Krnjevic_1982_Can.J.Physiol.Pharmacol_60_1643

In urethane-anaesthetized rats, ion-selective microelectrodes recorded changes in extracellular K+ and Ca2+ concentrations (delta[K+]omicron and delta[Ca2+]omicron) in pyramidal layers of the hippocampus (mostly in area CA1), which were evoked by fimbrial-commissural stimulation. [K+]omicron increased linearly with frequency of stimulation up to a critical frequency, in the range of 2-5 Hz, where bursts of population spikes appeared, and then rose rapidly to reach a ceiling of 9-12 mM. During continued stimulation, [K+]omicron remained well above the resting level of about 3.0 mM. At the end of stimulation [K+]omicron returned to the base line with a half time of 4-8 s, and a minor undershoot of congruent to 0.5 mM was detectable for 1-2 min. When stimulating at frequencies above the critical value, a sharp fall in [Ca2+]omicron (by an average of one-third below the mean resting level of 1.4 mM) consistently started 1-5 s after the onset of the rapid phase of delta[K+]omicron. [Ca2+]omicron typically reached a minimum in 5-10 s and immediately started to return towards the base line. The recovery of [Ca2+]omicron was often accelerated by an overshoot of up to 0.3 mM; this was followed by a delayed phase of low [Ca2+]omicron for another 2-3 min. During prolonged stimulation at frequencies near 7 Hz, both [Ca2+]omicron and [K+]omicron fluctuated periodically, in time with the appearance and disappearance of bursts of population spikes. Comparable observations were made in area CA2-3 (just external to CA1); in the deeper areas of CA3, in CA4, and in the dentate gyrus, major changes in [K+]omicron and [Ca2+]omicron (as well as bursts of population spikes) were evoked only by prolonged fimbrial stimulation at higher frequencies (congruent to 10 Hz). Thus, although adequate repetitive stimulation of fimbrial-commissural inputs evokes sharp but opposite changes in [K+]omicron and [Ca2+]omicron, the fall in [Ca2+]omicron is consistently much briefer than the rise in [K+]omicron, presumably because of the evanescent character of postsynaptic Ca2+ spikes.