Dynamic changes of volatile components in Forsythia suspensa at different harvest periods based on GC-MS and chemometrics analysis / 中国中药杂志

Forsythiae Fructus is the dried fruit of Forsythia suspensa and the volatile compounds are its main bioactive components. According to the different harvest periods, F. suspensa can be divided into Qingqiao(mature F. suspensa) and Laoqiao(ripe F. suspensa). To investigate dynamic changes of volatile components in Qingqiao and Laoqiao samples collected at different periods, the present study extracted and analyzed the total volatile oils in Qingqiao and Laoqiao samples(four harvest periods for Qingqiao and two for Laoqiao) by steam distillation method. The results indicated that the content of volatile oils in F. suspensa samples at different harvest periods was significantly different. The content of volatile oils in Qingqiao samples(except those harvested in the first period) was higher than that of Laoqiao, and the content of volatile oils in both Qingqiao and Laoqiao increased with the harvest period. Furthermore, volatile compounds in F. suspensa were qualitatively analyzed by the gas chromatography-mass spectrometry(GC-MS), and 28 volatile compounds were identified. Chemometrics analyses including principal component analysis(PCA) and partial least squares discriminant analysis(PLS-DA) were further applied to explore differential markers and dynamic changes of volatile components in Qingqiao and Laoqiao samples at different harvest periods. Finally, four volatile compounds, including α-pinene, sabinene, β-pinene, and 4-terpenol were selected as potential differential markers. The relative content of α-pinene and 4-terpenol was consistent with that of total volatile oils in the changing trend.

Dynamic changes of volatile components of Qiai from different harvest time based on GC-MS and chemometrics analysis / 中国中药杂志

Artemisiae Argyi Folium, the dried leaves of Artemisia argyi, has been widely used in traditional Chinese and folk medicines for a long time. Qiai is one of the top-geoherb of Artemisiae Argyi Folium. Qiai contains various bioactive constituents, such as volatile oils, phenolic acids, flavonoids and terpenoids. Phytochemical studies demonstrated that volatile compounds are the main bioactive constituents in Qiai. Try to investigate dynamic changes of volatile components of Qiai from different harvest time and explore the optimum harvest time of Qiai, in this study, the contents of total volatile oils in Qiai collected from five different harvest time were analyzed by steam distillation method. The results showed that the contents of volatile oils of Qiai were higher in the third harvest time(around the Dragon Boat Festival), which is basically consistent with the traditional harvest time. Furthermore, a sensitive method based on gas chromatography-mass spectrometry(GC-MS) was established for qualitative analysis of volatile compounds in Qiai, and a total of thirty volatile compounds were identified. Chemometrics methods including principal component analysis(PCA) and orthogonal partial least-squares discriminate analysis(OPLS-DA) were applied to explore chemical markers and dynamic changes of volatile components in Qiai from different harvest time, and the results indicated that there were obvious differences in the relative contents of volatile compounds of Qiai samples from different harvest time. Eight volatile compounds, including α-terpinene, γ-terpinene, D-camphor, trans-carveol, α-copaene, isobornylisobutyrate, humulene, and caryophyllene oxide were selected as potential chemical markers. Among the eight chemical markers, the relative contents of α-terpinene, γ-terpinene, α-copaene and caryophyllene oxide were higher in the third harvest period(around the Dragon Boat Festival), which is consistent with the contents of total volatile oils. The present study could provide the basis for investigating the optimum harvest time of Qiai, and might be useful for the quality control of this herbal medicine.

Study on difference of chemical constituents of Qiai in different harvest periods / 中国中药杂志

Artemisiae Argyi Folium,the dried leaves of Artemisia argyi,has been widely used in traditional Chinese and folk medicines for a long time. Qiai is one of the top-geoherb of Artemisiae Argyi Folium. Trying to investigate dynamic changes of chemical components of Qiai in different harvest periods and explore the optimum harvest time of Qiai,in this study,the contents of total flavonoids and total phenolic acids of 36 batches of Qiai collected in 6 different harvest periods were analyzed by ultraviolet-visible spectrophotometry. Furthermore,an HPLC method was applied for simultaneous determination of eight bioactive compounds including six phenolic acids( 5-caffeoylquinic acid,3-caffeoylquinic acid,4-caffeoylquinic acid,3,4-di-O-caffeoylquinic acid,3,5-di-O-caffeoylquinic acid and 4,5-di-O-caffeoylquinic acid) and two flavonoids( jaceosidin and eupatilin) in Qiai samples. The quantitative results indicated that there were some differences in the contents of total flavonoids,total phenolic acids and bioactive compounds of Qiai samples in different harvest periods. The dynamic changes of total flavonoids and total phenolic acids of Qiai in different harvest periods were consistent. The contents of total flavonoids and total phenolic acids of Qiai samples were higher in the third harvest period( around the Dragon Boat Festival),which is basically consistent with the traditional harvest periods. This present study can provide the basis for determining the suitable harvest time of Qiai,and might be useful for the quality evaluation of this herbal medicine.

Chemical comparison of Salvia miltiorrhiza phloem and xylem based on fingerprint analysis and quantitative analysis of multi-components / 中草药

Objective: To comprehensively compare and evaluate the composition of Salvia miltiorrhiza phloem and xylem samples based on fingerprint analysis and quantitative analysis of multi-components. Methods: In the present study, an accurate and reliable fingerprint approach was developed using high performance liquid chromatography for chemical comparison ofphloem and xylem samples of S. miltiorrhiza. Furthermore, eight bioactive compounds including four salvianolic acids and four tanshinones in S. miltiorrhiza phloem and xylem samples were simultaneously quantified. Moreover, chemometrics methods were performed to compare and discriminate the phloem and xylem based on the quantitative data. Results: The specific fingerprints of phloem and xylem of S. miltiorrhiza were obtained, and a total of 10 common peaks were marked. The quantitative and chemometrics analysis results indicated the content of chemical components in phloem and xylem samples of S. miltiorrhiza were notably different. Obviously, the content of tanshinones were notably different between phloem and xylem samples. The content of tanshinones were significant higher in phloem compared with xylem in S. miltiorrhiza. Conclusion: The fingerprint analysis and quantitative analysis of multi-components could be a well-acceptable strategy for chemical comparison of S. miltiorrhiza phloem and xylem.