University of North Florida
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Stuart Chalk, Ph.D.
Department of Chemistry
University of North Florida
Phone: 1-904-620-1938
Fax: 1-904-620-3535
Email: schalk@unf.edu
Website: @unf

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Journal of Neurochemistry

  • Publisher: Wiley
  • FAD Code: JNCH
  • CODEN: JONRA9
  • ISSN: 0022-3042
  • Abbreviation: J. Neurochem.
  • DOI Prefix: 10.1111/jnc
  • Language: English
  • Comments: Fulltext from 1956 V1

Citations 3

"Quantitative On-line Monitoring Of Hippocampus Glucose And Lactate Metabolism In Organotypic Cultures Using Biosensor Technology"
J. Neurochem. 2003 Volume 85, Issue 2 Pages 399-408
Jan Bert Gramsbergen,* Gea Leegsma-Vogt, Kor Venema, Jens Noraberg and Jakob Korf

Abstract: Quantitative glucose and lactate metabolism was assessed in continuously perfused organotypic hippocampal slices under control conditions and during exposure to glutamate and drugs that interfere with aerobic and anaerobic metabolism. On-line detection was possible with a system based on slow perfusion rates, a half-open (medium/air interface) tissue chamber and a flow injection analytic system equipped with biosensors for glucose and lactate. Under basal conditions about 50% of consumed glucose was converted to lactate in hippocampal slice cultures. Using medium containing lactate (5 mM) instead of glucose (5 mM) significant lactate uptake was observed, but this uptake was less than the net uptake of lactate equivalents in glucose-containing medium. Glucose deprivation experiments suggested lactate efflux from glycogen stores. The effects of drugs compromising or stimulating energy metabolism, i.e. 2-deoxyglucose, 3-nitropropionic acid, α-cyano-4-hydroxycinnamate, l-glutamate, d-asparate, ouabain and monensin, were tested in this flow system. The data show that maintaining Na+ and K+ gradients consumed much of the energy but do not support the hypothesis that l-glutamate stimulates glycolysis in hippocampal slice cultures.
Glucose Lactate Hippocampus Perfusate Sensor Interferences

"ATP-sensitive Potassium Channels And Local Energy Demands In The Rat Hippocampus: An In Vivo Study"
J. Neurochem. 1993 Volume 61, Issue 3 Pages 949-954
Fellows LK, Boutelle MG, Fillenz M.

Abstract: Microdialysis coupled with an enzyme-based flow injection analysis was used to monitor brain extracellular lactate and glucose in the freely moving rat. Glucose levels reflect the balance between supply from the blood and local utilisation, and lactate efflux indicates the degree of local nonoxidative glucose metabolism. Local application of tolbutamide, a blocker of the ATP-sensitive potassium channel, decreased extracellular glucose and lactate levels in the hippocampus but not in the striatum. The increase in glucose and lactate levels following mild behavioural stimulation was also reduced by tolbutamide in the hippocampus. Similar effects on both basal and stimulated lactate levels were obtained with local application of 10 mM glucose. These results indicate that ATP-sensitive potassium channels are active under physiological conditions in the hippocampus and that the effects of tolbutamide can be mimicked by physiological glucose levels.
Lactate Glucose Brain Dialysis In vivo monitoring

"Physiological Stimulation Increases Nonoxidative Glucose Metabolism In The Brain Of The Freely Moving Rat"
J. Neurochem. 1993 Volume 60, Issue 4 Pages 1258-1263
Fellows LK, Boutelle MG, Fillenz M.

Abstract: The effects of mild stress on nonoxidative glucose metabolism were studied in the brain of the freely moving rat. Extracellular lactate levels in the hippocampus and striatum were monitored at 2.5-min intervals with microdialysis coupled with an enzyme-based flow injection analysis system. Ten minutes of restraint stress led to a 235% increase in extracellular lactate levels in the striatum. A 5-min tail pinch caused an increase of 193% in the striatum and 170% in the hippocampus. Local application of tetrodotoxin in the striatum blocked the rise in lactate following tail pinch and inhibited the subsequent clearance of lactate from the extracellular fluid. Local application of the noncompetitive N-methyl-D-aspartate receptor antagonist MK-801 had no effect on the tail pinch-stimulated increase in lactate in the striatum. These results show that mild physiological stimulation can lead to a rapid increase in nonoxidative glucose metabolism in the brain.
Glucose Brain Dialysis