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Objective To study the quality standard of Gardenia jasminoides and its effective parts. Methods TLC was used to identify Gardenia jasminoides and its effective parts. The heavy metals, harmful elements, and moisture in Gardenia jasminoides and its effective parts were examined. The content of Gardenia jasminoides and its effective parts was determined by high performance liquid chromatography. Results TLC method could be used to identify Gardenia jasminoides and its effective parts. The moisture content of Gardenia jasminoides and its effective parts were 8.4% and 3.2%, respectively. ICP-MS was used to determine the contents of five elements in Gardenia jasminoides and its effective parts simultaneously. There was a good linear relationship between arsenic, cadmium, copper, mercury, and lead in the range of 0~20, 0~10, 0~500, 0~5 and 0~20 ng/ml, respectively; The method detection limit of each metal element was 3.3×10−5~1.3×10−3 mg/kg. The relative standard deviation (RSD) of precision was 0.32%~0.82%. RSD values of each element content showed that the method had good repeatability. And the recoveries of arsenic, cadmium, copper, mercury, and lead were 103%~112%, 98%~99%, 98%~99%, 105%~106% and 100%~103%, respectively (n=3). The stability of each element was good within 8 h. The contents of the five elements were within the limits of the current edition of Chinese Pharmacopoeia. The standard curve equation of gardenia was Y=15860X+22543, r=0.9999, indicating that there was a good linear relationship of gardenia in the range of 20.16~322.6 μg/ml. The RSD of precision was 1.86%. RSD of the two samples were 2.38% and 2.60%, respectively, indicated that the method had good repeatability. The average recovery of Gardenia was 99.1% (n=6). The stability of the two solutions was good within 8 h. The contents of gardenia and its effective parts were 5.71% and 34.2%, respectively. Conclusion The research on the quality of Gardenia jasminoides effective parts was carried out based on the research on the quality of Gardenia jasminoides, and the results met the requirements. Therefore, the method established in this experiment could control the quality of Gardenia jasminoides and its effective parts simultaneously.
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OBJECTIVE To compare the components of volatile oil from Gardenia jasminoides and their liver protective effect before and after stir-frying with wine. METHODS Steam distillation was used to exact the volatile oil from G. jasminoides and wine stir-fried G. jasminoides. The components of volatile oil were identified by GC-MS method, and the relative mass fraction of each component was calculated by peak area normalization method. The rats were randomly divided into normal group, model group, positive control group (bifendate suspension 35 mg/kg), G. jasminoides low-dose and high-dose groups [1, 2 g/kg (calculated by crude drug)] and wine stir-fried G. jasminoides low-dose and high-dose groups [1, 2 g/kg (calculated by crude drug)] with 10 rats in each group. Liver injury model was established by intraperitoneal injection of 40% carbon tetrachloride in rats of each group after continuous intragastric administration of corresponding drug solution for 7 days. The status, serum biochemical indexes, liver biochemical indexes and liver pathological sections of rats in each group were compared. RESULTS Twenty-three volatile oil components from G. jasminoides and 25 volatile oil components from wine stir-fried G. jasminoides were identified; there were 18 common volatile oil components, of which the contents of 17 common components were decreased, while the content of one common component was increased due to stir-frying with wine. Compared with model group, the symptoms of depression and liver cell damage of rats in each administration group were improved to varying degrees; the serum levels of adenosine deaminase, alanine transaminase, aspartate transaminase, direct bilirubin, lactate dehydrogenase,prealbumin, total bile acid and total bilirubin were significantly decreased, while the total protein level was significantly increased; the level of malondialdehyde in liver tissue was significantly decreased, there were statistical significance (P<0.05 or P<0.01). CONCLUSIONS During stir-frying with wine, the contents of 17 volatile oil components are decreased, while the content of one volatile oil component is increased. Wine stir-fried G. jasminoides shows liver protective effect. .
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MYB transcription factors are involved in the regulation of various secondary metabolites biosynthesis. Gardenia jasminoides Ellis is the commonly used Chinese herbal medicine, and its main active ingredient is geniposide. Here, leaves and flower buds at different developmental stages of G. jasminoides were used to explore MYB transcription factors related to geniposide biosynthesis based on genome and transcriptome analysis. Transcriptome data analysis showed that, different from the expression of the common pathway genes for terpenoid biosynthesis, the expression level of genes in the specific pathway of geniposide biosynthesis was significantly higher in flower buds than in leaves, which was the same as the organ accumulation pattern of this component. And the promoter regions of geraniol synthase, iridoid synthase and geniposidic acid methyltransferase involved in the specific pathway all contained multiple MYB-binding sites. A total of 105 MYB transcription factors were obtained by annotating the coding genes of G. jasminoides, which were divided into 68 1R-MYB, 33 R2R3-MYB, 3 3R-MYB and 1 atypical MYB transcription factor according to the number of conserved domain. Based on the analysis of phylogenetic tree and quantitative real-time PCR, three candidate MYB transcription factors related to geniposide biosynthesis were selected, including potential positive regulation factor GjMYB23 and negative regulation factors GjMYB31 and GjMYB73. The results of this study will lay a foundation for searching the regulation of geniposide biosynthesis and further analysis of the quality formation mechanism of G. jasminoides, so as to promote the breeding of excellent varieties of G. jasminoides.
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The current study explored the hepatotoxicity among closed-ring genipin, open-ring tautomer of genipin and gardenia blue that generated from genipin and amino acid reaction using HepaRG cells to identify the material basis of genipin-induced hepatotoxicity in vitro. The effects of temperature, pH value and different kinds of amino acids on the chemical structure tautomerism between closed-ring and open-ring tautomer of genipin and the production of gardenia blue were investigated firstly, which aimed to explicit the conditions that could distinguish the closed-ring genipin and its open-ring tautomer, and the conditions generating gardenia blue, which were applied to prepare different kinds of gardenia blue; the CCK-8 kit was employed to analyze the hepatotoxicity of closed-ring genipin, open-ring tautomer of genipin and gardenia blue. From the results, it was found that, the structure transformation from close-ring to open-ring of genipin could be inhibited under the condition with acid environment; being essential groups to generate gardenia blue, the primary amino group and the open-ring tautomer of genipin reacting to generate the dihydropyridine ring was probably the key structure of gardenia blue; the structure characteristics existed apparent distinction at the reactive temperature of 37 ℃ and 80 ℃; compared to the culture condition with pH = 7.4, the concentration of genipin with close-ring in culture medium was significantly increased at pH = 5, but the cell viability did not decreased; the cell toxicity of gardenia blue was apparently lower than open-ring tautomer of genipin, and even some kinds of gardenia blue showed growth promoting effect on HepaRG cells. Here, it was suggested potentially that open-ring tautomer of genipin be the important material basis to induce hepatotoxicity, which could provide a cue and lay a foundation for the elucidation of the underlying mechanism of genipin-induced hepatotoxicity.
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Alzheimer’s disease (AD)is a common latent neurodegenerative disease ,which is characterized by cognitive impairment,loss of learning and memory function ,abnormal behavior and dementia. At present ,there is no specific drug to effectively prevent or reverse AD. Gardenia jasminoides is the dried and mature fruit of G. jasminoides J. Ellis ,a gardenia plant in Rubiaceae. Its chemical components mainly include iridoids ,triterpenoids,organic acids and volatile oils ,among which iridoids are the main active components of G. jasminoides . This paper summarizes the researches on the mechanism of iridoids from G. jasminoides against AD at home and abroad in recent years ,in order to provide reference for the development of new drugs against AD.
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OBJECTIVE To establish the fingerp rint of decoction pi eces and dispensing granules of Gardenia jasminoides ,to determine the contents of 6 components,so as to evaluate its quality combined with chemical pattern recognition. METHODS High performance liquid chromatography (HPLC)was used. Using geniposide as the reference ,Similarity Evaluation System for Chromatographic Fingerprint of TCM (2012 edition)was used to draw the fingerprints of 20 batches of G. jasminoides decoction pieces and 10 batches of G. jasminoides dispensing granules. Similarity evaluation and common peaks identification were conducted. The same HPLC method was adopted to determine the contents of deacetyl asperulosidic acid methyl ester ,geniposide, picrocrocin,rutin,crocin-Ⅰ and crocin- Ⅱ. ORIGIN 9.1 software was used for hierarchical clustering analysis ,and SIMCA 16.0 software was used for principal component analysis (PCA) and partial least squares-discriminant analysis. The differential components affecting the quality of decoction pieces and dispensing granules were screened by taking the variable importance in projection(VIP)value>1 as the standard. RESULTS There were 24 common peaks for both 20 batches of G. jasminoides decoction piece and 10 batches of G. jasminoides dispensing granules ;a total of 22 common peaks were found in the fingerprints of 30 batches of samples ,and the similarity was not lower than 0.96;six common peaks were identified ,i.e. deacetyl asperulosidic acid methyl ester (peak 2),geniposide(peak 6),picrocrocin(peak 9),rutin(peak 11),crocin-Ⅰ(peak 15),crocin-Ⅱ(peak 17). Average contents of above 6 components in G. jasminoides decoction pieces were 1.04,57.00,1.30,1.03,9.63 and 0.99 mg/g, respectively;those of G. jasmin oides dispensing granules were 0.96,17.04,0.37,0.27,0.73 and 0.04 mg/g,respectively. PCA results showed that G. jasminoides decoction pieces and G. jasminoides dispensing granules were clustered into respective one category ,which was consistent with results of cluster analysis. There were 9 common peaks with VIP value >1, which were 16,14,3,17(crocin-Ⅱ),15(crocin-Ⅰ),18, 22, 2 (deacetyl asperulosidic acid methyl ester) and 21. CONCLUSIONS The estab lished fingerprint and content determination method are simple and reproducible. Combined with chemical pattern recognition ,it can be used to evaluate the quality of decoction pieces and dispensing granules of G. jasminoides . Nine corresponding components represented by peak 16 and so on are the differential components that affect the quality of them.
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ObjectiveTo study the chemical structure of gardenia blue pigment and its inhibitory activity against monoamine oxidase B (MAO-B), in order to seek a potential feasible way for rational utilization and value enhancement of iridoids in Gardeniae Fructus. MethodIridoid glycosides in Gardeniae Fructus were hydrolyzed by cellulase to obtain their aglycones and reacted with amino acids. Then, the products were purified by column chromatography packed with D101 macroporous resin and preparative liquid chromatography to obtain gardenia blue pigments, and the gardenia blue pigments were identified by nuclear magnetic resonance (NMR) and mass spectrometry (MS). Benzylamine was used as the reaction substrate of MAO-B and in vitro incubated with gardenia blue pigment monomers, high performance liquid chromatography (HPLC) was employed to determine the production of benzaldehyde for evaluating the inhibitory effect of gardenia blue pigments on MAO-B, the mobile phase was methanol (A) -50 mmol·L-1 potassium phosphate buffer (B, pH 3.2) (2∶3), and the detection wavelength was 245 nm. ResultEight compounds of gardenia blue pigment A-H were synthesized and identified. In MAO-B inhibition test, compared with geniposide, the inhibitory activity of gardenia blue pigment D and E was significantly enhanced (P<0.05). Compared with the 6β-hydroxygeniposide, the inhibitory activity of gardenia blue pigment G and H was significantly enhanced (P<0.05, P<0.01). All the four gardenia blue pigments showed better MAO-B inhibitory activity than the prototype compounds. ConclusionGardenia blue pigment is a simple compound formed by one molecule of amino acid and one molecule of iridoid. Some gardenia blue pigments have better MAO-B inhibitory activity than the prototype compounds. The activity of gardenia blue pigment produced by different substrates is different, and the high-value gardenia blue pigment can be prepared based on experimental optimization, which can expand the application range of gardenia blue pigment and enrich the comprehensive utilization of iridoids from Gardeniae Fructus.
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Growing evidences indicate that the development of mesenteric phlebosclerosis (MP) is associated with long-term gardenia fruit (GF) intake. Besides duration and total dosage of GF ingestion, other factors associated with the development of MP or the symptoms of MP have not been known. We searched for previous case reports of MP from Japan. MP patients were divided into two groups : asymptomatic group without abdominal symptoms or symptomatic group. Age, gender ratio, body size, and duration of GF ingestion of the both groups were statistically analyzed. We evaluated concomitant diseases that can cause elevated venous pressure in the both groups. Colectomy rate were compared between symptomatic men and symptomatic women. Severe symptoms including ileus, stenosis peritonitis, and perforation were also compared between men and women. Age and sex were analyzed in all 164 cases. The gender ratio of women to men in the symptomatic group was higher than that in the asymptomatic group. However, colectomy rate in the symptomatic group was similar between men and women. Ileus, stenosis, peritonitis, and perforation were similarly found in both men and women. We found 15 symptomatic MP patients with concomitant diseases that can cause phlebostasis. None of the asymptomatic had these diseases. Concomitant diseases that can cause elevated venous pressure might be associated with symptomatic MP. The severity of MP seems to be similar between men and women. Association of gender difference with the development of MP symptoms was uncertain.
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Objective: To study the intervention effect of Gardenia jasminoside var. radicans and its main effective component of geniposide on the degranulation model of RBL-2H3 cells based on metabolomics. Methods: The changed metabolite profile of RBL-2H3 cells was detected by UPLC-QTOF-MS; PCA (principal component analysis) and OPLS-DA (orthogonal partial least squares discriminant analysis) in SIMCA software were used to select the potential biomarkers. Meanwhile, the clustering and heat map analysis for those potential biomarker levels were carried out by MEV software. Result: A total of 54 and 46 relevant biomarkers of G. jasminoside var. radicans and geniposide were selected, of which 31 biomarkers enriched in five disturbed metabolite pathways, including glycine, aspartic acid and glutamate metabolism, glutathione metabolism, histamine metabolism, energy metabolism, and nicotinamide metabolism pathways. Conclusion: G. jasminoside var. radicans and geniposide exerts the inhibitory effect on the degranulation model of RBL-2H3 cells by regulating histamine metabolism, oxidative stress and energy metabolism, and geniposide was one of the main efficacious substance basis of G. jasminoside var. radicans.
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Objective: To study the main constituents from Gardenia jasminoides. Method In this study, the chemical constituents of enrichment fraction of iridoid glycosides were isolated by various chromatographic techniques and their structures were elucidated by spectroscopic analyses and comparison of NMR data with those reported in literatures. Results: The 60% ethanol extract of G. jasminoides was subjected to HP-20 macroporous adsorption resin CC to yield 30% ethanol fraction (GJ-2, UPLC-Q/TOF-MS method was used to identify the enrichment fraction of iridoid glycosides). Thirty-one compounds were obtained and characterized as 2'-O-trans-coumaroylgardoside (1), 6'-O-trans-sinapoylgardoside (2), 7-deoxygardoside (3), tarenninoside C (4), 2'-O-coumaroylmussaenosidic acid (5), 10-O-caffeoyl deacetyldaphylloside (6), 6'-O-trans-sinapoylgeniposide (7), genipin-1-O-β-D-gentiobioside (8), geniposide (9), 7-deoxy-8-epiloganicacid (10), secologanoside (11), gardenamide A (12), 6'-O-trans-sinapoyljasminoside B (13), epijasminoside A (14), jasminodiol (15), 6'-O-trans-sinapoyljasminoside L (16), 3-(β-D- glucopyranosyl-oxymethyl)-2,4,4-trimethyl-2-cyclohexen-1-one (17), jasminoside C (18), sinapinic acid (19), caffeic acid (20), methyl gallate (21), C-veratroylglucol (22), β-hydroxypropiosyringone (23), 3-hydroxy-1-(4-hydroxy-3-methoxyphenoyl) propan-1-one (24), threo-guaiacylglycerol-8'-vanillic acid ether (25), 1,2-bis-(4-hydroxy-3-methoxyphenyl)-1,3-propanediol (26), trans-2,3,5,4'-tetrahydroxystilbene-2-β-D-glucoside (27), 1-sinapoyl-β-D-glucopyranoside (28), 1,3,5-trimethoxybenzene (29), rutin (30), and glycyrrhisoflavone (31), respectively. Conclusion: Compounds 1-12are iridoid glycosides and 13-18are monoterpenoid glycosides. Compounds 6, 10, 22-29, and 31 were identified from Gardeniae Fructus for the first time.
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Objective@#To explore the cause and type of pigmentation in the livers and kidneys of rats caused by a compound Chinese medicine preparation. @*Methods@#The experiment consist of low, medium, and high dose groups and a control group, the Sprague-Dawley rats in these groups were orally given 1.0, 2.0 and 4.0 g/kgbw of a compound Chinese medicine preparation of gardenia and distilled water for 30 days, respectively. The body weight, diet, hematology and histopathology of the rats in each group were observed for changes in pigment metabolism. @*Results@#In the first and second weeks of the experiment, the rats in the low, medium, high dose groups and the control group showed no abnormal symptoms or signs. From the third weekend, the urine of the rats in the high dose group turned thick yellow and green, and the stool color became light. During the experiment, no rats died. There were statistically significant differences in body weights and weight gains among these groups ( P<0.05 ) . There were statistically significant differences in total food utilization, direct bilirubin, r-glutamyl transferase, alkaline phosphatase, and liver/body ratios among these groups ( P<0.05 ). Gross examination revealed that the livers and kidneys of rats in the high dose group were dull and green. Microscopic examination revealed changes in dark pigment particles in the livers and kidneys of rats in the high dose group. Histochemical staining confirmed that pigments in the livers and kidneys were bile pigments. @*Conclusions@#At a dosage of 4.0 g/kgbw, a compound Chinese medicine preparation of gardenia can lead to bile pigment deposition in the livers and kidneys of rats due to cholestasis.
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Objective To develop a simple, rapid and sensitive method for the determination of major compounds from Gardenia jasminoides Ellis using liquid chromatography tandem mass spectrometry (LC-MS/MS).Methods The analysis was performed on Dikma Diamonsil?C18 (100mm×4.6mm, 5μm) column with acetonitrile-0.1%acetic acid and 0.1%acetic acidwater as mobile phase at a rate of 0.4ml/min.The column temperature was set at 40℃and the injection volume was 2μl.Quantification of these compounds was performed by LC-MS/MS with positive or negative ion mode electrospray ionization (ESI) in the multiple reaction monitoring (MRM) mode.Nebulizer gas, 3L/h;drying gas, 15L/h;desolvation line (DL) temperature, 240℃;heat block temperature, 300℃;CID, 230kPa.The mass transition of the precursor/product ions was monitored at m/z 391.10→149.30for shanzhiside, 573.40→365.05for genipin-1-gentiobioside, 447.30→225.15for geniposide.Results The regress equation of shanzhiside, genipin-1-gentiobioside and geniposide were Y=243.810 X-289.957, r=0.999 9;Y=137.125 X+2 092.76, r=0.999 6;Y=2 030.32 X+823 213, r=0.999 8in the range of 10.76-215.2ng/ml;516-4 128ng/ml;2 000-20 000ng/ml respectively.This validated method has good repeatability, precision, recovery and stability.The results meet the requirements by regulation.Conclusion This method shortened the analysis time and improved efficiency.It assayed the three iridoid glycosides in Gardenia jasminoides Ellis sensitively and precisely.This method can be used for the quality control of Gardenia jasminoides Ellis.
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Objective To analyze of genetic diversity of Gardenia jasminoides and provide the information for the conservation and new variety breeding of G. jasminoides. Methods 12 ISSR primers and 9 primer combinations of SRAP were used to assess the polymorphisms, genetic diversity, and cluster analysis within 21 G. jasminoides materials from three populations. Results The results showed that 100 (80.00%) of 125 and 74 (92.50%) of 80 bands were polymorphic by ISSR and SRAP primers amplification, respectively. In ISSR results, the populations of species level of observed number of alleles (Na), effective number of alleles (Ne), Nei’s gene diversity (H), Shannon’s information index (I), total genetic diversity for species (Ht), and the mean heterozygosity with populations (Hs) were 1.461 3, 1.307 7, 0.173 1, 0.254 5, 0.239 1, and 0.173 1, respectively. Comparatively, for SRAP primers, the Na, Ne, H, I, Ht, and Hs value was 1.579 2, 1.342 1, 0.197 4, 0.295 9, 0.289 9, and 0.197 4, respectively. The coefficient of gene differentiation (Gst) for population was 0.276 2 and 0.318 9, which indicated that the within-population component accounted for 73.38% and 68.11%, respectively. The average mean of gene flow (Nm > 1) suggested that there certainly gene flow among the populations. UPGMA analysis showed that 21 samples were clustered into 2 branches, and a hierarchical dendrogram based on SRAP was more consistent with actual populations. Conclusion The gene diversity of G. jasminoides populations was high. The characteristics of genetic structure included genetic differentiation that occurs mainly within populations, which provided a reference for conservation and breeding of G. jasminoides germplasm.
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Gardenia jasminoides is a traditional Chinese herbal medicine, which is also the first batch of being used for both medicine and food issued by Ministry of Health of China. In recent years, G. jasminoides has been applied widely in medicine and health food, so the quality evaluation of G. jasminoides has become a key problem urgently needed to be solved in this industry. Based on the review of its chemical composition and pharmacological effects, combined with the definition of Q-marker, this study processed predictive analysis on Q-marker of G. jasminoides from several aspects at chemical composition, new clinical use, measurable composition, traditional medicine properties and efficacy, plasma composition, and storage time, which provides the basis for quality evaluation of G. jasminoides.
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Objective: To investigate the pharmacological mechanism of the crocin compounds from Gardenia jasminoides in Zhejiang Province by using network pharmacology. To provide a valuable research strategy for the rational use and in-depth research and development of G. jasminoides from Zhejiang. Methods: Our previous research results showed that the Zhejiang area of Gardenia crocin content and other areas have significant difference. Based on the results, the crocin compounds from G. jasminoides were used to predict the targets according to Pubchem, Uniprot, STITCH, SWISS, and TCMSP online databases. Cytoscape software was used to construct compound-target-disease network of the G. jasminoides crocin ingredients. The targets were analyzed by Gene ontology (GO) enrichment and KEGG pathway analysis using CTD online analysis platform to analyze main biological pathways for obtaining the deep mechanism of G. jasminoides in Zhejiang. Results: The crocin compounds from G. jasminoides in Zhejiang Province were obtained through previous work and network pharmacology screening, such as crocin-1 and crocin-2, and 18 corresponding targets were acted, such as FGF2, VEGFA, KDR, and FLT1. These targets could joint in pathways, such as GPCR, Rap1, and Ras signaling pathway. These ingredients are mainly used to treat 18 related diseases such as cardiovascular diseases, tumors and digestive system. Conclusion: The method based on system pharmacology could help to find the key targets of characteristic high-content chemical constituents of herb from different producing areas, signaling pathway and disease network of traditional Chinese medicine (TCM), and provide useful information and data support for giving a further study on TCM resources in different regions of China.
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Objective: To optimize the processing technology of Gardenia jasminoides carbon and validate the process with pharmacodynamics research. Methods: The pyrolysis characteristics of different active components in G. jasminoides were analyzed by thermal analysis technology, and the optimum processing temperature range of G. jasminoides carbon was obtained; Taking the tannin content in G. jasminoides carbon as the index, two factors of stir-frying temperature and stir-frying time was chosen to optimize the processing technology of G. jasminoides carbon by response surface methodology, and the processing technology of G. jasminoides carbon was verified by pharmacodynamics experiment (hemostasis test). Results: The optimum processing temperature range of G. jasminoides carbon was 290.3-387 ℃, response surface methodology was used to optimize the processing technology of G. jasminoides carbon: The processing temperature was 330 ℃, the processing time was 5.91 min, and the tannin content was 3.120 mg/g; Compared with the blank group, the new method group and the traditional group could significantly shorten the clotting time of mice (P < 0.01), raw product group can significantly shorten the clotting time of mice (P < 0.05), the new method group can significantly shorten APTT in mice (P < 0.05), there was no significant difference in PT and TT in mice. Conclusion: The processing technology of G. jasminoides carbon was optimized by thermal analysis technology and response surface methodology, and the results were verified by pharmacodynamics experiments. The method can provide a reference for improving the processing technology of Chinese materia medica and quantifying the fire parameters in the process of processing.
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To screen the active ingredients of Gardenia jasminoides and potential targets,and investigate the mechanisms against cholestasis based on network pharmacology technology. Twenty-one active components of G. jasminoides were retrieved and the target sites were screened by using Traditional Chinese Medicine Systems Pharmacology Database and Analysis Platform( TCMSP). Cytoscape3. 2. 1 was used to construct the component-target network. Two hundred and eight targets related to cholestasis were searched and screened through Dis Ge NET,KEGG and OMIM databases. The key targets of G. jasminoides components and cholestasis were integrated and screened,and the component-target-disease network was constructed with Cytoscape 3. 2. 1 software to screen out the core network whose freedom degree was greater than the average value. The Clue GO plug-in of Cytoscape 3. 2. 1 software was used to analyze the biological processes and pathway enrichment of G. jasminoides in regulation of cholestasis. GO biological process analysis revealed 17 biological processes,involving 3 signaling biological processes related to cholestasis,i.e. acute inflammatory response,positive regulation of reactive oxygen species metabolic process,and nitric oxide biosynthetic process. KEGG-KEEG-305 terms and REACTOME pathways analysis revealed 17 regulatory pathways,involving 4 signaling pathways related to cholestasis,i.e. metabolism of xenobiotics by cytochrome P450,nuclear receptor transcription pathway,GPVI-mediated activation cascade and platelet activation. It was found that aqueous extract of G. jasminoides could improve serum biochemical abnormalities in ANIT-induced cholestasis rats. Aqueous extract of G. jasminoides could decrease the protein and mRNA expression levels of ESR1 in liver tissues,and increase the protein and mRNA expression levels of PPARG,NOS2,F2 R,NOS3,and NR3 C1. To sum up,the possible mechanisms of G. jasminoides against cholestasis may be related with the above three processes and four pathways.
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Animais , Ratos , Colestase , Tratamento Farmacológico , Medicamentos de Ervas Chinesas , Farmacologia , Gardenia , Química , Medicina Tradicional Chinesa , Extratos Vegetais , Farmacologia , Transdução de SinaisRESUMO
Objective: To determine the content of index components in different parts of Gardenia jasminoides (pericarp, seeds, whiskers), study the fingerprint, and compare the contents and compositions differences of different parts of G. jasminoides, in order to provide the theoretical basis for different efficacies of G. jasminoides pericarp and seeds, explore the exploitation and utilization values of G. jasminoides whiskers, and avoid waste of gardenia medicinal resources. Method: The contents of geniposide and crocetin Ⅰ was were determined by HPLC, the content of total iridoid glycosides was determined by ultraviolet spectrophotometry, and three index components in different parts of G. jasminoides were analyzed. HPLC fingerprints of different parts of G. jasminoides were collected, the common pattern of HPLC fingerprints of different parts of G. jasminoides of different origins and with different processing methods was established, and the similarity evaluation software was used for data analysis; comparative analysis on fingerprints of different parts of G. jasminoides was conducted. Result: Content change of index components in G. jasminoides pericarp and seeds from Henan, Fujian and Jiangxi were the same. Content of geniposide:Fujian > Henan > Jiangxi, the contents of three components in G. jasminoides pericarp from Fujian were much higher than those from Henan and Jiangxi, the contents of crocetin Ⅰ and total iridoid glycosides:Fujian > Jiangxi > Henan, the contents of total iridoid glycosides from Fujian, Jiangxi were much higher than those from Henan. The order of three index components in G. jasminoides whiskers from different origins from high to low, the content of geniposide and crocetin Ⅰ was Fujian > Jiangxi and Henan, the content of total iridoid glycosides was Fujian > Jiangxi > Henan.In the same part, there were 22 common peaks in the fingerprints of G. jasminoides pericarp, except for S13-S15, the similarity of other samples were more than 0.9;the fingerprints of G. jasminoides seeds had 22 common peaks, except for S22-S30, the similarities of other samples were more than 0.9;the fingerprints of G. jasminoides whiskers had 16 common peaks, except for S7-S9, the similarities of other samples were more than 0.9.In different parts, the fingerprints of G. jasminoides whiskers were significant different from those of pericarp and seeds, the number of peaks in G. jasminoides whiskers reduced, the order of height of peaks 2, 3, 5 of G. jasminoides from high to low were whiskers > gardenia > seeds. There was not peak X in the seeds, the height of peak X of gardenia in whiskers was higher than that in pericarp, except for the peak 17, the height of all peaks in seeds were higher than that in whiskers. Conclusion: There are significant differences in the contents of index components in G. jasminoides pericarp and seeds. The content of total glycosides in gardenia is high, suggesting that it can be used to extract total iridoid glycosides. The fingerprints can reflect the content difference and species distribution of different parts of G. jasminoides, so as to provide theoretical support for the studies for pharmacodynamic material basis of G. jasminoides and the scientificity and rationality of the separate application of G. jasminoides pericarp and seeds.
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Objective@#To evaluate the toxicological safety of a compound Chinese medicine preparation of gardenia.@*Methods@#Eighty healthy SD rats with half males and half females were randomly divided into four groups. The low-,moderate- and high-dose group were given 1.00 g/kgbw,2.00 g/kgbw and 4.00 g/kgbw of the preparation,while the control group was given distilled water,by gavage for 30 days. The changes of diet,weight,hematological parameters and major organs of rats were observed,and the histopathological examination of the main organs was performed.@*Results@#The rats in the high-dose group reduced activities and their urine turned dark yellow or green,while the other rats showed no abnormality. No rats died during the experimental period. Compared with the control group,the weight,the total weight gain,the food utilization rate,the fasted weight of the rats in the high-dose group and the hemoglobin content of the female rats in the high-dose group were significantly decreased(P<0.05);the ratio of liver to body weight,the ratio of kidney to body weight,the serum creatinine levels of the rats in the high-dose group and the serum urea nitrogen levels of the male rats in the high-dose group were significantly higher(P<0.05). The livers and kidneys of the rats in high-dose group turned different degrees of dark green;the hepatic pigmentation,hepatocyte vacuolar degeneration,bile duct hyperplasia accompanied with inflammatory cell infiltration,renal pigmentation,renal tubular epithelial cellular swelling,and renal interstitial inflammatory cell infiltration were observed.@*Conclusion@#This preparation at a dose of 4.0 g/kgbw has hepatotoxicity and nephrotoxicity to rats. A dose of 2.0 g/kgbw has no harmful effect but less than 100 times of the possible human intake,the safety is not guaranteed.
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Aim: This study aims to screen the aqueous extract of Gardenia ternifolia fruit for toxicity in Wistar albino rats by determination of morality, Percentage of weight change, hematology, biochemistry and histopathology. Methodology: Twenty four male Wistar albino rats were divided into four groups, each of 6. Group 1 (control), group 2 and 3 (sub-chronic toxicity) and group 4 (acute toxicity). The aqueous extract was administered orally at a dose of 50 and 500 mg/ kg/ day -for four weeks- to group 2 and 3, respectively. Group 4 received 2000 mg/kg once, and group 1 was kept as a control. Clinical signs and mortality were observed daily. The weights of the animals were recorded weekly at week intervals till the end of the experiment. Blood samples were collected for hematology and biochemistry. Specimens of Liver and kidney were kept in 10% formalin for histopathology. Results: The results revealed that no clinical signs of toxicity or mortality were recorded during the experiment in all groups. The percentage of weight gain was lowest in group 4 compared with group 1 (control). The hematology and biochemistry of group 1 and 2 were not affected. However, both were altered in group 4. White Blood Cells (WBC) were significantly (P<0.05) increased; Red Blood Cells (RBC), Hemoglobin (Hb) and Packed Cell Volume (PCV) were significantly (P<0.05) decreased. Total protein and albumin were significantly (P<0.05) decreased. Cholesterol, urea, creatinine, Alanin Transaminase (ALT), Asparate Transaminase (AST) and Alkaline phosphatase (ALP) were significantly (P<0.05) increased. But, bilirubin was not affected in all groups. Histopathological changes on liver and kidney correlated with the hematological and biochemical alterations. Conclusion: The aqueous extract of G. ternifolia fruit was safe and not lethal to rats at low doses; the highest dose altered the haematology, biochemistry and histology of the tested animals.