K. Alici et al., EFFECTS OF GLUCOSE DEPRIVATION IN AREA CA1 OF HIPPOCAMPAL SLICES FROMADULT AND JUVENILE RATS, Developmental brain research, 107(1), 1998, pp. 71-80
The effects of glucose deprivation were studied in area CA1 of rat hip
pocampal slices obtained from adult and juvenile rats (postnatal days
(PN) 6-8; 13-15; 20-22). Ion-sensitive microelectrodes were employed t
o monitor baseline and stimulus-induced changes in [Ca2+](0), [K+](0)
and field potentials. In slices from juvenile animals, the decline of
baseline [Ca2+](0) during glucose deprivation was delayed in compariso
n to adult slices. The minimum in [Ca2+](0) was reached in slices from
adult rats after 50 +/- 8.5 min, in slices from PN 20-22 after 69 +/-
9 min, and in slices from PN 13-15 after 111 +/- 11 min. In slices fr
om PN 6-8, [Ca2+](0) did not decrease significantly even during prolon
ged exposure of up to 4 h. Alvear stimulation failed to evoke any stim
ulus-induced responses in field potentials, rises in [K+](0) and decre
ases in [Ca2+](0) after the minimum in [Ca2+](0) was reached in slices
from all age groups except for slices from PN 6-8. In the older age g
roups, afferent fibre stimulation still induced afferent volleys and s
mall decreases in [Ca2+](0), which were about 20-30% of those under co
ntrol conditions, suggesting that presynaptic fibres and endings maint
ained some of their functional properties even after prolonged glucose
deprivation. In contrast, stimulation of the stratum radiatum failed
to evoke synaptic responses in slices from PN 6-8, presumably due to a
failure in synaptic transmission. These findings confirm that similar
to hypoxia during the early postnatal stage, hippocampal neurons are
much more resistant to glucose deprivation. The findings also show tha
t during early postnatal development, glucose deprivation may result i
n a block of synaptic transmission independent of postsynaptic excitab
ility. (C) 1998 Elsevier Science B.V.