Stanley R. Nelson

A possible role for taurine in osmoregulation within the brain

Abstract: Intracranial microdialysis was used to measure changes in extracellular amino acids within the rat brain during local osmotic alteration of the extracellular micro‐environment or during systemic water intoxication. Increased cellular hydration produced by either of these methods was accompanied by a marked increase in extracellular taurine levels without affecting the other amino acids measured. With local osmotic alteration, this increase was osmolarity dependent and reversible. The specificity, sensitivity, and reversibility of the increase in extracellular taurine strongly suggest a functional role in osmoregulation in the brain under normal as well as pathological conditions.

Changes in extracellular amino acids during soman- and kainic acid-induced seizures

Extracellular amino acid levels in the rat piriform cortex, an area highly susceptible to seizure‐induced neuropathology, were determined by means of intracranial microdialysis. Seizures were induced by systemic administration of either soman (O‐1,2,2‐trimethylpropyl methylphosphonofluoridate), a potent inhibitor of acetylcholinesterase, or the excitotoxin kainic acid. Extracellular glutamate levels increased in animals with seizures shortly after administration of either convulsant, but this change was statistically significant only in the case of soman‐treated animals. Extracellular taurine levels increased markedly, reaching two‐and fourfold baseline levels during the second hour of soman‐and kainic acid‐induced seizures, respectively. Taurine levels did not increase in the subpopulation of soman‐treated animals without seizures, a finding indicating that elevation of extracellular taurine level is seizure related. Thus, we propose that taurine efflux may be a physiological cellular response to neuronal changes produced by excito‐toxic chemicals, either directly or as a consequence of seizures.

Ketamine-induced Changes in Regional Glucose Utilization in the Rat Brain

Ketamine appears to induce both excitatory and depressant actions in the brain; however, it is not clear which regions are affected. The 2-deoxyglucose functional mapping method of Sokoloff et al. was used to determine regional variations in metabolic activity of rat brain caused by injection of ketamine, 25-75 mg, intramuscularly. To compare the effects of ketamine with those of hippocampal-induced seizures, the 2-deoxyglucose method was used, following injection of penicillin G, 400-800 units, into the hippocampus. The findings from five control, seven ketamine-treated, and three penicillin G-treated rats are given. Ketamine caused a significant increase of metabolic activity in the hippocampal sulci and a decrease of activity in the medial geniculate and the inferior colliculus. Similar changes were found with hippocampal seizures caused by penicillin. The inhibition of the regions associated with sensory systems (medial geniculate and inferior colliculus) may account in part for the anesthetic action of ketamine, while the intense activity of the hippocampus may be related to the excitatory manifestations. The results indicate that ketamine produces seizures in the hippocampus, which in turn inhibit auditory and visually associated nuclei. Thus, the anesthesia may follow from the sensory depression and the cataleptic phenomena may be related to the hippocampal excitation.

Hypoxia preconditioning attenuates brain edema associated with kainic acid-induced status epilepticus in rats.

Kainic acid (KA)-induced seizures elicit edema associated with necrosis in susceptible brain regions (e.g., piriform cortex and hippocampal CA1 and CA3 regions). To test the hypothesis that hypoxia preconditioning protects against KA-induced edema formation, adult male rats were exposed to a 9% O2, 91% N2 atmosphere for 8 h. KA (14 mg/kg, i.p.) was administered 1, 3, 7, or 14 days later. Regional analysis of edema indicated that hypoxia exposure attenuated edema formation in piriform and frontal cortices and hippocampus when KA was given 1, 3, or 7 days later but not 14 days after hypoxia. Cycloheximide (2 mg/kg s.c.) given 1 h prior to hypoxia prevented the protective effect of hypoxia on KA-induced edema attenuation in the piriform cortex and hippocampus. Thus, hypoxic challenge induces a general adaptive response that protects against the seizure-associated pathophysiology, with no direct relationship to seizure intensity. This response may involve stress-related transcription factors and effector proteins.

Soman induced changes in brain regional glucose use

Soman, a potent central acetylcholine esterase inhibitor, has a greater impact on brain regional glucose use than other organophosphates, such as diisopropylfluorophosphate (DFP) or phospholinium iodide. At near-lethal doses soman induced explosive persistent seizures that were associated with a greater than fourfold increase of glucose use in many brain structures. Single near-lethal doses of soman lead to conspicuous neuronal damage and a marked reduction in brain activity, 1 to 3 days after exposure. When soman (2 X LD50) was given to TAB (an antidotal mixture of trimedoxime, atropine, and benactyzine ) pretreated rats, there was a greater than twofold reduction of glucose use in almost every brain region. We suggest that soman seizures are mediated via activation of muscarinic receptors; also, the substantia nigra has a key role in the initiation/propagation of seizures. Soman has in addition, a depressive effect on some brain components which appears not to involve muscarinic receptors. We suggest that the conspicuous pathology that follows a single, near-lethal dose of soman results from a depletion of energy flow along with an influx of Ca2+ which sets into motion a cascade of destructive reactions, such as activation of proteases.

The osmotic/calcium stress theory of brain damage: Are free radicals involved?

This overview presents data showing that glucose use increases and that excitatory amino acids (i.e., glutamate, aspartate), taurine and ascorbate increase in the extracellular fluid during seizures. During the cellular hyperactive state taurine appears to serve as an osmoregulator and ascorbate may serve as either an antioxidant or as a pro-oxidant. Finally, a unifying hypothesis is given for seizure-induced brain damage. This unifying hypothesis states that during seizures there is a release of excitatory amino acids which act on glutamatergic receptors, increasing neuronal activity and thereby increasing glucose use. This hyperactivity of cells causes an influx, of calcium (i.e. calcium stress) and water movements (i.e., osmotic stress) into the cells that culminate in brain damage mediated by reactive oxygen species.

The Influence of Droperidol, Diazepam, and Physostigmine on Ketamine-induced Behavior and Brain Regional Glucose Utilization in Rat

Diazepam and droperidol are used clinically with ketamine anes-thesia to reduce emergence hallucinations, vivid unpleasant dreams, and hyperexcitability. Also, there are reports that the recovery time from ketamine anesthesia is shortened after administration of physostigmine. The authors investigated the influence of diazepam, droperidol, and physostigmine pretreatment on ketamine anesthesia by measuring the brain regional activity and behavioral responses in rat. The 2-deoxyglucose brain local metabolic mapping method was used to determine regional brain functional activity. The recovery of tail flick response and righting reflex from ketamine anesthesia were prolonged by diazepam and by droperidol pretreatment, but the duration of agitation was shortened; physostigmine caused no significant change in any of these responses. Ketamine alone caused a statistically significant (P < 0.05) increase in the rate of glucose utilization along the hippocampal molecular layer (control 87 μmol·100 g-1·min-1; ketamine 166 μmol·100 g-1·min-1) and a decrease in medial geniculate (25%), inferior colliculus (37%), and lateral habenula (18%). Diazepam, droperidol, and physostigmine pretreatment did not significantly alter any ketamine-induced glucose use changes, except for a decreased activity in hippocampal molecular layer with diazepam pretreatment (20%) and an increased activity in the lateral habenula with droperidol pretreatment (94%, P < 0.05). These findings corroborate the “epileptogenic” character of ketamine anesthesia and implicate the hippocampus as a major focus. The reduced activity in the hippocampus induced by diazepam pretreatment and the increased activity in the lateral habenula induced by droperidol pretreatment may be factors in the clinical reduction of ketamine hyperexcitability and hallucination by these drugs.

Soman-induced convulsions affect the inositol lipid signaling system: potentiation by lithium; attenuation by atropine and diazepam.

Effects of atropine or diazepam pretreatment on soman-induced convulsions and brain phosphoinositide (PI) metabolism, as assessed by brain regional inositol-1-phosphate (IP1) levels, were studied in saline and LiCl-pretreated rats. IP1, an intermediate in PI turnover, was measured in cortex, caudate, thalamus, hippocampus, and cerebellum. Soman (100 micrograms/kg; sc) produced convulsions in 63% of the saline-pretreated rats, whereas with LiCl pretreatment all rats exposed to 100 micrograms/kg of soman had tonic-clonic convulsions. Thus, LiCl pretreatment potentiated soman-induced convulsions. Tissue IP1 increased severalfold in soman-exposed convulsing rats with the highest increases being in frontal cortex and caudate. In contrast, no marked increases of IP1 occurred in similarly treated nonconvulsing rats. LiCl treatment itself increased IP1 levels without causing convulsions. In LiCl-pretreated rats, soman again markedly elevated IP1 levels above LiCl alone in convulsing rats, whereas no such effect occurred in nonconvulsing rats. In LiCl-pretreated rats, the increased IP1 levels associated with soman-induced convulsions were greatest in hippocampus and piriform cortex. Thus, LiCl appears to lower the threshold for the spread of seizure activity through limbic structures, thereby potentiating cholinergic-induced convulsions. Diazepam and atropine both blocked soman-induced convulsions, and brain regional IP1 elevations were concomitantly abolished as well. These results indicate that soman-induced convulsions involve the inositol lipid signaling system. This involvement is potentiated by lithium but attenuated by atropine and diazepam.

A global hypoxia preconditioning model: neuroprotection against seizure-induced specific gravity changes (edema) and brain damage in rats

Hypoxia preconditioning states that a sublethal hypoxia episode will afford neuroprotection against a second challenge in the near future. We describe and discuss a procedure for the development of global hypoxia preconditioning in adult male Wistar rats, using a mildly hypoxic (9% O(2), 91% N(2)) atmospheric exposure of 8 h. The persistence of neuroprotection was analyzed using a kainic acid (KA) model of brain injury. Rats were challenged with KA (14 mg/kg, i.p.) on 1-14 days post-hypoxia. The effects of hypoxia preconditioning on seizure score, weight loss, brain edema and histopathology were assessed. Brain edema, predominantly of vasogenic origin, was measured 24 h after KA administration using a reproducible and quantitative method based on the specific gravities of tissue samples. A density gradient column (1.0250-1.0650 g/cm(3)) comprised of kerosene and bromobenzene was used to assess the presence of edema in regions involved in seizure initiation and propagation that are normally extensively damaged (i.e., piriform cortex and hippocampus). Specific gravities of tissues were calculated through extrapolation with known NaCl standards. We found that hypoxia preconditioning prevented the formation of edema in these brain regions when KA challenge was given 1, 3, and 7, but not 14 days post-hypoxia exposure. Furthermore, neuroprotection was observed in animals that had robust seizures. The described procedure may be used to examine the neuroprotective mechanisms induced by global hypoxia preconditioning against many subsequent challenges reflecting a variety of experimental models of brain injury, and will provide a better understanding of the brain response to hypoxia and stress.

Nitric oxide detection with intracerebral microdialysis: Important considerations in the application of the hemoglobin-trapping technique

Nitric oxide (NO.) is involved in processes such as neurotransmission, memory, brain injury, vessel relaxation, etc. To study the functional and pathological roles of NO. in the brain, a reliable method to monitor NO. directly is needed. Since oxyhemoglobin (Hb) has a high affinity for NO. and upon binding is converted quantitatively to methemoglobin (MetHb), spectrophotometry of Hb conversion to MetHb can give a credible measurement of NO. concentration. Although this method is especially promising for in vivo microdialysis, factors can influence the reproducibility and stability, making it difficult to obtain reliable results at low NO. levels. Evaluation of the diffusion rates of NO. and sodium nitroprusside across the microdialysis membrane indicates that NO. readily diffuses through the membrane. By taking into account protein degradation and Hb autoxidation as well as integrating the difference spectra, this assay has a practical differential detection limit of about 7 nM (0.4 pmol) in vivo. We evaluated this method in anesthetized and awake rats by measuring the release of NO. induced by the excitotoxin kainic acid (13 mg/kg, i.p.). A protocol with detailed analytical parameters for NO. monitoring in neurobiological research is given.