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By reviewing the ancient and modern literature, the name, origin, scientific name evolution, place of origin, quality, harvesting, processing, efficacy and toxicity of Asteris Radix et Rhizoma(ARR) were systematically sorted out, so as to provide reference for the development and utilization of the relevant famous classical formulas. According to textual research, ARR was first contained in Shennong Bencaojing, all generations are Ziwan for its proper name, and there are still aliases such as Ziyuan, Ziqian and Xiaobianer. Its mainstream origin in successive generations was Aster tataricus, and there are also Ligularia fischeri and others in local area of use. The medicinal parts of ARR are root and rhizome, but in modern times, the rhizome is mostly used for propagation and cultivation, so some of ARR medicinal materials only have the root without the rhizome. The earliest recorded ancient origin of ARR was now Fangxian(Hubei), Zhengding and Handan(Heibei), then the range of production areas gradually expanded, the mainstream production areas from the Song dynasty to the Ming and Qing dynasties included Hebei, Jiangsu, Anhui, Henan and other places, since modern times, two major producing areas have been formed in Anguo, Hebei province and Bozhou, Anhui province. From the quality evaluation, it is clear that from ancient times, flexible roots and purple color are the best. The ancient harvesting was mainly in lunar February or March, and then dried in the shade, and the modern harvesting is mostly in spring and autumn, and the roots are braided into pigtails and then dried in the sun or dried in the sun after 1-2 d. The ancient and modern processing method of ARR are basically the same, mainly honey processing, there are still methods of frying, steaming, vinegar sizzling, etc. Based on the results, it is recommended that the dried roots and rhizomes of A. tataricus should be used in clinical and the development of related famous classical formulas, and those whose original formulas specify the processing requirements can be processed according to the relevant requirements, while whose processing requirements are not specified should be used in the form of raw products.
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By consulting ancient and modern literature, the herbal textual research of Farfarae Flos has been conducted to verify the name, origin, producing area, quality evaluation, harvesting and processing methods, so as to provide reference for the development and utilization of the famous classical formulas containing Farfarae Flos. According to the research, the results showed that Farfarae Flos was first described as a medicinal material by the name of Kuandonghua in Shennong Bencaojing(《神农本草经》), and the name was used and justified by later generations. The main origin was the folwer buds of Tussilago farfara, in addition, the flower buds of Petasites japonicus were used as medicine in ancient times. The ancient harvesting time of Farfarae Flos was mostly in the twelfth month of the lunar calendar, and the modern harvesting time is in December or before the ground freeze when the flower buds have not been excavated. Hebei, Gansu, Shaanxi are the authentic producing areas with the good quality products. Since modern times, its quality is summarized as big, fat, purple-red color, no pedicel is better. Processing method from soaking with licorice water in the Northern and Southern dynasties to stir-frying with honey water followed by micro-fire in the Ming dynasty, and gradually evolved to the modern mainstream processing method of honey processing. Based on the research results, it is suggested that the dried flower buds of T. farfara, a Compositae plant, should be selected for the development of famous classical formulas containing Farfarae Flos, and the corresponding processed products should be selected according to the specific processing requirements of the formulas, and raw products are recommended for medicinal use without indicating processing requirements.
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Through reviewing the ancient and modern literature, the name, origin, producing area, quality evaluation, harvesting and processing methods of Trichosanthis Fructus(TF) and Trichosanthis Radix(TR) in famous classical formulas were systematically sorted out following the chronological order. The results showed that there were many nicknames of TF and TR, and Gualou and Tianhuafen have become the mainstream names for its fruit and root, respectively. Both of them took Trichosanthes kirilowii as the mainstream base. TF and TR have been used as medicines in the Han dynasty, and since the North and South dynasties, Leigong Paozhilun had been clear that the effects of peels, seeds, stems, roots were different. TF was used as medicine with intact fruits, harvested after maturity from September to October, hung and dried in the shade, and its quality has been summarized in recent times as being best for those who are mature, large, thick and pliable peels, orange-yellow in color, and with sufficient sugary properties. In ancient times, the processing of TR was mostly crushed or shredded with the peels and seeds, or processing for pancakes and creams. TR was used as medicine with the roots, it is harvested from November to December, peeled and dried in the sun, and its quality was best when it was deep in the soil, large, white, powdery, firm and delicate with few muscles and veins, and it was considered to be toxic when it was born in briney land. Processing method of TR was to do powder into the medicine in the Tang dynasty, and gradually evolved into direct slicing use in the Ming and Qing dynasties. Since the modern era, the authentic producing areas of TF and TR were in the vicinity of Lingbao, Henan province, known as Anyang Huafen, and in modern times, there are well-known production areas such as Anguo, which produces Qihuafen, and Jinan, which produces Changqing Gualou. In the Song dynasty, there was a habit of substituting Trichosanthis Semen for the whole herb, which was later corrected by the materia medica in Ming dynasty. Based on the results, It is suggested that T. kirilowii be selected as the basal plant for the development of famous classical formulas involving TR and TF. In Qingjin Huatantang, Trichosanthis Semen is processed by stir-frying method, while TR and TF in other five formulas from the Catalogue of Ancient Famous Classical Formulas(The First Batch) were all used in raw form.
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OBJECTIVE To explore the extraction process of volatile oil from the stems, leaves and roots of Glehnia littoralis, analyze the chemical components of the volatile oil from the stems, leaves and roots of G. littoralis, and preliminarily evaluate its in vitro antifungal activity. METHODS Based on the steam distillation method, single factor test and orthogonal experiment were conducted to optimize the extraction method of volatile oil from the stems, leaves and roots of G. littoralis. The chemical components of the volatile oil from the stems, leaves and roots of G. littoralis were identified by using gas chromatography-mass spectrometry (GC-MS) technology and their relative contents were calculated. The antifungal activity of volatile oils from the stems, leaves and roots of G. littoralis against Fusarium solani, Fusarium incarnatum, Fusarium oxysporum, Aspergillus parasiticus and Aspergillus flavus was determined by paper diffusion method. RESULTS The optimal extraction process of G. littoralis was solid-liquid ratio of 1∶15, distillation time of 5 hours, and KCl concentration of 15%. Eleven components were identified from the volatile oil of the stems and leaves of G. littoralis, and a total of eight components were identified from the volatile oil of the roots. Ginsenethinol was a common component in the volatile oil from the stems, leaves and roots of G. littoralis, its contents in the stems and leaves, roots were 38.21% and 74.02%, respectively. The volatile oil from the stems, leaves and roots of G. littoralis had a certain E-mail:zwhjzs@126.com inhibitory effect on F. solani, F. incarnatum, F. oxysporum, A. parasiticus and A. flavus, especially volatile oil from the stems and leaves. CONCLUSIONS There is a significant difference in chemical components of the volatile oil between the roots, stems and leaves of G. littoralis, both of which have certain in vitro antifungal activity.
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Through reviewing ancient and modern literature, the textual research of Anemarrhenae Rhizoma(AR) has been conducted to verify the name, origin, changes in production areas, quality evaluation, harvesting and processing methods, so as to provide reference for the development and utilization of the famous classical formulas containing AR. Through the herbal textual research, AR was first published in Shennong Bencaojing, and has been used as the proper name for this herb for generations, and the mainstream source of AR used for generations is the rhizome of Anemarrhena asphodeloides. The high-quality production areas that have been revered throughout the ages are Hebei, Shanxi, Shaanxi, Inner Mongolia and Fangshan district of Beijing, etc. In recent times, AR produced in Yixian county of Hebei province(Xiling Zhimu), is better known and is regarded as a very good source. At present, cultivated AR is mainly produced in Yixian county and Anguo of Hebei province, Bozhou of Anhui province and other places. The medicinal parts of AR in ancient and modern times are all rhizomes, and the quality is better if it has thick flesh, hard wood, yellow outer color and white section color. The harvesting time recorded in ancient medical books is usually in lunar February and August, with exposure to dryness, while modern harvesting is spring and autumn. The processing methods of the past dynasties were mainly to remove the hair when using, avoid iron when cutting, process with wine or salt water, while the two main specifications in modern times are raw and salted products. Based on the systematic research, it is recommended that the dried rhizome of A. asphodeloides in the famous classical formulas be used for AR. If the original formula specifies processing requirements, it should be operated according to the requirements, if the processing requirements are not indicated, the raw products can be used as medicine.
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OBJECTIVE To provide reference for clarifying improvement effects of Anemarrhena asphodeloides on sepsis- induced myocardial injury and potential material basis. METHODS Water extract of A. asphodeloides was extracted by thermal reflux method. Total xanthone and total saponins in A. asphodeloides were separated by macroporous adsorption resin. The mice model of sepsis-induced myocardial injury was established by intraperitoneal injection of lipopolysaccharide. The effects of the location of three extraction fractions and the monomers of A. asphodeloides as mangiferin, timosaponin AⅢ and timosaponin BⅡ on the survival rate of the model mice were explored. HE staining was used to observe the effects of mangiferin, timosaponin AⅢ and timosaponin BⅡ on myocardial morphology in model mice. The effects of mangiferin on mRNA expressions of inflammatory cytokines [interleukin-6 (IL-6), IL-1β and tumor necrosis factor-α (TNF-α)] and the level of reactive oxygen species (ROS) in myocardial tissue of model mice were detected. RESULTS Compared with the model group, the survival rate of mice in the intervention group of total xanthone, total saponins and water extract was increased to different extents, especially total xanthone fraction. Mangiferin, timosaponin AⅢ and timosaponin BⅡcould improve the degree of myocardial cell swelling and muscle bundle arrangement disorder in model mice, especially mangiferin. Compared with model group, mRNA expressions of IL-6, IL- 1β and TNF- α, ROS level in myocardium of mice after mangiferin intervention were decreased to different extents. CONCLUSIONS The different extraction fractions of A. asphodeloides can improve survival rate of mice with sepsis-induced myocardial injury, especially total xanthone fraction. Mangiferin is the best among the three monomers of A. asphodeloides to improve sepsis-induced myocardial injury, which may play a role in anti-sepsis myocardial injury by anti-inflammation and antioxidantion.
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By reviewing ancient materia medica, medical and prescription books, combined with modern literature, the textual research of Stephaniae Tetrandrae Radix has been conducted to verify the name, origin, producing area, harvesting and processing methods. Through textual research, the results show that the mainstream name of this herb recorded in the past dynasties is Fangji, which is also called Hanzhong Fangji because it is produced in Hanzhong city, and after the Tang dynasty, it was gradually divided into Hanfangji and Mufangji, and there is the saying that Han Zhushuiqi, Mu Zhufengqi. The names of Fenfangji and Guangfangji were first seen in the republic of China. In addition, Fenfangji was once distributed in Hankou, so it was also known as "Hanfangji", which is easily confused with the traditional Hanzhong Fangji for short. Based on the original research, it is concluded that Aristolochia heterophylla(Hanzhong Fangji)is the mainstream of Stephaniae Tetrandrae Radix used in the Qing dynasty and before, and the application history of Cocculus orbiculatus can be traced back to before the Tang dynasty. After the Ming dynasty, Stephania tetrandra gradually became another main origin, and in the Republic of China, A. fangchi was used as a medicine for Stephaniae Tetrandrae Radix, but in modern times it was banned because it contained aristolochic acid as a toxic ingredient, and S. tetrandra has become the mainstream legal origin. The traditional production area of Hanzhong Fangji is Hanzhong, Shaanxi province, while today the mainstream of S. tetrandra is manly produced in Jiangxi and other places. Based on the quality evaluation research, the quality of Hanzhong Fangji is better with the radial texture of section used as radial solution, yellow solid and fragrant. Fenfangji with solid quality, white inside, powdered enough, less fiber and radiating texture is better. From the harvesting and processing research, the root of Fangji is mostly harvested in spring and autumn, and the outer bark should be removed in some literature. Before the Ming dynasty, this herb was dried in the shade, and after the Ming dynasty, it was dried in the sun. The modern production processing of Fangji is to harvest it in autumn, wash it, remove the rough bark, dry it to half dry, cut it into sections, and then cut it longitudinally if it is large, and dry it. Based on the results, combined with current studies on the toxicity of aristolochic acid and influencing factors such as commercial circulation, it is suggested that S. tetrandra should be used as the origin of Fangji, the processed products are selected according to the prescription requirements, and those without specified requirements can be processed by referring to the raw products in the 2020 edition of Chinese Pharmacopoeia.
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OBJECTIVE To establish the fingerprints of c ultivated and wild Anemarrhena asphodeloides,and to identify their differential components. METHODS Using an evaporative light-scattering detector , the high performance liquid chromatography combined with Similarity Evaluation System of TCM Chromatographic Fingerprint (2012 edition) were used to establish fingerprints of 14 batches of cultivated A. asphodeloides and 14 batches of wild medicinal materials ,and evaluate their similarity. The common peaks were identified by comparison with the chromatogram of the mixed control. At the same time ,the contents of components corresponding to common peaks in cultivated and wild A. asphodeloides were determined. The principal component analysis and orthogonal partial least squares discrimination analysis were adopted to identify differential components of them ,and compare the contents of them. RESULTS Among 28 batches of A. asphodeloides ,10 common peaks were found ,i.e. neomangiferin(peak 1),mangiferin(peak 2),isomangiferin(peak 3),timosaponin B Ⅱ(peak 7),timosaponin B Ⅲ(peak 8), timosaponin Ⅰ(peak 9),timosaponin A Ⅲ(peak 10). The similarities of fingerprints of samples with control fingerprint were no less than 0.963. The average total contents of seven components in cultivated and wild A. asphodeloides were 74.18 and 84.72 mg/g, respectively;there was statistical significance (P<0.05). The cultivated and wild A. asphodeloides could be divided into two categories. The differential components were neomangiferin ,mangiferin,timosaponin B Ⅱ and timosaponin A Ⅲ(VIP values were all higher than 1). The content of neomangiferin in cultivated products was significantly higher than that in wild products (P< 0.05),and the contents of mangiferin ,timosaponin B Ⅱ and ti mosaponin A Ⅲ were significantly lower than those in wild products (P<0.05). CONCLUSIONS Fingerprint of A. asphodeloides is established ,and differential components of cultivated and wild A. asphodeloides are identified primarily.
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Objective: Network pharmacology combines drug and disease targets with biological information networks based on the integrity and systematicness of the interactions between drugs and disease targets. This study aims to explore the molecular basis of Hanshi Zufei formula for treatment of COVID-19 based on network pharmacology and molecular docking techniques. Methods: Using TCMSP, the chemical constituents and molecular targets of Atractylodis Rhizoma, Citri Reticulatae Pericarpium, Magnoliae Officinalis Cortex, Pogostemonis Herba, Tsaoko Fructus, Ephedrae Herba, Notopterygii Rhizoma et Radix, Zingiberis Rhizoma Recens, and Arecae Semen were investigated. The predicted targets of novel coronavirus were screened using the NCBI and GeneCards databases. To further screen the drug-disease core targets network, the corresponding target proteins were queried using multiple databases (Biogrid, DIP, and HPRD), a protein interaction network graph was constructed, and the network topology was analyzed. The molecular docking studies were also performed between the network's top 15 compounds and the coronavirus (SARS-CoV-2) 3CL hydrolytic enzyme and angiotensin conversion enzyme II (ACE2). Results: The herb-active ingredient-target network contained nine drugs, 86 compounds, and 49 drug-disease targets. Gene ontology (GO) enrichment analysis resulted in 1566 GO items (P < 0.05), among which 1438 were biological process items, 35 were cell composition items, and 93 were molecular function items. Fourteen signal pathways were obtained by enrichment screening of the KEGG pathway database (P < 0.05). The molecular docking results showed that the affinity of the core active compounds with the SARS-CoV-2 3CL hydrolase was better than for the other compounds. Conclusion: Several core compounds can regulate multiple signaling pathways by binding with 3CL hydrolase and ACE2, which might contribute to the treatment of COVID-19.
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OBJECTIVE:To analyze the chemotypes of volatile components from Perillae Folium of different germplasms ,and to investigate the relationship of germplasm and leaf color with chemotype. METHODS :The fingerprints of volatile components from 30 batches of Perillae Folium were prepared by GC-MS with P 4 peak as reference. Similarity Evaluation System for TCM Chromatographic Fingerprint (2004A edition )was applied to evaluate the similarity and confirm common peaks. The volatile components of Perillae Folium were determined by the same GC-MS method. Qualitative Navigator (B.08.00)software was used to analyze and compare with NIST 17.0 standard mass spectrum database. The compounds corresponding to the peak were analyzed ; clustering analysis was carried out with Origin 2018 software. RESULTS :There were 13 common peaks in the fingerprints of volatile components from 30 batches of Perillae Folium . The similarities were 0.13-1.00. Totally 54 components were identified from 30 batches of Perillae Folium of different germplasm. Cluster analysis showed that 30 batches of Perillae Folium samples could be clustered into three categories ;among them ,SCY-1,YNT-9,YNX-17,YN-28 were clustered into one category ,with phenylpropanoid-elemicin(PP-e as )the main volatile component ,being PP-e type ;GS-4,GS-7,GS-11,GS-19,HBA-14, HBA-20,GZZ-8,LN-39,GSL-27,GSQ-32,GSQ-33,GST-31,YNW-12,LN-38 were clustered into one category ,and the content of perilla ketone (PK)in them was the highest except for LN- 38, being PK type [the content of phenylpropanoid-apiol(PP-a)in LN- 38 was higher than that of perilla ketone ,being PP-a type] ;HBS-2,HBS-3,HBS-6, C201859)HBS-15,HBS-16,HBS-24,HBS-25,GX-26,SXS-30,SCC- 36,RB-37,SC-29 were clustered into one category ,and thecontent of perillaldehyde (PA)was the highest ,being PA type.The color characteristics of Perillae Folium of different germplasm showed that Perilla frutescens (L.) Britt. var.frutescens with green leaves on both sides was PK type ,while P. frutescens (L.)Britt. var. arguta with purple leaves on one or both sides was PA type ,and P. frutescens (L.) Britt var. auriculato-dentata C. Y. Wu et Hsuan ex H. W. Li was PP-e type. CONCLUSIONS:The chemotype of volatile components in Perillae Folium have a certain corresponding relationship with their leaf colors. Most of P. frutescens (L.)Britt. var. arguta with purple leaves on one side or both sides are PA type. P. frutescens (L.) Britt. var. acuta (Thunb.)Kudo,P. frutescens (L.)Britt var. auriculato-dentata C. Y. Wu et Hsuan ex H. W. Li and P. frutescens (L.)Britt. var. frutescens with green leaves on both sides do not belong to PA type ,among which P. frutescens (L.)Britt var. frutescens is PK type ,while P. frutescens (L.)Britt var. auriculato-dentata C. Y. Wu et Hsuan ex H. W. Li is mostly PP-e type.
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OBJECTIVE:To establish the fingerprint of ethanol extract and acetone extract from Anemarrhena asphodeloides and its different processed products ,and to investigate the spectrum-effect relationship between the fingerprint and the antioxidant activity. METHODS :HPLC method and HPLC-ELSD method were adopted. The determination was performed on Thermo BDS Hypersil C 18 column with mobile phase consisted of acetonitrile- 0.2% acetic acid at the flow rate of 1.0 mL/min. The column temperature was 30 ℃,and the detection wavelength was set at 258 nm. The sample size was 10 μL. The determination was performed on XDB-C 18 columnwith mobile phase consisted of acetonitrile-0.1% acetic acid (gradient elution )at the flow rate of 0.9 mL/min. The column temperature was 30 ℃ . The temperature of atomizer was 40 ℃ and the flow rare of N 2 was 1.6 mL/min. The sample size was 10 μL. Using mangiferin and timosaponin B Ⅱ as reference ,Fingerprint Similarity Eva- com luation System of TCM Chromatogram (2004A edition )was adopted to draw the fingerprint of ethanol extract and acetoneextract from 20 batches of A. asphodeloides and its different processed products to confirm common peaks. Using scave nging rate of 1,1-diphenyl-2-trinitrophenylhydrazine(DPPH)radical as index,antioxidant activities of ethanol extract and acetone extract from 20 batches of A. asphodeloides and its processed products were investigated. Using scavenging rate of DPPH radical as dependent variable ,common peak area as independent variable ,PLSR was used to analyze the spectrum-effect relationship of ethanol extract and acetone extract from A. asphodeloides with antioxidantion activity. RESULTS :Eight peaks (M1-M8)were identified in the fingerprints of ethanol extracts from 20 batches of processed A. asphodeloides . Mangiferin (chromatogram peak M 7)was identified with similarity of 0.389-1.000;seven comon peaks (S1-S7)and timosaponin B Ⅱ(peak S 5)were identified in the fingerprint of acetone extract ,and the similarity was 0.044-0.999. DPPH radical scavenging rate of ethanol extract from 20 batches of A. asphodeloides and its processed products was 21.23%- 81.39%,and A. asphodeloides was significantly lower than salt-processed A. asphodeloides with salt wine-processed A. asphodeloides (P<0.001);and that of acetone extract was 49.73%-83.78%,and A. asphodeloides was significantly higher than stir-baked A. asphodeloides with salt ,wine or fire (P<0.001). The standardized regression coefficients of peaks M 2-M7 in the spectrum of ethanol extract from A. asphodeloides were all greater than 0,which was positively correlated with antioxidant activity. Only the variable importance projection (VIP)value of peak M 7 was greater than 1,which had an important contribution. The standardized regression coefficients of peaks S 4-S7 in the acetone extract spectrum of A. asphodeloides were greater than 0,and were positively correlated with antioxidant activity. The order of VIP values was peak S 5>S6>S4,and the VIP values were all greater than 1. CONCLUSIONS:The fingerprint of the different processed products A. asphodeloides and its antioxidant activity spectral effect relationship were successfully established ;mangiferin(peak M 7)may be the main antioxidant substance of ethanol extract from A. asphodeloides . Timosaponin B Ⅱ(peak S 5),peak S 6 and peak S 4 may be the main antioxidant substance in acetone extract from A. asphodeloides .
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OBJECTIVE:To establish the rapid field identification method of Cryptotympana pustulata ecdysis. METHODS : 3D depth of field synthesis technology was used to identify 50 batches of C. pustulata ecdysis and its adulterants from the length of beak ,size and protrusion degree of upper labial base ,the protrusion degree of the lower labial base ecdysis and the color of its upper transverse groove ,the number and shape of main and lateral spines on the foot ,significance of abdominal valves ,the number of webs ,the number and shape of side plates ,the number of tergum rings ,terminaliae,etc. RESULTS :Among 50 batches of samples ,S1-S5,S26-S30,S36-S50 were C. pustulata ecdysis;S21-S25 was adulterants of C. pustulata ecdysis after weight gain ;S31-S35 was adulterants of C. pustulata ecdysis after extraction ;S6-S20 were ecdysis from Tibicen flammatus ,C. flammatta,Lyristes pekinensis ,all of which were adulterants. The main distinguishing feature of C. pustulata ecdysis and its adulterants was that abdomen and ventral surface of C. pustulata ecdysis were triangular ,and the abdomen and ventral surface of other species was nearly parallel ;the valve of C. flammatta ecdysis was obvious ,but those of other varieties were not obvious ;the lateral appearance of terminaliae of C. flammatta ecdysis was sharper than those of other species ;there was an acute angle between the front foot accessory thorns and the end thorns of the T. flammatus ecdysis,and an obtuse angle between the front foot accessory thorns and the end thorns of the L. pekinensis ecdysis. CONCLUSIONS :The method is simple ,reliable and suitable for rapid field identification of C. pustulata ecdysis and its adulterants.
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OBJECTIVE: To establish a method for simultaneous determination of spinosin and jujuboside A in the seads of Ziziphus jujuba, and to investigate its quality grading standard. METHODS: HPLC-ELSD method was adopted. The separation was carried out on Inertsil ODS-SP column with mobile phase consisted of acetonitrile-water (gradient elution) at the flow rate of 1.0 mL/min. The column temperature was 30 ℃, the temperature of drift tube was 90 ℃, the flow of carrier gas was 2.9 L/min and injection volume was 20 μL. The thickness, width, length and 100-grain quality of the medicinal materials were used as indicators to investigate the appearance traits. SPSS 22.0 software was used to analyze the correlation of the contents of spinosin and jujuboside A, its appearance traits with the quality constant of TCM, and establish a quality classification standard for the seads of Z. jujuba. RESULTS: The linear range of spinosin and jujuboside A were 1.03-6.18 μg/mL (r=0.999 7), 1.05-6.30 μg/mL (r=0.999 8); the limits of quantitation were 0.171, 0.174 μg/mL, respectively; the limits of detection were 0.052, 0.053 μg/mL, respectively. RSDs of precision, stability and reproducibility tests were all lower 2%. The recoveries were 99.01%-102.97% (RSD=1.39%, n=6), 97.94%-101.03% (RSD=1.13%, n=6), respectively. Correlation analysis results showed that the length, width, 100-grain quality spinosin content and jujuboside A content of the medicinal materials were positively correlated with the quality constant of TCM. The results of quality classification for 30 batches of medicinal materials showed that S1-S4 and S7-S12 were first-class products; S5, S6, S13-S17 and S20-S30 were second-class products; S18 and S19 were third-class products. CONCLUSIONS: Established content determination method is simple, precision, accurate and stable, and can be used for simultaneous determination of spinosin and jujuboside A in the seads of Z. jujuba. Established quality grading standard of the seads of Z. jujuba can be used to evaluate the quality.
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Molecular pharmacognosy is an emerging interdisciplinary subject with crude drugs as research subjects. Its development provides a new theoretical method and technique for traditional pharmacognosy research, so that the study of crude drugs has reached the level of gene. As traditional Chinese materia medica, Bupleuri Radix has developed molecular pharmacognosy research on the basis of traditional research Methods , and achieved certain Results . This article summarized the research achievements of Bupleuri Radix through molecular pharmacognosy method in recent years, and prospected this field, in order to further provide references for the protection, development and utilization of Bupleuri Radix resources and other TCM resources.
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Objective To research the effects of drought stress on activity of key enzyme in saikosaponin biosynthesis and saponins content in Bupleurum chinense; To reveal response of Bupleurum chinense to drought stress from protein level. Methods Bupleurum chinense was cultivated in potted water control experiment with 70%–80%, 60%–70%, 40%–50% and 20%–30% saturated soil water contents. The enzyme activities of 3-hydroxy-3-methyl-glutaryl-coenzyme A reductase (HMGR), isoprenyl-based coke (IPPI), farnesyl pyrophosphate synthase (FPS) and β-carotenoid synthase (β-AS) of six months and one year old Bupleurum chinense were measured. The contents of saikosaponins a and d in samples of different soil water contents were determined by HPLC. Results When the saturated moisture was 40%–50%, the enzymatic activities of HMGR, IPPI, FPS and β-AS were the highest, followed by saturated moisture 60%–70%、70%–80% and 20%–30%. The trend of saikosaponin was similar to that of the activity of key enzyme. Conclusion 40%–50% soil saturated water content can significantly increase the activity of the key enzymes in the saikosaponin synthesis pathway. The saponin content and enzyme activity show a significant positive correlation, indicating that under drought stress, Bupleurum chinense regulates the synthesis of saikosaponin by regulating the key enzyme activity of saikosaponin synthesis pathway to respond drought stress.