Objective To study the effects of ginsenosides (GS) on spontaneous sleep architecture and Cortical EEG power spectrum. Methods 24 adult SD rats were randomly divided into the control, GS 10 and 100mg/kg groups ( n = 8). Rats were instrumented with sleep-wake recording electrodes. After recovery from surgical operation,rats were orally administered GS 10 and 100mg/kg or distilled water once per day for 6 days. On GS administration day 1 and 6,Polygraphic signs of undisturbed sleep-wake activities were recorded for 12 h after GS administration. Results On GS administration day 1 ,only 100mg/kg GS increased significantly total sleep and the non-rapid eye movement ( NREM ) sleep but decreased wakefulness [(9.40 ± 0.88 ) h, ( 8.00 ± 1. 21 ) h,(2.46 ±0.81)h s (7.55 ±1.59)h,(6.36±1.54)h,(4.38 ±1.62)h,(P＜0.01, P＜0.05, P＜0.01),respectively] ;Low and high dose GS enhanced δ-wave power of NREM sleep and wakefulness (P＜ 0.05 ) but reduced θ-wave power of wakefulness (P＜0.01) and-wave power during NREM, REM sleep and wakefulness (P ＜ 0.01 ),moreover,Low and high dose GS lowered θ-wave power of REM and NREM stage(P＜0.05 ) ,respectively. After 6days of GS administration, Low and high dose GS increased markedly total sleep(P＜0.05 ) and NREM sleep(P＜0.05 ) but decreased wakefulness (P ＜0.05 ) and sleep-wake cycles (P ＜ 0.05, P ＜ 0.01 ); moreover, Low and high dose GS enhanced δ-wave power during NREM sleep and wakefulness (P ＜ 0. 05 ) but reduced θ-wave power of wakefulness(P ＜ 0.05 ) and -wave power during NREM, NEM sleep and wakefulness (P ＜ 0. 05 ), 10mg/kg GS also lowered θ-wave power of NREM sleep (P＜0.01). Conclusion These results demonstrate that GS can regulate spontaneous sleep architecture in time dependent manner,as well as cortical EEG power spectrum in rats.

The growth and development of follicles are regulated by genes,hormones and growth factors autocrined and paracrined from granulosa cells,theca cells,and oocytes.Products of glycolysis from granulosa cells such as pyruvate and lactate are one of the main energy sources,which play an important role during folliculogenesis and follicle maturity.Studies on the changes of the products and rate-limiting enzymes during granulosa cells' glycolysis help to clarify the molecular mechanism of energy demand in folliculogenesis and guide the clinical treatment of infertility due to abnormal follicular development.This article reviews recent research advances in the energy demand and regulatory mechanism in different states of folliculogenesis.
Energy Metabolism ; Female ; Glycolysis ; Granulosa Cells ; Humans ; Intercellular Signaling Peptides and Proteins ; Oocytes ; Ovarian Follicle ; growth & development ; Theca Cells