ABSTRACT
Objective To establish a RP-HPLC method for determining indigo and indirubin in Baphicacanthus cusia from different producing areas and medicinal parts. Methods The separation was achieved by an Agilent TC-C18 Column (4.6 mm×250 mm, 5 μm) at 25 ℃ using methanol-water (75??25) as mobile phase at a flow rate of 1 mL??min-1.The detection wavelength was 290 nm. Results Indigo had a good linear relationship with peak area at range of 0. 051 3-0.820 8 μg (r=0.999 3).The recovery rate was 99.00% and RSD was 1.30% (n=6).Indirubin had a good linear relationship with peak area at range of 0.049 5-0.792 0 μg (r=0.999 9).The recovery rate was 98.88% and RSD was 1.51% (n=6). Conclusion The contents of the two components are obviously different in Baphicacanthus cusia because of different places or medicinal parts. The proposed method is simple, rapid and reliable. This method for determination of indigo and indirubin in Baphicacanthus cusia by RP-HPLC provides a basis for quality control of Baphicacanthus cusia.
ABSTRACT
Descurainiae, Lepidii Semen and their it adulterants were identified by analysising their ITS2 sequences. The genomic DNA was extracted from 46 samples including Descurainiae and Lepidii Semen and their it adulterants. Their ITS2 sequences were amplified, and purified PCR products were sequenced. Sequence assembly and consensus sequence generation were performed using CodonCode Aligner v 4.25. The genetic distances, variable sites and the neighbor-joning (NJ) phylogenetic tree were computed by MEGA 6.0 in accordance with the Kimura 2-parameter (K2P) model. The results showed that the intra-specific genetic distances of Descurainia sophia and Lepidium apetalum were 0.021 and 0.010, which were smaller than inter-specific ones of D. sophia, L. apetalum and their adulterants. The NJ tree showed that both D. sophia and L. apetalum were clustered into one monophyletic branch, and clearly separated with their sibling species. Therefore ITS2 sequence was able to identify Descurainiae and Lep-idii Semen and its adulterants to ensure the quality of medicines and clinical efficacy.
ABSTRACT
Objective: The Phenomenon of different species with the same name has created potential threats to cinical safety of medication. Because of that, two kinds of “gonglao leaf” and their sibling adulterants have been identified by molecular methods in this study, to secure its safety in medication. Methods: Ilexcornuta, Mahoniabealei, Mahoniafortuneiand their sibling adulterants total of 9 species 45 samples were collected in this experiment,Total genomic DNA was extracted from them by the method of improved CTAB, ITS2 sequences were amplified, and the PCR products were sequenced. Sequence assembly and consensus sequence generation were performed by the CodonCode Aligner V 4.2.4.. The genetic distances were computed by MEGA 6.0 in accordance with the Kimura 2-Parameter (K2P) model and the phylogenetic tree constructed by the neighbor-joining (NJ) method. Results: The analysis results of the genetic distances, variable sites and the NJ phylogenetic tree showed that Ilexcornuta, Mahoniabealei, Mahoniafortunei were seperated from their sibling adulterants obviously. Conclusion: ITS2 sequence was able to identify two kinds of “gonglao leaf” and their sibling adulterants which can provide a basis for clinical accurate medication.
ABSTRACT
Objective To establish a method for content determination of swertiamarin in Lomatogoniopsis alpina. Methods HPLC method for determination was used. Chromatographic column: Alltimal C18 (250 mm?4.6 mm, 5 ?m). Mobile phase: methanol-water (including 0.05% H3PO4), and gradient elution. Flow rate:1 mL/min. Wavelength:234 nm. Column temperture:30 ℃. Results The calibration curve of swertiamarin was in good linearity over the range of 3.10~30.98 (r =0.999 1). The average recoveries were 98.0%, with RSD=2.66% (n =6). Conclusion It is a simple and sensitive method in controlling the quality of Lomatogoniopsis alpina.