry)

Blood in its passage through the brain loses oxygen and glucose at relatively high rates, the amount of oxygen disappearing being approximately equivalent to the amount of glucose consumed, calculating on the basis that the sugar is completely oxidized. The respiratory quotient of brain in vivo is unity. These facts point to the dominance of carbohydrate oxidation in brain respiration in vivo and are similar to those found in studies of brain in vitro.Various factors influence glucose oxidation in brain, e.g. changes in the ionic environment of the cells, vitamin B(1), or the presence of narcotics. The latter bring about inhibitions of glucose oxidation in brain tissue which may in most cases be shown to be reversible in vitro. Glucose is not only important for the maintenance of respiration of brain but for enabling certain synthetic processes to occur. One of these is the formation of acetylcholine whose physiological significance is now well known and whose synthesis seems to be confined to the nervous system. This synthesis depends not only on the presence of glucose but on that of oxygen. The influence of glucose has been observed also in investigations on cortical potentials.An important feature of the nerve cell is its vulnerability to the lack of oxygen. Reversibility depends on the degree and duration of the anox?mia.During insulin shock treatment studies of brain in vivo show lowered oxygen consumption and glucose utilization, these depending on the degree of hypoglyc?mia. In cardiazol treatment, in vivo studies show that the oxygen content of the blood may fall to 42%. During the convulsion there is a greatly lowered arterial and venous blood-flow through the brain and cerebral an?mia becomes a marked feature. In narcosis treatment both in vitro and in vivo studies show a diminished ability of the brain to consume oxygen.It is suggested that the most significant facts to be taken into account are (1) the importance of glucose and oxygen for the metabolism and function of the nervous system, (2) the vulnerability and varying sensitivities of nerve cells to lack of oxygen and glucose, (3) the occurrence of varying degrees of cerebral anox?mia in narcosis, insulin and cardiazol treatments.     

Metabolic correction of cerebral radiation syndrome.

DNA strand breaks that occur after irradiation activate the repair enzyme adenosine diphosphoribosyl transferase, which consumes NAD as a substrate and causes depletion first of neuronal NAD and then of the ATP pool. This is considered to be the crucial link in the mechanism underlying the cerebral radiation syndrome (CRS). In this study, two ways to correct the CRS metabolically were examined: (a) prevention of depletion of NAD after irradiation by administration of the enzyme inhibitor nicotinamide and (b) shunting the NAD-dependent oxidative phosphorylation pathway of ATP resynthesis by administration of a substrate of NAD-independent oxidation, succinate. Cerebral lesions induced by radiation were modeled by irradiation of rats or rat brain homogenates with 150 Gy of X rays. The manifestations of CRS in rats (excitement, convulsions, etc.) closely resembled those seen after acute hypoxia. In brain homogenates, pyruvate tetrazolium-reductase activity decreased after irradiation and could be corrected by addition of NAD after irradiation. Succinate tetrazolium-reductase activity was not affected by irradiation. Oxygen consumption by brain homogenates after irradiation in vitro and in situ decreased, as did oxygen consumption by rats in vivo after cranio-caudal irradiation. Administration of nicotinamide or succinate prevented both the postirradiation decrease in respiration (in both rats in vivo and brain homogenates in vitro) and the development of cerebral radiation syndrome. These results help to clarify the mechanisms underlying CRS and its metabolic correction.     

Targeted brain delivery of 17 beta-estradiol via nasally administered water soluble prodrugs

The utility of the nasal route for the systemic delivery of 17beta-estradiol was studied using watersoluble prodrugs of 17beta-estradiol. This delivery method was examined to determine if it will result in preferential delivery to the brain. Several alkyl prodrugs of 17beta-estradiol were prepared and their physicochemical properties were determined. In vitro hydrolysis rate constants in buffer, rat plasma, and rat brain homogenate were determined by high-performance liquid chromatography. In vivo nasal experiments were carried out on rats. Levels of 17beta-estradiol in plasma and cerebral spinal fluid (CSF) were determined with radioimunoassay using a gamma counter. The study revealed that the aqueous solubilities of the prodrugs were several orders of magnitude greater than 17beta-estradiol with relatively fast in vitro conversion in rat plasma. Absorption was fast following nasal delivery of the prodrugs with high bioavailability. CSF 17beta-estradiol concentration was higher following nasal delivery of the prodrugs compared to an equivalent intravenous dose. It was determined that water-soluble prodrugs of 17beta-estradiol can be administered nasally. These prodrugs are capable of producing high levels of estradiol in the CSF and as a result may have a significant value in the treatment of Alzheimer's disease.     

Brain temperature measured by 1H-NMR in conjunction with a lanthanide complex.

In vivo data on temperature distributions in the intact brain are scarce, partly due to lack of noninvasive methods for the region of interest. NMR has been exploited for probing a variety of brain activities in vivo noninvasively within the region of interest. Here we report the use of a thulium-based thermometric sensor, infused through the blood, for monitoring absolute temperature in rat brain in vivo by (1)H-NMR and validated by direct temperature measurements with thermocouple wires. Because the (1)H chemical shifts also demonstrate pH sensitivity, detection of multiple resonances was used to measure both temperature and pH simultaneously with high sensitivity. Examination of blood plasma and cerebral spinal fluid samples removed from rats infused with the thermometric sensor suggests that the complex, despite its negative charge, crosses the blood-brain barrier to enter the extracellular milieu. In the future, the thulium-based thermometric sensor may be used for monitoring temperature (and pH) distributions throughout the entire brain, examining response to therapy and evaluating changes induced by alterations in neuronal activity.     

PROTEIN SYNTHESIS IN FRACTIONS FROM ISOLATED BRAIN CELL NUCLEI

Abstract— 1. The incorporation in vivo and in vitro of isotopically labelled leucine into fractions of nuclear proteins from young and adult rat brain was investigated.
2. During post-natal cerebral maturation, the ability of nuclei from brain cells to synthesize proteins decreased. The specific activities of all the fractions of nuclear protein were highest in 3-day-old rats and declined thereafter. Nuclei from adult brain cells exhibited only 10 per cent of the activity found in nuclei from brain cells of 3-day-old rats.
3. The 'residual protein' fraction was most rapidly labelled, peak activity being reached within 30 min after injection. In vitro , the 'residual protein' fraction attained maximum activity within 40 min.
4. The specific activity of the chromatin acidic proteins (HCl-insoluble) was considerably higher than that of the histones both in vivo and in vitro. Histones were the most inert of all the nuclear protein fractions studied.
The possible functional significance of the various protein fractions during the process of cerebral maturation and in the adult brain is discussed.     

A glycosylated complex of gadolinium,a new potential contrast agent for magnetic resonance angiography?

A new low-molecular weight dendrimer-like MRI contrast agent (Gd-D1) has been synthesized and characterized in vitro by proton and oxygen-17 relaxometry. Its pharmacokinetic parameters and biodistribution patterns were evaluated on rats. Its in vitro and in vivo properties, that is, the longitudinal relaxivity (defined as the increase of the water proton longitudinal relaxation rate induced by one millimole per liter of Gd-D1) equal to 5.6s(-1)mM(-1) at 20 MHz and 310 K, the elimination half-time equal to 85 min, and its low accumulation in liver and spleen, underline its potential as a blood-pool MRI contrast agent.     

Effect of aging on phosphate metabolites of rat brain as revealed by the in vivo and in vitro 31P NMR measurements

Changes of phosphate metabolism in brains of neonate, weaning and adult rats were compared using both in vivo and in vitro nuclear magnetic resonance spectra. Ratios of phosphocreatine/nucleoside triphosphate (PCr/NTP) were the same in neonatal brain in both in vivo and in vitro studies, but not in weaning and adult brains. This discrepancy may have resulted from extended cerebral hypoxia due to slowed freezing of the brain by the increased skull thickness and brain mass in the weaning and adult rats. Variations in in vitro extraction condition for this age-related study may lead to systematic errors in the adult rats. Nevertheless, the phosphomonoester/nucleoside triphosphate (PME/NTP) ratios in extracts of brain from neonatal rats were higher than those obtained in vivo. In addition, the glycerophosphorylethanolamine plus glycerophosphorylcholine/nucleoside triphosphate (GPE+GPC/NTP) ratios, which were not measurable in vivo, showed age-dependent increase in extracts of rat brain. Some of the phosphomonoester and phosphodiester molecules in rat brain may be undetectable in in vivo NMR analysis because of their interaction with cellular components. The total in vitro GPE and GPC concentration in brain from neonatal rat was estimated to be 0.34 mmole/g wet tissue.     

Proline promotes decrease in glutamate uptake in slices of cerebral cortex and hippocampus of rats

In the present study we first investigated the in vitro and in vivo effects of proline on glutamate uptake in the cerebral cortex and hippocampus slices of rats. The action of alpha-tocopherol and/or ascorbic acid on the effects elicited by administration of proline was also evaluated. For in vitro studies, proline (30.0 microM and 1.0 mM) was added to the incubation medium. For acute administration, 29-day-old rats received one subcutaneous injection of proline (18.2 micromol/g body weight) or saline (control) and were sacrificed 1 h later. Results showed that addition of proline in the assay (in vitro studies) reduces glutamate uptake in both cerebral structures. Administration of proline (in vivo studies) reduces glutamate uptake in the cerebral cortex, but not in the hippocampal slices of rats. In another set of experiments, 22-day-old rats were pretreated for one week with daily administration of alpha-tocopherol (40 mg/kg) or ascorbic acid (100 mg/kg) or with both vitamins. Twelve hours after the last vitamins injection, rats received a single injection of proline or saline and were killed 1 h later. Pretreatment with alpha-tocopherol and/or ascorbic acid did not prevent the effect of proline administration on glutamate uptake. alpha-Tocopherol plus ascorbic acid prevented the inhibitory effect of acute hyperprolinemia on Na(+),K(+) -ATPase activity in the cerebral cortex of 29-day-old rats. The data indicate that the effect of proline on reduction of glutamate uptake and Na(+),K(+) -ATPase activity may be, at least in part, involved in the brain dysfunction observed in hyperprolinemic patients.     

Increase in receptor binding affinity for nimodipine in the rat brain with permanent occlusion of bilateral carotid arteries

The permanent occlusion of bilateral common carotid arteries (2VO) in rats has been shown to cause progressive and long-lasting cognitive deficits which may be due to impairment of memory retention and/or memory recall process. To clarify the function of voltage dependent calcium channels and the receptor binding of nimodipine by chronic cerebral ischemia, we examined specific (+)-[3H]PN 200-110 binding and the effect of oral administration of nimodipine in brain regions and hearts of rats, at 2 weeks to 4 months after permanent 2VO. There was no significant difference in either dissociation constant (Kd) or maximal number of binding sites (Bmax) for (+)-[3H]PN 200-110 in the cerebral cortex, hippocampus, corpus striatum and thalamus between 2VO and sham rats. In addition, in vitro inhibitory effect of nimodipine on cerebral cortical (+)-[3H]PN 200-110 binding in 2VO rats was similar to that in sham rats. Compared to control rats, oral administration of nimodipine to both 2VO and sham rats at 2 months after permanent 2VO brought about a significant increase in Kd values of specific (+)-[3H]PN 200-110 binding in the cerebral cortex, hippocampus, thalamus and myocardium, and the increase in Kd values was much larger in brain regions of 2VO rats than sham rats. However, the increase in Kd values in the myocardium did not differ between 2VO and sham rats. This observation suggests an increased in vivo binding affinity for nimodipine in chronic ischemic brain. In conclusion, the present study has shown that oral administration of nimodipine may cause a greater occupation in vivo of 1,4-dihydropyridine (DHP) calcium channel antagonist receptors in brains of permanent 2VO rats than in sham rats. Thus, nimodipine may be pharmacologically effective in preventing brain dysfunction due to cerebral ischemia in vivo.     

Effect of hyperphenylalaninaemia on lipid synthesis from ketone bodies by rat brain.

The effect of hyperphenylalaninaemia on the metabolism of ketone bodies in vivo and in vitro by developing rat brain was investigated. The incorporation in vivo of [14C]acetoacetate into cerebral lipids was decreased by both chronic (for 3 days) and acute (for 6h) hyperphenylalaninaemia induced by injecting phenylalanine into 1-week-old rats. In studies in vitro it was observed that the incorporation of the radioactivity from [14C]acetoacetate and 3-hydroxy[14C]butyrate into cerebral lipids was inhibited by phenyl-pyruvate, but not by phenylalanine. Phenylpyruvate also inhibited the incorporation of 3H from 3H2O into lipids by brain slices metabolizing either 3-hydroxybutyrate or acetoacetate in the presence of glucose. These findings suggest that the decrease in the incorporation in vivo of [14C]acetoacetate into cerebral lipids in hyperphenylalaninaemic rats is most likely caused by phenylpyruvate and not by phenylalanine. Phenylpyruvate as well as phenylalanine had no inhibitory effects on ketone-body-catabolizing enzymes, namely 3-hydroxybutyrate dehydrogenase, 3-oxo acid CoA-transferase and acetoacetyl-CoA thiolase, in rat brain. Phenylpyruvate but not phenylalanine inhibited the activity of the 2-oxoglutarate dehydrogenase complex from rat and human brain. These findings suggest that the metabolism of ketone bodies is impaired in brains of untreated phenylketonuric patients, and in turn may contribute to the diminution of mental development and function associated with phenylketonuria.     

Targeted brain delivery of 17β-estradiol via nasally administered water soluble prodrugs

The utility of the nasal route for the systemic delivery of 17β-estradiol was studied using watersoluble prodrugs of 17β-estradiol. This delivery method was examined to determine if it will result in preferential delivery to the brain. Several alkyl prodrugs of 17β-estradiol were prepared and their physicochemical properties were determined. In vitro hydrolysis rate constants in buffer, rat plasma, and rat brain homogenate were determined by high-performance liquid chromatography. In vivo nasal experiments were carried out on rats. Levels of 17β-estradiol in plasma and cerebral spinal fluid (CSF) were determined with radioimunoassay using a gamma counter. The study revealed that the aqueous solubilities of the prodrugs were several orders of magnitude greater than 17β-estradiol with relatively fast in vitro conversion in rat plasma. Absorption was fast following nasal delivery of the prodrugs with high bioavailability. CSF 17β-estradiol concentration was higher following nasal delivery of the prodrugs compared to an equivalent intravenous dose. It was determined that water-soluble prodrugs of 17β-estradiol can be administered nasally. These prodrugs are capable of producing high levels of estradiol in the CSF and as a result may have a significant value in the treatment of Alzheimer's disease. Published: March 25, 2002.     

Application of in vivo ESR spectroscopy to measurement of cerebrovascular ROS generation in stroke

This study used an in vivo ESR spectroscopy/spin probe technique to measure directly the generation of reactive oxygen species (ROS) in the brain after cerebral ischemia-reperfusion. Transient middle cerebral artery occlusion (MCAO) was induced in rats by inserting a nylon thread into the internal carotid artery for 1 h. The in vivo generation of ROS and its location in the brain were analyzed from the enhanced ESR signal decay data of three intra-arterially injected spin probes with different membrane permeabilities. The ESR signal decay of the probe with intermediate permeability was significantly enhanced 30 min after reperfusion following MCAO, whereas no enhancement was observed with the other probes or in the control group. The enhanced in vivo signal decay was significantly suppressed by superoxide dismutase (SOD). Brain damage was barely discernible until 3 h of reperfusion, and was clearly suppressed with the probe of intermediate permeability. The antioxidant MCI-186 completely suppressed the enhanced in vivo signal decay after transient MCAO. These results clearly demonstrate that ROS are generated at the interface of the cerebrovascular cell membrane when reperfusion follows MCAO in rats, and that the ROS generated during the initial stages of transient MCAO cause brain injury.     

Effect of transient hypoxia on oxygenation of the developing rat brain: relationships among haemoglobin saturation, autoregulation of blood flow and mitochondrial redox state

Multi-wavelength, differential spectroscopy was used to examine the effects of transient hypoxia on oxygen delivery and intracellular utilization in the brain of developing rats. The in vivo redox status of cytochrome a,a3 was compared simultaneously with changes in relative haemoglobin saturation and blood volume in the cerebral cortex during lowered FiO2. During hypoxia, neonates maintained their intracellular cytochrome a,a3 redox state as well as did adults, but did so through unusual characteristics, including: (1) maintenance of haemoglobin oxygenation at lower FiO2; (2) regulation of cerebral blood volume at blood pressures below the point at which autoregulation would fail in the adult; and (3) the capacity to tolerate a greater reduction of cytochrome a,a3 relative to haemoglobin desaturation at lowered FiO2. These data suggest that mechanisms which protect the neonate from hypoxic insult involve preservation of oxygen delivery, increased respiratory compensation for metabolic acidosis, and maintenance of cellular energy requirements predominantly through anaerobic metabolism.     

Equilibration of Halothane with Brain Tissue In Vitro: Comparison to Brain Concentrations During Anesthesia

A method was devised for reproducing anesthetic concentrations of halothane in slice and membrane preparations of rat brain in vitro. Rats were anesthetized with varying concentrations of halothane, responsiveness was tested, and brain halothane content was determined by heptane extraction and gas chromatography. The inspired concentration of halothane at which half of all animals were unresponsive was 1.05%. At 1.25% halothane, all animals were unresponsive and brain halothane was determined to be 41 +/- 1.3 nmol/mg lipid. No significant differences in halothane concentration between whole brain and a variety of brain regions were detected. To obtain similar concentrations in vitro, membranes or slices of cerebral cortex were incubated in Krebs-Ringer bicarbonate buffer (KRB) that had been preequilibrated with anesthetic. Halothane equilibrated rapidly with the buffer and the tissues. The partition coefficient between gas and KRB was found to be 0.78, and between brain slices and KRB approximately 12. Slightly lower gas concentrations were necessary in vitro than in vivo to obtain the same tissue levels of anesthetic. Using this method, it was shown that there was no effect of anesthetic concentrations of halothane on the uptake of [3H]norepinephrine or [3H]choline into slices of rat cerebral cortex.     

Metalloendopeptidases EC 3.4.24.15/16 regulate bradykinin activity in the cerebral microvasculature

Bradykinin is a vasoactive peptide that has been shown to increase the permeability of the cerebral microvasculature to blood-borne macromolecules. The two zinc metalloendopeptidases EC (EP 24.15) and EC (EP 24.16) degrade bradykinin in vitro and are highly expressed in the brain. However, the role that these enzymes play in bradykinin metabolism in vivo remains unclear. In the present study, we investigated the role of EP 24.15 and EP 24.16 in the regulation of bradykinin-induced alterations in microvascular permeability. Permeability of the cerebral microvasculature was assessed in anesthetized Sprague-Dawley rats by measuring the clearance of 70-kDa FITC dextran from the brain. Inhibition of EP 24.15 and EP 24.16 by the specific inhibitor N-[1-(R,S)-carboxy-3-phenylpropyl]-Ala-Aib-Tyr-p-aminobenzoate (JA-2) resulted in the potentiation of bradykinin-induced increases in cerebral microvessel permeability. The level of potentiation was comparable to that achieved by the inhibition of angiotensin-converting enzyme. These findings provide the first evidence of an in vivo role for EP 24.15/EP 24.16 in brain function, specifically in regulating alterations in microvessel permeability induced by exogenous bradykinin.     

Characterization of Infant Rat Cerebral Cortical Membrane Proteins Phosphorylated In Vivo: Identification of the ACTH-Sensitive Phosphoprotein B-50

This study on the phosphorylation in vivo of membrane proteins in cerebral cortices of infant rats reports the identification of the adrenocorticotropin (ACTH)-sensitive phosphoprotein B-50 as one of the substrate proteins that are rapidly phosphorylated in vivo following intracisternal administration of 2 mCi [32P]orthophosphate. Rats were sacrificed 30 min after isotope injection. A fraction enriched in membranes, designated neural membranes (NM), was isolated from the cerebral cortices according to the procedure used for preparation of synaptic plasma membranes (SPM) from adult brain. This NM fraction was characterized by electron microscopy. The proteins of NM were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography. Numerous protein bands of NM in infant rat brain were phosphorylated in vivo. Attention was focussed on the 32P-labeled protein bands in the molecular weight range of 47K-67K. In this region one phosphoprotein band (MW 48K) was more highly labeled than the other bands. The electrophoretic behavior of three of these labeled bands, designated a, c, and e (MW 48K, 55K, and 62K, respectively) was compared with that of protein bands that were phosphorylated in vitro in cerebral membranes isolated from noninjected infant rats. The effects of ACTH1-24 and cyclic AMP in the in vitro system were also studied to probe for the presence of specific membrane proteins known to be sensitive to these modulators. On incubation of NM with [gamma-32P)ATP in the presence and absence of ACTH1-24 in vitro, phosphorylation of a 48K protein band was inhibited in a dose-dependent fashion by the neuropeptide. Two-dimensional electrophoretic separation of NM proteins labeled in vivo indicated that the 48K band had an isoelectric point of 4.5, identical to that of the ACTH-sensitive B-50 protein previously identified. Cyclic AMP stimulated phosphorylation in vitro of two protein bands (MW 55K and 59K) in NM preparations. This result indicates that the in vivo labeled band c may correspond to the cyclic AMP-sensitive 55K protein, whereas phosphoprotein band e, labeled in vivo, appears to be different from the cyclic AMP-sensitive 59K protein band. These observations indicate that neural membranes isolated from infant rat cerebral cortices contain a variety of proteins that can be phosphorylated in vivo. Several of these, for example, the 48K protein band, have the properties of synaptic plasma membrane proteins of adult rat brain that have been characterized by their sensitivity to neuromodulators in endogenous phosphorylating systems in vitro.     

Acute Restraint-Mediated Increases in Glutamate Levels in the Rat Brain: An In Vivo <Superscript>1</Superscript>H-MRS Study at 4.7 T

It is well known that a variety of stressors induces a significant alteration in various putative neurotransmitters in the mammalian CNS. However, relatively little attention has been paid on the alteration of central glutamate neurotransmission, which is a major excitatory neurotransmitter in the brain. The present study aimed to determine whether acute restraint stress induces the changes in neurotransmitter level, especially glutamate, in rat brain and to examine whether 1-h recovery time after the termination of stress can revert to its pre-stress state. In vivo ¹H-NMR spectra were acquired from the cerebral cortex and hippocampus (control: N = 10, stress: N = 10, stress + 1 h rest: N = 10) immediately or after 1 h rest from restraint stress. All in vivo proton spectra were automatically analyzed using LCModel. We found that acute restraint stress induced significant increase in glutamate concentrations in the cerebral cortex and the hippocampus of rat. However, the level could not revert to its pre-stress state by the end of 1-h recovery period in cerebral cortex of rats. In addition, glutamine/glutamate ratio, which may function as an index of the glutamatergic neurotransmission, was significantly lower in the cerebral cortex of both stress and 1 h stress + 1 h recovery groups, as compared to control. Our finding may provide important evidence for altered glutamatergic activity after the stress and suggest a potential biochemical marker for eventual diagnosis and/or therapy monitoring in mood disorder.