Reperfusion Injury in Glial Cells: The Phenomenon and Mechanism of "Calcium Paradox".
10.4097/kjae.1996.30.4.384
- Author:
Myung Hee KIM
1
;
Byung Dal LEE
;
Yu Hong KIM
;
Baek Hyo SHIN
Author Information
1. Department of Anesthesiology, Samsung Medical Center, Seoul, Korea.
- Publication Type:Original Article
- Keywords:
Brain;
ischmia;
cells;
glia;
viability;
ions;
calcium
- MeSH:
Astrocytoma;
Brain;
Calcium;
Cell Line;
Cell Survival;
Central Nervous System;
Fura-2;
Humans;
Ions;
Ligases;
Neuroglia*;
Neurons;
Photometry;
Reperfusion Injury*;
Reperfusion*
- From:Korean Journal of Anesthesiology
1996;30(4):384-391
- CountryRepublic of Korea
- Language:Korean
-
Abstract:
BACKGROUND: Mechanisms of secondary injury(post-ischemic injury) in the central nervous system have recently reported in a vast of amount of experiments. Among many factors which give rise to post-ischemic neuronal damage, glial deterioration probably mediated by calcium paradox, could be another of the aggravating deleterious factors to the already ischemic neurophil. METHODS: here we have designed experiment to investigate calcium paradox in astroglial cell line, human astrocytoma U1242MG. Intracellular calcium alterations in experimental cells were monitored by using calcium indicating dye fura-2 and epifluorescent photometry system. RESULTS: Intracellular free calcium changes during reperfusion phase after exposure to low calcium led to a prompt increase in intracelluar calcium level after 10 and 30 minutes. The way of calcium entry during the reperfusion phase was mediated by the reverse mode of NA+/Ca2+ exchanger. Cells that had a reduction of reperfusate calcium to 10uM increased cell viability. Also we observed an inverse relationship between major enzymatic activity in the astrocytoma cells(i.e., gultamine synthetase activity) and the duration of reperfusion in the the same protocols. CONCLUSIONS: A relatively small amount of intracellular clcium increase by the reverse mode of Na+/Ca2+ exchanger during the reperfusion period is related to a limitation of enzyme activity and viability 24hours later.
