Preischemic hyperglycemia-aggravated damage: Evidence that lactate utilization is beneficial and glucose-induced corticosterone release is detrimental

Aerobic lactate utilization is crucial for recovery of neuronal function posthypoxia in vitro. In vivo models of cerebral ischemia pose a conceptual challenge when compared to in vitro models. First, the glucose paradox of cerebral ischemia, namely, the aggravation of delayed neuronal damage by prei...

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Bibliographic Details
Published in:Journal of neuroscience research 2001-12, Vol.66 (5), p.782-789
Main Authors: Schurr, Avital, Payne, Ralphiel S., Miller, James J., Tseng, Michael T.
Format: Article
Language:English
Subjects:
Adenosine Diphosphate - metabolism
Adenosine Monophosphate - metabolism
Animals
Blood Glucose - drug effects
Blood Glucose - physiology
Brain Ischemia - metabolism
Brain Ischemia - physiopathology
cerebral ischemia
corticosterone
Corticosterone - blood
Corticosterone - secretion
Coumaric Acids - pharmacology
Cyclic AMP - metabolism
Electric Stimulation
Enzyme Inhibitors - pharmacology
Glucose - metabolism
Glucose - pharmacology
Heart Arrest, Induced
Hippocampus - injuries
Hippocampus - metabolism
Hippocampus - physiopathology
hyperglycemia
Hyperglycemia - chemically induced
Hyperglycemia - metabolism
Hyperglycemia - physiopathology
lactate
Lactic Acid - metabolism
Male
Metyrapone - pharmacology
Nerve Degeneration - metabolism
Nerve Degeneration - physiopathology
neuronal damage
Organ Culture Techniques
Rats
Rats, Sprague-Dawley
Recovery of Function - physiology
Reperfusion Injury - metabolism
Reperfusion Injury - physiopathology
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Summary:Aerobic lactate utilization is crucial for recovery of neuronal function posthypoxia in vitro. In vivo models of cerebral ischemia pose a conceptual challenge when compared to in vitro models. First, the glucose paradox of cerebral ischemia, namely, the aggravation of delayed neuronal damage by preischemic hyperglycemia, cannot be reproduced in vitro. Second, in vitro elevated glucose levels protect against ischemic (hypoxic) damage, an outcome that has seldom been reproduced in vivo. Employing a rat model of cardiac‐arrest‐induced transient global cerebral ischemia (TGI), we found that hyperglycemic conditions, when induced 120–240 min pre‐TGI, significantly reduced post‐TGI neuronal damage as compared to normoglycemic conditions. In contrast, hyperglycemia, when induced 15–60 min pre‐TGI, significantly aggravated post‐TGI neuronal damage. Brain lactate levels in rats loaded with glucose either 15 min or 120 min pre‐TGI were significantly and equally higher than those of control, saline‐injected rats. The beneficial effect of 120 min pre‐TGI glucose loading was abolished by lactate transport inhibition. A significant increase in blood corticosterone (CT) levels was observed upon glucose loading that peaked at 15–30 min and returned to baseline levels by 60–120 min. When rats loaded with glucose 15 min pre‐TGI were treated with metyrapone, a CT synthesis inhibitor, a significantly lower degree of delayed neuronal damage in comparison to both untreated, 15 min glucose‐loaded rats and normoglycemic, control rats was observed. Thus, although elevated levels of brain lactate cannot explain the glucose paradox of cerebral ischemia, hyperglycemia‐induced, short‐lived elevation in CT blood levels could. More importantly, lactate appears to play a crucial role in improving postischemic outcome. © 2001 Wiley‐Liss, Inc.
ISSN:0360-4012
1097-4547
DOI:10.1002/jnr.10065