BIOMAT Database Logo BIOMAT Database Logo

Effects of inhalation anesthetics of Kainate-induced glutamate release from cerebellar granule cells. 1996

S Zhu, and R C Baker
Department of Pharmacology and Toxicology, University of Mississippi Medical Center, Jackson, 39216-4505, USA.

The mechanisms of inhalation anesthesia may include inhibiting non NMDA excitatory amino acid neurotransmission. This possibility was addressed by measuring the effect of three anesthetics at clinically relevant concentration on kainate-induced glutamate release from cerebellar granule cells. Cerebellar granule cells were obtained from 8-day-old SD rats and maintained in vitro for 9-14 days. Medium glutamate concentrations were measured by HPLC after 90 minutes incubation with kainate or NMDA. Inhalation anesthetics were introduced by holding the cells under a continuous flow of air/anesthetic mixtures. All anesthetics tested did not effect NMDA-induced glutamate release. Halothane (1 MAC), isoflurane (1 MAC) inhibited kainate-induced glutamate release from the cultured cells whereas enflurane (1 MAC) had no effect on kainate-induced glutamate release. The difference between enflurane and the other anesthetics tested suggests that anesthesia is dependent on more than one process and the extent at which each function is perturbed is dependent on the specific anesthetic used. Halothane inhibition of kainate-induced glutamate release was not reversible by increasing kainate concentration, indicating halothane does not directly compete with kainate at its receptor.

UI MeSH Term Description Entries
D007608 Kainic Acid (2S-(2 alpha,3 beta,4 beta))-2-Carboxy-4-(1-methylethenyl)-3-pyrrolidineacetic acid. Ascaricide obtained from the red alga Digenea simplex. It is a potent excitatory amino acid agonist at some types of excitatory amino acid receptors and has been used to discriminate among receptor types. Like many excitatory amino acid agonists it can cause neurotoxicity and has been used experimentally for that purpose. Digenic Acid,Kainate,Acid, Digenic,Acid, Kainic
D007700 Kinetics The rate dynamics in chemical or physical systems.
D009475 Neurons, Afferent Neurons which conduct NERVE IMPULSES to the CENTRAL NERVOUS SYSTEM. Afferent Neurons,Afferent Neuron,Neuron, Afferent
D002478 Cells, Cultured Cells propagated in vitro in special media conducive to their growth. Cultured cells are used to study developmental, morphologic, metabolic, physiologic, and genetic processes, among others. Cultured Cells,Cell, Cultured,Cultured Cell
D002531 Cerebellum The part of brain that lies behind the BRAIN STEM in the posterior base of skull (CRANIAL FOSSA, POSTERIOR). It is also known as the "little brain" with convolutions similar to those of CEREBRAL CORTEX, inner white matter, and deep cerebellar nuclei. Its function is to coordinate voluntary movements, maintain balance, and learn motor skills. Cerebella,Corpus Cerebelli,Parencephalon,Cerebellums,Parencephalons
D003594 Cytoplasmic Granules Condensed areas of cellular material that may be bounded by a membrane. Cytoplasmic Granule,Granule, Cytoplasmic,Granules, Cytoplasmic
D004347 Drug Interactions The action of a drug that may affect the activity, metabolism, or toxicity of another drug. Drug Interaction,Interaction, Drug,Interactions, Drug
D000818 Animals Unicellular or multicellular, heterotrophic organisms, that have sensation and the power of voluntary movement. Under the older five kingdom paradigm, Animalia was one of the kingdoms. Under the modern three domain model, Animalia represents one of the many groups in the domain EUKARYOTA. Animal,Metazoa,Animalia
D016202 N-Methylaspartate An amino acid that, as the D-isomer, is the defining agonist for the NMDA receptor subtype of glutamate receptors (RECEPTORS, NMDA). N-Methyl-D-aspartate,NMDA,N-Methyl-D-aspartic Acid,Acid, N-Methyl-D-aspartic,N Methyl D aspartate,N Methyl D aspartic Acid,N Methylaspartate
D017207 Rats, Sprague-Dawley A strain of albino rat used widely for experimental purposes because of its calmness and ease of handling. It was developed by the Sprague-Dawley Animal Company. Holtzman Rat,Rats, Holtzman,Sprague-Dawley Rat,Rats, Sprague Dawley,Holtzman Rats,Rat, Holtzman,Rat, Sprague-Dawley,Sprague Dawley Rat,Sprague Dawley Rats,Sprague-Dawley Rats

Related Publications

S Zhu, and R C Baker
Selective release of glutamate from cerebellar granule cells differentiating in culture.
December 1982, Proceedings of the National Academy of Sciences of the United States of America,
S Zhu, and R C Baker
Low calcium-induced release of glutamate results in autotoxicity of cerebellar granule cells.
April 1990, Brain research,
S Zhu, and R C Baker
Release of taurine from cultured cerebellar granule cells and astrocytes: co-release with glutamate.
January 1989, Neuroscience,
S Zhu, and R C Baker
Nitric oxide inhibits depolarization-evoked glutamate release from rat cerebellar granule cells.
March 2007, Nitric oxide : biology and chemistry,
S Zhu, and R C Baker
Evidence for evoked release of adenosine and glutamate from cultured cerebellar granule cells.
September 1989, Neurochemical research,
S Zhu, and R C Baker
Quinolinic acid protects rat cerebellar granule cells from glutamate-induced apoptosis.
January 1998, Neuroscience letters,
S Zhu, and R C Baker
Cycloheximide abolishes pertussis toxin induced increase in glutamate release from cerebellar granule neurones.
May 1993, Biochemical Society transactions,
S Zhu, and R C Baker
Cycloheximide abolishes pertussis toxin-induced increase in glutamate release from cerebellar granule neurones.
January 1994, Neuroscience letters,
S Zhu, and R C Baker
Adenosine inhibits glutamate stimulated [(3)H]d-aspartate release from cerebellar granule cells.
January 1987, Neurochemistry international,
S Zhu, and R C Baker
Effects of calcium channel antagonists on calcium entry and glutamate release from cultured rat cerebellar granule cells.
December 1995, Journal of neurochemistry,
Copied contents to your clipboard!