[New method for green extraction of ginsenosides based on mechanochemically-assisted extraction and deep eutectic solvents].

Ginsenosides are the main active ingredients in ginseng. Studies have shown that ginsenosides have anti-virus, anti-tumor, anti-aging, nootropic, cardiovascular diseases-protecting, and other pharmacological activities. Thus, the development and utilization of ginsenosides have persistently attracted much attention. At present, the extraction of ginsenosides is mainly based on organic solvents, and there are relatively few studies on their green extraction. In this study, different deep eutectic solvents(DESs) were synthesized by heating and stirring method, combined with an emerging technology, mechanochemically-assisted extraction(MCAE), to extract ginsenosides in a green way. Six parameters that might affect the extraction effect were optimized to determine the optimal conditions, and the method validation was conducted. The new established method was compared with a commonly used extraction method(ultrasound-assisted extraction using 70% ethanol) to evaluate its extraction efficiency. The results revealed that the optimal extraction conditions of DES-MCAE were that the volume ratio of DES3(choline chloride∶urea 1∶2) and water in the extraction solvent was 6∶4, and the liquid ratio and the linear vibration speed were 0.05 g·mL~(-1) and 4.0 m·s~(-1); the extraction was performed twice, 40 s each. With only 80 s extraction, the extraction rate of this method was 36.22% higher than that of ultrasoun-dassisted extraction using 70% ethanol. In this study, a DESs-based pretreatment method for ginsenosides was established and its rapid, green and efficient extraction was realized, which provided new ideas and methods for further research on green extraction of other active ingredients from Chinese medicine.

In silico drug design of inhibitor of nuclear factor kappa B kinase subunit beta inhibitors from 2-acylamino-3-aminothienopyridines based on quantitative structure-activity relationships and molecular docking.

Inhibitor of nuclear factor kappa B kinase subunit beta (IKK-ß), a specific regulator of nuclear factor-κB (NF-κB), is considered a valid target to design novel candidate drugs to treat rheumatoid arthritis and various cancers. In the present study, quantitative structure-activity relationships (QSAR) and molecular docking techniques were used to screen for new IKK-ß inhibitors from a series of 2-acylamino-3-aminothienopyridine analogs. During the two-dimensional QSAR phase, the statistical model partial least square was selected from among two alternatives (r2 = 0.868, q2 (cross-validation) = 0.630). Descriptors with positive or negative contributions were derived from the created model. To build of three-dimensional QSAR models, we used three different fingerprints as analysis precepts for molecular clustering and the subsequent division of training sets and test sets. The best model, which used fingerprint model definition language public keys, was selected for further prediction of the compounds' activities. Favorable physicochemical, structural, electrostatic, and steric properties were derived from the created QSAR models and then used for drug design with an in-house library. Amongst the designed compounds, compounds B01 and B02 showed good predicted activities. Furthermore, after a selecting the protein structure and docking method, docking studies were carried out to reveal the detailed interactions between the ligands and the target protein. Binding affinity was measured and sorted using the value of "-CDOCKER_ENERGY". The high -CDOCKER_ENERGY values of compounds B01 (41.6134 kcal/mol) and B02 (40.1366 kcal/mol) indicated their prominent docking affinities.

[Molecular action mechanism of desoxyrhaponticin and serum albumin characterized by spectroscopy combined with molecular modelling].

OBJECTIVE: To study the molecular action mechanism of active constituents desoxyrhaponticin (DES) and human serum albumin (HSA). METHOD: Under the simulated physiological condition, computer analog technology, fluorescent spectrometry and ultraviolet spectrum were combined to study the binding mechanism between drug and protein. RESULT: Molecular modeling was adopted to establish the binding model between DES and HSA, suggesting that the interaction force maintaining drug and protein is mainly the hydrophobic interaction with a hydrogen-bond interaction. The results from spectroscopy indicated that the interaction between DES and HSA is a dynamic binding process with a high intensity. The value of the binding distance (r) between DES and HSA was low, which demonstrate the occurrence of energy transfer. DES made an impact on HSA' structural domain microcell conformation, which resulted in hydrophobic changes in binding areas. According to the fluorescent phase diagram technical analysis, the changes in the DES-HSA reaction conformational pattern showed a "two-state" model. According to the obtained thermodynamic parameters for the DES-HSA interaction, the interactional force between DES and HSA was mainly a hydrophobic interaction. The fluorescence polarization proved that a non-covalent compound was generated during the interaction between DES and HSA. CONCLUSION: The spectrum experiment showed consistent results with the computer analog technology, which could provided certain reference for studies on the interaction between DES and HSA.

[Study on honeysuckle active ingredients and comparative analysis on their interactive mechanisms with different proteins].

OBJECTIVE: To analyze and compare molecular mechanisms of active ingredients of honeysuckle (chlorogenic acid, CGA) with bovine lactoferrin (BLF) or bovine serum albumin (BSA). METHOD: The spectral experiment and the computer analog technology were combined to determine the binding parameters, energy transfer parameters and thermodynamic functions between CGA and proteins, study the molecular mechanism, and compare the differences in interactive mechanism between CGA and BLF or BSA. RESULT: The interactive mechanism between CGA and BLF or BSA was a dynamic molecular mechanism, whereas the static quenching mechanism existed between the interaction of CGA and BSA, with differences in the bonding intensity due to difference temperature. The binding distance r between CGA and BLF/BSA was very short, indicating the phenomenon of energy transfer. The results of the molecular modeling showed that the main interaction force between CGA and BLF or BSA was hydrogen bonds, together with Van der Waals' forces and hydrophobic effect. CONCLUSION: The computer analog shows consistent results with spectral experiment.