Effect of small changes in temperature on CA1 pyramidal cells from rat hippocampal slices during hypoxia: implications about the mechanism of hypothermic protection against neuronal damage
P. Amorim et al., Effect of small changes in temperature on CA1 pyramidal cells from rat hippocampal slices during hypoxia: implications about the mechanism of hypothermic protection against neuronal damage, BRAIN RES, 844(1-2), 1999, pp. 143-149
Small reductions in temperature have been shown to improve neurologic recov
ery after ischemia. We have examined the effect of temperature on biochemic
al and physiological changes during hypoxia using rat hippocampal slices as
a model system. The postsynaptic population spike recorded from the CA1 py
ramidal cell region of slices subjected to 7 min of hypoxia with hypothermi
a (34 degrees C) recovered to 73% of its prehypoxic level; slices subjected
to the same period of hypoxia at 37 degrees C did not recover. After 7 min
of hypoxia ATP fell to 48% of its prehypoxic concentration at 34 degrees C
and 30% at 37 degrees C. Potassium fell to 86% during 7 min of hypoxia wit
h hypothermia, this compares to a fall to 58% at 37 degrees C. The increase
in sodium after 7 min of hypoxia was also attenuated by hypothermia (133%
vs. 163% of its prehypoxic concentration). When the hypoxic period was shor
tened to 3 min (37 degrees C) the population spike recovered to 94%. If the
temperature was increased to 40 degrees C there was only 7% recovery of th
e population spike after 3 min of hypoxia. With hyperthermia (40 degrees C)
, ATP fell to 33% after 3 min of hypoxia, this compares to 81% at normother
mia. Potassium fell to 76% after 3 min of hypoxia with hyperthermia, this c
ompares to 91% at 37 degrees C. Sodium concentrations increased with hypert
hermia before hypoxia, at 3 min of hypoxia there was no significant differe
nce between the hyperthermic and normothermic tissue; there was a large inc
rease in sodium with hyperthermia after 5 min of hypoxia (209% vs. 146%). W
e conclude that the improved recovery after hypothermic hypoxia is at least
in part due to the attenuated changes in ATP, potassium and sodium during
hypoxia and that the worsened recovery with hyperthermia is due to an exace
rbation of the change in ATP, potassium and sodium concentrations during hy
poxia. (C) 1999 Published by Elsevier Science B.V. All rights reserved.