Study on the technology of efficient extraction of eleutheroside E from Acanthopanax senticosus by green solvent DES.

OBJECTIVES: Acanthopanax senticosus (Rupr. & Maxim.) Harms is a medicinal and edible plant which is clinically used for the recovery and treatment of cardiovascular and central diseases. As a characteristic active pharmaceutical ingredient of Acanthopanax senticosus, eleutheroside E is the core of the therapeutic effect. Organic solvent extraction has low selectivity, low extraction rate, difficulty in separation and purification and safety risks. The purpose of this study was to extract the effective component of Acanthopanax senticosus with a new green solvent. METHODS: In this article, two kinds of deep eutectic solvents (DESs) (DES-1 and DES-2) were synthesised by heating and stirring methods. Eleutheroside E was extracted by ultrasonic extraction with two kinds of DES as extractants and quantitatively analysed by Orbitrap-tandem mass spectrometry (MS/MS). RESULTS: The main results showed that the initial polarity of the DES was similar to that of 60 to 80% ethanol and hydrogen bond donors were the main factors affecting the polarity of DES. In the test, the viscosity of DES was higher than that of ethanol, and even the addition of a small amount of water (10%) caused intermolecular hydrogen bond disruption and redistribution of the solvent, resulting in a significant decrease in solvent viscosity. The solvents in the test group were stable after standing at 5°C in the dark for 100 days. The extraction rate of eleutheroside E by DES solvent was 5-6 times higher than that by ethanol. DES-1 and DES-2 can efficiently extract eleutheroside E. CONCLUSION: This study developed a new method for the application of the green extraction of eleutheroside E with certain practical significance.

A recoverable hydrophilic deep eutectic solvent for efficient extraction of polyphenolic compounds from raspberry root.

Green deep eutectic solvents (DESs) are widely used to extract bioactive components from plant biomass; however, hydrophilic DES and bioactive component isolation methods have not been developed. In this study, we synthesized hydrophilic DES (CL-CA-DES) using citric acid and choline chloride. We combined this with environmentally friendly anion- and cation-exchange resin column chromatographic isolation methods. This approach extracted and isolated four polyphenolic compounds (catechins, epicatechins, procyanidin B1, and procyanidin B2) from raspberry root and efficiently recovered the hydrophilic DES. CL-CA-DES extracted significantly higher contents of catechin and procyanidin B2 from raspberry root compared to other solvents. It also extracted substantially higher contents of epicatechin compared to butyl alcohol, 70% ethanol, and water, but there was no significant difference when compared with acetone and ethyl acetate. Additionally, CL-CA-DES extracted significantly higher contents of procyanidin B1 compared to butyl alcohol, water, and ethyl acetate, with no significant difference when compared with 70% ethanol and acetone. The isolation efficiency of the bioactive components in the raspberry root extract by anion- and cation-exchange resin column chromatography was higher than that of the organic solvent extraction and precipitation generation methods, and the method was effective in recovering CL-CA-DES with a recovery rate higher than 60%. In conclusion, this study developed a new method for the efficient recovery of hydrophilic CL-CA-DES, which can be used for isolating polyphenolic compounds from raspberry root.