Identification of Polar Constituents in the Decoction of Juglans mandshurica and in the Medicated Egg Prepared with the Decoction by HPLC-Q-TOF MS².

As a folk medicinal plant, Juglans mandshurica has been used for the treatment of cancer in China and Korea. Traditionally, J. mandshurica is decocted together with chicken eggs. Both the decoction and medicated eggs possess anti-tumor properties. Clarifying the constituents of the decoction and absorbed by the medicated eggs is essential for the investigation of the active principles of J. mandshurica. Herein, the medicated eggs were prepared by decocting raw chicken eggs, having unbroken shells, with the decoction of J. mandshurica. A systematic investigation of the chemical profile of the J. mandshurica decoction and the medicated egg extraction was conducted by HPLC-Q-TOF-MS². In total, 93 peaks, including 45 tannins, 14 naphthalene derivatives, 17 organic acids, 3 diarylheptanoids, 4 lignans, 3 anthraquinones, 1 flavonoid glycoside, 3 amino acids, and 3 nitrogenous compounds, were tentatively identified in the decoction. In the medicated egg extraction, 44 peaks including 11 organic acids, 3 amino acids, 3 nitrogenous compounds, 8 naphthalene derivatives, 3 diarylheptanoids, 15 tannins, and 1 lignan were tentatively identified. The chemical profile presented provided a detailed overview of the polar chemical constituents in J. mandshurica and useful information for the research of bioactive compounds of this plant.

Multiconstituent identification in root, branch, and leaf extracts of Juglans mandshurica using ultra high performance liquid chromatography with quadrupole time-of-flight mass spectrometry.

As a traditional medicinal plant, Juglans mandshurica has been used for the treatment of cancer. Different organs of this plant showed anti-tumor activity in clinic and laboratory. Comparative identification of constituents in different plant organs is essential for investigation of the relationship between chemical constituents and pharmacological activities. For this aim, the roots, branches, and leaves of J. mandshurica were extracted with 50% v/v methanol and then subjected to ultra-high performance liquid chromatography with quadrupole time-of-flight mass spectrometry analysis conducted under low and high energy. As a result, we have to date identified 111 compounds consisting of 56 tannins, 29 flavonoids, 13 organic acids, 8 naphthalene derivatives, and 5 anthracenes. Five compounds, namely, diquercetin trihydroxy-truxinoyl-glucoside, two quercetin kaempferol dihydroxy-truxinoyl-glucosides, syringoyl-tri-galloyl-O-glucose, and dihydroxy-naphthalene syringoyl-glucoside, were tentatively identified as new compounds. Of the compounds identified, 76 were found in the root extract, 67 in the branch extract, and 37 in the leaf extract. Only six compounds including four organic acids and two tannins were found in all three extracts. We developed a rapid and sensitive ultra high performance liquid chromatography with quadrupole time-of-flight mass spectrometry approach to identify multiple constituents of complex extracts without separation and ion selection. The results presented provide useful information on further research of the bioactive compounds of J. mandshurica.

[Studies on optimizing extraction technics of flowers of Polygonum orientale by response surface methodology].

OBJECTIVE: To analyze and optimize extraction technics of Polygonum orientale flowers by response surface methodology. METHODS: With the index for the content of taxifolin in flowers of Polygonum orientale, the effect of three factors such as concentration of alcohol, extraction time and solvent-solid ratio was designed by Box-Behnken central composite. Extraction technic parameters of Polygonum orientale flowers was optimized by response surface methodology. RESULTS: The optimizing extraction conditions of Polygonum orientale flowers were as follows: ethanol concentration was 65%, extracting time was 129 min and solvent-solid ratio was 18. Under the conditions, the average yield of taxifolin in 3 validation experiments was 2.79 mg/g. CONCLUSION: Optimizing extraction technics by response surface methodology is reasonable, simple, and has good predictability.

Role of berberine in anti-bacterial as a high-affinity LPS antagonist binding to TLR4/MD-2 receptor.

BACKGROUND: Berberine is an isoquinoline alkaloid mainly extracted from Rhizoma Coptidis and has been shown to possess a potent inhibitory activity against bacterial. However, the role of berberine in anti-bacterial action has not been extensively studied. METHODS: The animal model was established to investigate the effects of berberine on bacterial and LPS infection. Docking analysis, Molecular dynamics simulations and Real-time RT-PCR analysis was adopted to investigate the molecular mechanism. RESULTS: Treatment with 40 mg/kg berberine significantly increased the survival rate of mice challenged with Salmonella typhimurium (LT2), but berberine show no effects in bacteriostasis. Further study indicated that treatment with 0.20 g/kg berberine markedly increased the survival rate of mice challenged with 2 EU/ml bacterial endotoxin (LPS) and postpone the death time of the dead mice. Moreover, pretreatment with 0.05 g/kg berberine significantly lower the increasing temperature of rabbits challenged with LPS. The studies of molecular mechanism demonstrated that Berberine was able to bind to the TLR4/MD-2 receptor, and presented higher affinity in comparison with LPS. Furthermore, berberine could significantly suppressed the increasing expression of NF-κB, IL-6, TNFα, and IFNß in the RAW264.7 challenged with LPS. CONCLUSION: Berberine can act as a LPS antagonist and block the LPS/TLR4 signaling from the sourse, resulting in the anti-bacterial action.

[Study on species identification of commercial drug cudraniae tricuspidatae radix et caulis and its medicinal parts].

OBJECTIVE: To establish an identification method of Cudrania tricuspidata and Cudrania cochinchinensis, and their medicinal parts, and analyse the species of commercial drug Cudraniae Tricuspidatae Radix et Caulis. METHODS: TLC and First-order Derivative UV Spectrophotometry were used. RESULTS: Commercial drugs 5, 6, 7 and 9 belonged to the stem of Cudrania cochinchinensis, commercial drug 1, 2, 3 ,4 and 8 were neither Cudrania tricuspidata nor Cudrania cochinchinensis. CONCLUSION: Cudrania tricuspidata and Cudrania cochinchinensis can be identified by TLC, as well as the medicinal parts. UV Spectrophotometry can't be applied to variety identification but can be used for identifying the medicinal parts. It's more accurate and reliable for identifying Cudrania tricuspidata and Cudrania cochinchinensis, and the medicinal parts by combined using TLC and UV. This study provides a scientific and effective method for species identification and medicinal part analysis of commercial drug Cudraniae Tricuspidatae Radix et Caulis.

[Simultaneous determination of four flavones in root and stem of Cudrania tricuspidata and C. cochinchinensis by HPLC-DAD].

OBJECTIVE: To establish a HPLC-DAD method for the determination of axifolin, naringenin, quercetin and kaempferol in Cudrania tricuspidata and C. cochinchinensis in order to provide a scientific reference for species identification and quality evaluation, by establishing. METHOD: The determination was performed by HPLC-DAD on an Agilent C18 column (4.6 mm x 150 mm, 5 microm) by gradient elution (0-15 min, 35%-50% A; 15-30 min, 50% - 65% A) using methanol (A) and 0.1% phosphoric acid (B) as the mobile phase. The flow rate was 1 mL x min(-1). The detection wavelength was 290 nm for taxifolin and naringenin, 365 nm for quercetin and kaempferol with column temperature at 30 degrees C. RESULT: The content of axifolin and quercetin in the root of C. tricuspidata were remarkably higher than that in the root of C. cochinchinensis, and the content in stem of C. tricuspidata was also higher than that in the stem of C. cochinchinensis, the content of axifolin and quercetin was variable in different species. The content of naringenin and kaempferol in the root of C. cochinchinensis was visibly higher than that in the root of C. tricuspidata, and the content in the stems of the two herbs was similar, the content of naringenin and kaempferol was visibly variable in different medicinal parts of the herb, but similar between the two herbs. CONCLUSION: There's some difference of the content of the four ingredients in different medicinal parts and different herbs, so clinical use should not be confused.

[Determination of taxifolin in Polygonum orientale of different storage period].

OBJECTIVE: To find out the correlation between the content of taxifolin in Polygonum orientale and the storage time. METHOD: HPLC was used to determine taxifolin. The chromatographic condition was as following: Diamonsil C18 column (4.6 mm x 200 mm, 5 microm), mobile phase acetonitrile -0.1% phosphoric acid (gradient elution), the detection wavelength 290 nm and flow rate 1.0 mL x min(-1), the column temperature 30 degrees C. RESULT: The injection volume of taxifolin was in good linearity within 0.07 and 0.35 microg, the average recovery was 99.7% with RSD 0.2%. Taxifolin content was 0.84, 1.36, 1.75, 1.99 mg x g(-1) corresponding to storage time of 10, 7, 6, 5 years, respectively. CONCLUSION: The content of taxifolin decreased with the storage time. When the storage period is more than six years, the content is lower than that required by Chinese Pharmacopoeia (2010 version). This method has a good repeatability and accuracy, it provides a scientific reference for clinical use and quality evaluation of P. orientale.

[Study on characteristic HPLC fingerprint of Polygonum orientale inflorescence].

OBJECTIVE: To establish a characteristic HPLC fingerprint of Polygonum orientale inflorescence, and to provide reference for its quality evaluation. METHODS: Taxifolin was used as reference. HPLC analysis was carried out with Diamonsil C18 column (200 mm x 4.6 mm, 5 microm) using acetonitrile -0.1% phosphoric acid(gradient elution)as mobile phase at flow rate of 1.0 mL/min. The detection wavelength was set at 280 nm and the column temperature was 30 degrees C. RESULTS: Eighteen common peaks were pointed out from the HPLC fingerprint of Polygonum orientale inflorescence from 12 different habitats. Among of them,four common peaks were identified as taxifolin, catechin, gallic acid and 3,3'-dimethyl ellagic acid-4-O-beta-D-glucoside. Analyzed by "Similarity Evaluation for Chromatographic Fingerprint of Traditional Chinese Medicine" software, the HPLC fingerprint similarities of 12 samples were more than 0.9. CONCLUSION: This method is repeatable and exclusive. It can be used for identification and quality control of Polygonum orientale inflorescence.

[Effects of different processing on active components in fructus polygoni orientalis by HPLC analysis].

OBJECTIVE: To study the effects of different processing on taxifolin and quercetin in Fructus Polygoni Orientalis. METHODS: The analysis was performed on a Agilent column (4. 6 mm x 150 mm, 5 microm) eluted with a gradient elution of methanol-water containing 0. 1% phosphoric acid. The flow rate was 1 mL/min, the detection wave length was 270 nm and the column temperature was set at 25 degrees C. The content changes of taxifolin and quercetin processed by different methods was compared. RESULTS: The contents of active ingredients in Fructus Polygoni Orientalis that processed by the method of therm-high pressure (the pressure was 14Pa) was obvious higher than those of other methods. CONCLUSION: Active ingredients of Fructus Polygoni Orientalis may be promoted by therm-high pressure processed. There is significant difference for the major components by different processing methods. The method of therm-high pressure to processing is used for the first time in the Fruit Polygoni Orientalis. The method appears to be simple, easy and can be used as quantitative determination method for quality control of the Fructus Polygoni Orientalis.

[Study on the expressed oil of princes-feather fruit before and after processed by GC-MS].

OBJECTIVE: To compare the chemical compositions in the expressed oil before and after processed of princes-feather fruit. METHODS: Making use of the GC-MS to compare the chemical composition in the expressed oil before and after processed of princes-feather fruit. RESULTS: 4 chemical compounds were detected in the expressed oil of the raw and 7 of the processed. But the main chemical compound (E, E) 9, 12-Octadecadienoic acid, methyl ester of the raw wosnt detected in the processed product. CONCLUSION: Processing drugs has the major effect on the chemical composition in the expressed oil of princes-feather fruit.