Sedative and hypnotic effects of compound Anshen essential oil inhalation for insomnia

ICR mice aged 6–8 weeks, half male and half female, weighing 25-35 g, provided by Jiangsu Jicui Yaokang Biotechnology Co., Ltd. License number: SCXK (su) 2018–0008. During the whole experiment, the animals could get enough food and water. The temperature of the feeding environment was 21 °C ± 1 °C, the humidity was 55% ± 5%, the light and dark alternate for 12 h, and the test was started after 1 week of adaptive feeding.

The experiments were approved by the Institutional Animal Ethics Committee of Jiangxi University of Traditional Chinese Medicine. All animals were maintained in accordance with the guidelines outlined by the Chinese legislation on the ethical use and care of laboratory animals. All animals were maintained in accordance with the guidelines outlined by the legislation on the ethical use and care of laboratory animals. All efforts were made to minimize both animal suffering and the number of animals used to produce reliable data.

Compound Anshen essential oil is a blended formula consisting of seven natural plant essential oils. Lavender, Sweet Orange, Sandalwood, Frankincense, Orange blossom, Rose, and Agarwood oil are purchased from Puli Aroma Pharmaceutical Technology (Shanghai) Co., Ltd. The seven essential oils are mixed to make a composite oil of a specific mixing ratio. (Lavender, Sweet orange, Sandalwood, Frankincense, Orange blossom, Rose, Agarwood oil blend ratio 10:4:2:1.6:1.2:1:0.6). Diazepam (Beijing Yimin Pharmaceutical Co., LTD). Tween-80 (Shanghai Miura Reagent Co., Ltd). Ethanol Disinfectant (Nanchang Likang Pharmaceutical Machinery Co.,Ltd). 5-HT Elisa kit (Andygene). GABA Elisa kit (Andygene). PBS buffer (Solarbio).

Ultrasonic atomizing aromatherapy machine (Shenzhen Kangmeitai Industrial Co., Ltd). Animal aromatherapy room (large box structure of 50x50x40cm made of plexiglass, 4 small boxes structure of 20x20x20cm which can be vented with gas, and ultrasonic atomizing aromatherapy machine can be placed in the middle). SMART Behavior Recording Video Analysis System (Panlab). Agilent 7890A GC-5975 Mass Spectrometer (Agilent, USA). High-throughput tissue grinding machine (Ningbo Xinzhi Biotechnology Co., Ltd. SCIENTZ-192). Low temperature high speed centrifuge (2K15C, SIGMA, Germany). Microplate reader (Gene Co., Ltd. Elx800).

Experimental animals except for the control group were given intraperitoneal injection of PCPA to induce animal insomnia. PCPA is an inhibitor of tryptophan hydroxylase (TDH), and TDH is the limit of the sleep neurotransmitter serotonin (5-HT). Speed enzyme, so PCPA deprives sleep by blocking 5-HT. Therefore, PCPA is used to deprive sleep by blocking 5-HT. Each mouse was accurately weighed to PCPA according to the amount of 300 mg/kg, and was mixed with weak alkaline saline to prepare a suspension. After continuous injection for 2 days, after the first intraperitoneal injection for 28–32 h, the circadian rhythm disappeared and the day and night activities continued, indicating successful modeling.

48 mice were randomly divided into 6 groups. This experiment consisted of control group, model group, diazepam group, and Compound Anshen essential oil groups (low-dose group, medium-dose group, high-dose group). After the establishment of the PCPA insomnia model, the model group did not implement the inhalation of essential oil intervention, in which the low-dose, medium-dose, and high-dose groups were daily aromatherapy for 7 consecutive days, 60 min per day. The essential oil was diluted with 1% Tween 80 Solution. The concentration of low, medium, and high doses of Compound Anshen essential oil was 1 × 10^− 3, 2 × 10^− 3, 4 × 10^− 3. The inhalation time was set at 8:00–16:00 daily. Diazepam was prepared into a solution of 0.1 ml/10 g with distilled water. The diazepam group was given diazepam solution by gavage for 7 consecutive days, and the dose was 1 mg/kg (the dose was converted into the dose of mice by body surface area according to the adult dose). The control group, model group, and each Compound Anshen essential oil groups were given the same volume of distilled water by gavage.

Mice were weighed before the establishment of the PCPA insomnia model and at the end of the experiment, and the weight gain was calculated.

After the final aromatherapy or drug administration for 30 min, mice in each group were subjected to an open field test. The mice were acclimated to the environment for 5 min, and the behavioral parameters were counted within 3 min, and the differences between the mice in each group were compared. Autonomous activity test index: Total movement distance, unit: cm; Maximum velocity, unit: cm/s; Average velocity, unit: cm/s; Rest time, unit: s; Number of arm lifting.

Mice in each group were intraperitoneally injected with a threshold dose of pentobarbital sodium of 45 mg/kg after the final aromatherapy or 30 min of administration. After the administration, the righting reflex of the mice disappeared for 1 min as the index of falling into sleep. The time from the injection of the drug to the disappearance of the righting reflex was latency of sleeping time, the time that the righting reflex disappeared until the recovery was duration of sleeping time, and latency of sleeping time and duration of sleeping time were recorded.

After the open field test was completed, the mice were fasted for 6 h. The mice in each group were sacrificed by cervical dislocation, the skull was removed, brain tissue was exposed, and the brain tissue was completely removed. After separating the brain, the blood and tissues were washed in ice-cold PBS buffer and weighed with an electronic balance. The mouse brain was placed in a centrifuge tube, and a certain amount of PBS buffer was added thereto, thoroughly homogenized, centrifuged (3000 r/min, 20 min), and the supernatant was taken. After treatment with the mouse 5-HT and GABA ELISA kits, the 5-HT and GABA contents were measured at 450 nm on a microplate reader.

Gas chromatographic conditions: Agilent DB-624 (30 m×320 μm×1.8 μm) capillary column was used, the carrier gas was high purity He (99.999%), the injection volume was lμL, the split ratio was 40:1, and the flow rate was 1 mL/min. Temperature program: initial temperature 40 °C (for 1 min), ramp to 10 °C/min to 220 °C, and then raise the temperature to 25 °C/min to 280 °C (for 9 min). Mass spectrometry conditions: EI ion source, electron energy 70 eV, ion source temperature 230 °C, MS quadrupole temperature 150 °C;Interface temperature 250 °C, solvent 3.0 min delay, quality scan pattern full scan, scan range of 30 ~ 650 amu. Standard spectral library NIST11 retrieval, peak area normalization method to calculate the relative percentage content of each component.

Animals were weighed before the establishment of the PCPA insomnia model and at the end of the experiment, and the weight gain was calculated. The effect of Compound Anshen essential oil on animal body weight was studied by weight change experiment and compared with the diazepam group (Fig 1). Compared with the control group, the weight gain of the model group (P = 0.000) was extremely significantly reduced, the weight gain of the and the diazepam group (P = 0.000) was extremely significantly increased, the weight gain of the low-dose group (P = 0.14) and high-dose group (P = 0.14) was significantly increased, and the weight gain of the medium-dose group (P = 0.370) was not significantly different; Compared with the model group (P = 0.237), the weight gain of the other groups (P = 0.000) was extremely significantly increased except for the diazepam group.

From the perspective of mice movement distance (Fig. 2), compared with the control group, the movement distance of the model group (P = 0.002) was extremely significantly increased, and the movement distance of the diazepam group (P = 0.039) was significantly decreased. Compared with the model group, there was no significant difference in the movement distance in the low-dose group (P = 0.062), and the movement distance of the control group (P = 0.002), the diazepam group (P = 0.000) and the medium-dose group (P = 0.000) was extremely significantly reduced, and the movement distance of the high-dose group (P = 0.020) was significantly increased. From the perspective of average velocity of mice, the average velocity of the model group (P = 0.002) increased extremely significantly, and the average velocity of the diazepam group diazepam group (P = 0.039) decreased significantly. Compared with the model group, there was no significant difference in the average velocity of the low-dose group (P = 0.062), the average velocity of the control group (P = 0.002) decreased extremely significantly, the average velocity of the diazepam group (P = 0.000) and the medium-dose group (P = 0.000) decreased extremely significantly, and the average velocity of the high-dose group (P = 0.021) decreased extremely significantly. From the point of view of the maximum velocity of mice, compared with the control group, the maximum velocity of the model group (P = 0.000) was extremely significantly increased, and there was no significant difference in the other groups (P > 0.05). Compared with the model group, the maximum velocity of the control group (P = 0.000), the diazepam group (P = 0.000) and the medium-dose group (P = 0.002) was extremely decreased extremely significantly, and the maximum velocity of the low-dose group (P = 0.017) and the high-dose group (P = 0.015) was decreased significantly. From the resting time of the mice, compared with the control group, the model group (P = 0.004) had extremely significant difference, which showed an increase in resting time, and there was no significant difference in other groups (P > 0.05); Compared with the model group, the other groups had extremely significant differences (P < 0.01), which showed an increase in resting time. From the point of view of number of arm lifting of mice, compared with the control group, the model group had significant difference (P = 0.010) which showed an increase in the number of arm lifting, while the diazepam group (P = 0.000) and the medium-dose group (P = 0.008) showed an extremely significant difference, which showed that number of arm lifting decreased. Compared with the model group, there were significant differences in other groups (P < 0.05), among which the diazepam group (P = 0.000), the low-dose group (P = 0.007), the medium-dose group (P = 0.000) and the high-dose group (P = 0.001) had extremely significant differences, which showed that the number of arm lifting was reduced. From the point of view of number of arm lifting of mice, compared with the control group, the number of arm lifting in the model group (P = 0.010) increased significantly, and number of arm lifting in the diazepam group (P = 0.000) and the medium-dose group (P = 0.008) was extremely significantly reduced. Compared with the model group, the number of arm lifting in the diazepam group (P = 0.000), the low-dose group (P = 0.007), the medium-dose group (P = 0.000), and the high-dose group (P = 0.001) was extremely significantly reduced.

From the perspective of latency of sleeping time (Fig. 3), compared with the control group, the latency of sleeping time of the diazepam group (P = 0.000) and the medium-dose group (P = 0.000) was extremely significantly shortened, and the latency of sleeping time of the model group (P = 0.000) was extremely significantly increased. Compared with the model group, the latency of sleeping time of the other groups was significantly different (P < 0.01), which was manifested as decreased latency of sleeping time. From the perspective of duration of sleeping time, compared with the control group, the sleep time of the diazepam group (P = 0.000), the low-dose group (P = 0.000), the medium-dose group (P = 0.000), and the high-dose group (P = 0.001) was extremely significantly increased, and the sleep time of the model group (P = 0.027) was significantly reduced. Compared with the model group, the duration of sleeping time of the other groups was significantly different (P < 0.01), which was manifested as increased duration of sleeping time.

From the perspective of the concentration of 5-HT in the brain in mice (Fig. 4), compared with the control group, the 5-HT concentration in the model group (P = 0.001) was extremely significantly reduced, the 5-HT concentration in the low-dose group (P = 0.031) and the high-dose group (P = 0.012) was significantly increased; Compared with the model group, the 5-HT concentration in the diazepam group (P = 0.002), the medium-dose group (P = 0.000), and the high-dose group (P = 0.000) was extremely significantly increased, and the 5-HT concentration of the low-dose (P = 0.193) group was. not significantly different. From the perspective of the concentration of GABA in the brain in mice, compared with the control group, the GABA concentration in the model group (P = 0.000), the diazepam group (P = 0.000) and the low-dose group (P = 0.000) was extremely significantly reduced, while there was no significant difference in the medium-dose group (P = 0.434) and the high-dose group (P = 0.114). Compared with the model group, except the low-dose group (P = 0.614), all the other groups showed significant differences (P < 0.01), which showed that the concentration of GABA in the brain increased.

The main chemical composition and relative percentage of Compound Anshen essential oil analyzed by GC-MS were shown in Table 1,GC-MS analysis of the TIC component of Compound Anshen essential oil is shown in Fig. 5.A total of 30 chemical components were identified, accounting for 93.92% of total volatile oil, with the highest content of D-limonene (24.07%), Linalool (21.98%), Linalyl acetate (15.37%), α-Pinene (5.39%), α-Santalol (4.8%), etc.