Single-cell activity and synchronous bursting in the rat hippocampus during waking behavior and sleep

“…These two baseline values of the 5-HT-depleted rats were significantly higher than those of control rats (event The other parameters, spikes/event and CS%, were not different between the two groups (spikes/event: control 2.02 Ϯ 0.05 vs. PCPA 2.00 Ϯ 0.07, CS%: control 65.97 Ϯ 3.54% vs. PCPA 62.90 Ϯ 3.21%). The event rate of the control was comparable with the rates previously reported during this awake immobile behavioral state (Suzuki and Smith 1985;Tada et al 1999). …”

“…Similarly, PCPA and NAN-190 are expected to reduce the firing activity through increasing wakefulness (Li and Satinoff 1992;Neckelmann et al 1996) whereas PCPA increased and NAN-190 unchanged the firing activity (Figure 2) (Tada et al 1999). Moreover, it has been demonstrated that a selective 5-HT 1A agonist 8-hydroxy-2-(di-n-propylamino)tetralin (8-OH-DPAT) increases the wakefulness (Monti and Hantos 1994) and decreases the firing activity (Tada et al 1999), which is consistent with the behavioral correlates (Suzuki and Smith 1985). Taken together, the actual influences of the drugs on the firing activity were extremely different from the expectable indirect influences through the effects on the behavioral states.…”

“…Previous studies have demonstrated that PCPA and NAN-190 decrease slow wave sleep and increase wakefulness (Li and Satinoff 1992;Neckelmann et al 1996), and that ritanserin increases slow wave sleep and decreases waking (Bjorvatn and Ursin 1990;Silhol et al 1992). Suzuki and Smith (1985) have shown that the pyramidal neurons are most active during slow wave sleep, slightly less active during a quiet awake state, and least active during an active awake condition and paradoxical sleep. Thus, one might assume that the present observations reflect indirect influences of the tested drugs through their direct effects on the states of the animals.…”

“…Thus, one might assume that the present observations reflect indirect influences of the tested drugs through their direct effects on the states of the animals. Given the correlation between the behavioral states and the firing activity (Suzuki and Smith 1985), ritanserin is expected to increase the firing activity since this drug could increase slow wave sleep and decrease wakefulness (Bjorvatn and Ursin 1990;Silhol et al 1992). However, ritanserin did not change the firing activity (data not shown).…”

“…The criteria were generated on the basis of the previous studies (Fox and Ranck 1975;Suzuki and Smith 1985). Recordings with a low signal-to-noise ratio ( Ͻ 5:1) were not employed for data analysis.…”

Endogenous 5-HT Tonically Inhibits Spontaneous Firing Activity of Dorsal Hippocampus CA1 Pyramidal Neurons Through Stimulation of 5-HT1A Receptors in Quiet Awake Rats In Vivo Electrophysiological Evidence

“…These two baseline values of the 5-HT-depleted rats were significantly higher than those of control rats (event The other parameters, spikes/event and CS%, were not different between the two groups (spikes/event: control 2.02 Ϯ 0.05 vs. PCPA 2.00 Ϯ 0.07, CS%: control 65.97 Ϯ 3.54% vs. PCPA 62.90 Ϯ 3.21%). The event rate of the control was comparable with the rates previously reported during this awake immobile behavioral state (Suzuki and Smith 1985;Tada et al 1999). …”

“…Similarly, PCPA and NAN-190 are expected to reduce the firing activity through increasing wakefulness (Li and Satinoff 1992;Neckelmann et al 1996) whereas PCPA increased and NAN-190 unchanged the firing activity (Figure 2) (Tada et al 1999). Moreover, it has been demonstrated that a selective 5-HT 1A agonist 8-hydroxy-2-(di-n-propylamino)tetralin (8-OH-DPAT) increases the wakefulness (Monti and Hantos 1994) and decreases the firing activity (Tada et al 1999), which is consistent with the behavioral correlates (Suzuki and Smith 1985). Taken together, the actual influences of the drugs on the firing activity were extremely different from the expectable indirect influences through the effects on the behavioral states.…”

“…Previous studies have demonstrated that PCPA and NAN-190 decrease slow wave sleep and increase wakefulness (Li and Satinoff 1992;Neckelmann et al 1996), and that ritanserin increases slow wave sleep and decreases waking (Bjorvatn and Ursin 1990;Silhol et al 1992). Suzuki and Smith (1985) have shown that the pyramidal neurons are most active during slow wave sleep, slightly less active during a quiet awake state, and least active during an active awake condition and paradoxical sleep. Thus, one might assume that the present observations reflect indirect influences of the tested drugs through their direct effects on the states of the animals.…”

“…Thus, one might assume that the present observations reflect indirect influences of the tested drugs through their direct effects on the states of the animals. Given the correlation between the behavioral states and the firing activity (Suzuki and Smith 1985), ritanserin is expected to increase the firing activity since this drug could increase slow wave sleep and decrease wakefulness (Bjorvatn and Ursin 1990;Silhol et al 1992). However, ritanserin did not change the firing activity (data not shown).…”

“…The criteria were generated on the basis of the previous studies (Fox and Ranck 1975;Suzuki and Smith 1985). Recordings with a low signal-to-noise ratio ( Ͻ 5:1) were not employed for data analysis.…”

Endogenous 5-HT Tonically Inhibits Spontaneous Firing Activity of Dorsal Hippocampus CA1 Pyramidal Neurons Through Stimulation of 5-HT1A Receptors in Quiet Awake Rats In Vivo Electrophysiological Evidence

Single neuron burst firing in the human hippocampus during sleep

Endogenous 5‐HT inhibits firing activity of hippocampal CA₁ pyramidal neurons during conditioned fear stress‐induced freezing behavior through stimulating 5‐HT_1A receptors