The traditional Chinese medicine(TCM) quality constant herbal slices evaluation method was applied to evaluate the grade of Sophorae Tonkinensis Radix et Rhizoma based on the combination of traditional character identification and modern scientific and technological methods. The TCM quality constant evaluation method was used to determine the appearance and index content of medicinal slices, calculate the quality constant and percentile quality constant of Sophorae Tonkinensis Radix et Rhizoma from different sources, and discuss their classification. The quality constants of 15 batches of Sophorae Tonkinensis Radix et Rhizoma slices were between 0.004 and 0.063. The slices with the percentage quality constant ≥80% were classified as the first grade; those with the percentage quality constant ≥50% and less then 80% were classified as the second grade; and those with the percentage quality constant less then 50% were classified as the third grade. Then the slices with the quality constant ≥0.050 were classified as the first grade; those with the quality constant ≥0.032 and less then 0.050 were classified as the second grade; and those with the quality constant less then 0.032 were classified as the third grade. According to the results, the 15 batches of Sophorae Tonkinensis Radix et Rhizoma slices were divided into 1 batch of the first grade, 4 batches of the second grade, and 10 batches of the third grade. The quality constant evaluation method established is scientific, objective, simple and feasible. The application of the method in Sophorae Tonkinensis Radix et Rhizoma slices has reasonable results, which is helpful to promote the classification of Sophorae Tonkinensis Radix et Rhizoma and promotes the high-quality application of Sophorae Tonkinensis Radix et Rhizoma.To prepare ginkgolide B nanosuspension(GB-NS), and investigate its dissolution behaviors in vitro. The miniaturized media milling method was used to prepare nanosuspensions, with average particle size and polydispersity index as the evaluation indexes. The formulation and process of GB-NS were optimized by single factor experiment and Box-Behnken design-response surface method. The morphology was observed by scanning electron microscope(SEM), and thecrystallinity of GB-NS was investigated by X-rays diffraction(XRD). The paddle method was used to study the dissolution of GB-NS in vitro. The mean particle size of optimized GB-NS was(180±7) nm, with a polydispersity index of 0.196±0.036. SEM showed that GB-NS was rod-like or irregular granular. XRD showed that the crystallinity of GB-NS was significantly reduced compared with GB raw material. The cumulative dissolution rate of GB-NS reached 90% in 30 min, which was higher than that of GB raw material. The findings suggested that the miniaturized media milling method was simple, efficient and feasible to prepare GB-NS. https://www.selleckchem.com/products/bismuth-subnitrate.html And the dissolution rate of GB was significantly improved by nanosuspension technology.To enrich the transcriptome data in rhizome of Polygonatum cyrtonema seedlings, identify candidate functional genes involved in steroidal saponin biosynthesis and provide genetic resources for the research on anabolism pathway and regulatory mechanism of active components in P. cyrtonema, Illumina platform was applied to perform transcriptomic sequencing of rhizome of P. cyrtonema, followed by a series of bioinformatics analysis on RNA-seq data, including de novo assembly, annotation, classification and metabolic pathway analysis of the assembled unigene. Meanwhile, a deep analysis on the steroidal saponin biosynthesis in secondary metabolism pathway was performed. The results showed a total of 126 546 unigene were obtained by de novo transcriptome assembly, of which 47 226 were annotated. Of these, 16 499 unigene were mapped to 132 specific pathways, of which 2 768 were identified to be involved in 22 secondary metabolic pathways. One hundred and thirteen unigene were identified from the transcriptome database, which encoded 27 metabolic enzymes associated with steroidal saponin biosynthesis and shared similarity with 45 functional genes in Arabidopsis thaliana. In conclusion, a series of candidate functional genes, which might be involved in steroidal saponin biosynthesis, were selected from the transcriptome database of P. cyrtonema rhizome. Further investigation of these candidate genes will provide insight into their actual functions in the steroidal saponin biosynthetic pathway in P. cyrtonema. In addition, this study also provide abunant reference data for transcriptome characterization of P. cyrtonema and has important significance for functional genomics of P. cyrtonema.Aquilaria sinensis is a typical inducible medicinal plant, that can produce agarwood only after it is wounded by external stimuli. Alternative oxidase(AOX) is one of the terminal oxidases of the plant mitochondrial electron transport, which plays an important role in plants' response to environmental stress. In order to reveal the physiological function of AOX gene in the process of agarwood formation from A.sinensis induced by wounding, AOX gene was cloned based on the transcriptome database and then identified by the bioinformatics analysis, and their expression pattern in different tissues and under wounding stress were detected by qRT-PCR. The results as follows. Three AOX genes were cloned from A.sinensis for the first time. They were named AsAOX1a, AsAOX1d and AsAOX2, respectively. The tissue expression shown that AsAOX1a is mainly expressed in the stem and the seed, and the AsAOX1d and AsAOX2 genes are mainly expressed in the pulp and the stem. AsAOX1a and AsAOX1d genes are highly responsive to wounding stress, and their response time was different. In addition, the expression of AsAOX1a and AsAOX2 induced by wounding are reduced by H_2O_2 treatment, but promoted by AsA treatment. The cloning, bioinformatics analysis and expression characteristics of AOX genes from A.sinensis provided basic information for further study the function of AOX genes in the development of A.sinensis, especially in the process of agarwood formation of A. sinensis induced by wounding.