BACKGROUND: Coffee is one of the most consumed beverages in the world, coffee consumption has been growing in the United States over the past 20 years. Periodontitis is defined by the pathologic loss of the periodontal ligament and destruction of the connective tissue attachment and alveolar bone loss and is related to different systemic diseases and conditions. However, the causality has remained unclarified, thus we regarded discovering the causal relationship between coffee consumption and the liability to periodontitis as the objective of the study. METHODS: Coffee consumption was subdivided into binary coffee consumption and continuous coffee consumption to refine the study design. Genetic instruments were stretched from the MRC-IEU's (MRC Integrative Epidemiology Unit) output from the GWAS pipeline using phesant-derived variables based on the UK Biobank, the Gene-Lifestyle Interactions in Dental Endpoints (GLIDE) project, and the joint meta-analysis of a recent GWAS. The IVW (Inverse Variance Weighted) was regarded as the primary method to estimate the causality, a scatter plot revealed the intuitive result, and tests for stability were also carried out. RESULTS: An effect of continuous coffee consumption on the risk of periodontitis was found, with per SD of coffee consumed increases, the risk of periodontitis rises by 1.04% (Odds Ratio of IVW is 1.0104), while the effect of binary coffee consumption on periodontitis did not meet the requirement of indicating a strong causal association, neither were the reverse causality analyses. CONCLUSIONS: The study indicated the causality of continuous coffee consumption to the risk of periodontitis with a relatively small scale of effect estimate and no strong evidence for an effect of binary coffee-consuming behavior on periodontitis. There was also no intensive evidence suggesting reverse causality.
ObjectiveTo establish the determination for index components in benchmark samples of Erdongtang, and clarify the content and transfer rate rages of index components in 15 batches of benchmark samples, and to explore the quantity transfer of index components of decoction pieces to benchmark samples. MethodFifteen batches of benchmark samples were prepared, the contents of mangiferin, baicalin and glycyrrhizic acid were determined by high performance liquid chromatography (HPLC)-diode array detector (DAD), the mobile phase was acetonitrile (A)-0.1% formic acid aqueous solution (B) for gradient elution (0-10 min, 10%-17%A; 10-25 min, 17%-19%A; 25-28 min, 19%-25%A; 28-45 min, 25%-33%A; 45-46 min, 33%-45%A; 46-60 min, 45%-55%A), detection wavelength was set at 254 nm. Contents of timosaponin BⅡ and the sum of protoneodioscin and protodioscin were determined by HPLC-evaporative light scattering detector (ELSD), the mobile phase was acetonitrile (A)-water (B) for gradient elution (0-20 min, 24%A; 20-25 min, 24%-27%A; 25-33 min, 27%-28%A; 33-36 min, 28%-90%A; 36-41 min, 90%-24%A). ResultThe methodological verification of the established method was good, which could be used for determination of five index components in benchmark samples. The content ranges of mangiferin, baicalin, glycyrrhizic acid, timosaponin BⅡ, and the sum of protoneodioscin and protodioscin in 15 batches of benchmark samples of Erdongtang were 0.14%-0.23%, 2.40%-3.37%, 0.07%-0.44%, 0.43%-0.95%, and 0.15%-0.47%, the transfer rate ranges of them were 33.90%-52.15%, 84.46%-105.61%, 22.59%-93.86%, 38.07%-61.43%, and 53.28%-96.11%, respectively. ConclusionThe consistencies of transfer rate of mangiferin, baicalin, timosaponin BⅡ and the sum of protoneodioscin and protodioscin (except glycyrrhizic acid) between decoction pieces and benchmark samples of Erdongtang are good, indicates that the transfer rates of 4 index components are stable during the preparation process of benchmark samples, which can provide data support for research and development of the compound preparation of this formula.
Objective:There were 92 kinds of compound preparations containing Ophiopogonis Radix in the 2015 edition of Chinese Pharmacopoeia, but there was no effective method to identify these compound preparations. Because Ophiopogonis Radix and Liriopes Radix are similar in appearance, it is easy to be confused in application. The aim of this study was to set up a thin layer chromatography (TLC) to identify compound preparations containing Ophiopogonis Radix and distinguish Ophiopogonis Radix and Liriopes Radix in the forms of decoction pieces and standard decoction. Method:In this study, decoction pieces of Ophiopogonis Radix and Liriopes Radix were collected and separately prepared as standard decoction. TLC was used to qualitatively identify decoction pieces and standard decoction of Ophiopogonis Radix and Liriopes Radix, and compound preparations containing Ophiopogonis Radix. In the TLC, the lower solution of chloroform-methanol-water (65∶35∶10) was selected as the developing agent and 10% sulfuric acid ethanol solution as the chromogenic agent. Result:The resolution of this TLC was good. Decoction pieces, standard decoction and preparations of Ophiopogonis Radix had the same characteristic strips, which were two bright white fluorescent strips under ultraviolet lamp (365 nm). But these two characteristic strips were not existed in the TLC of decoction pieces and standard decoction of Liriopes Radix. The corresponding components of both of these two strips were identified as mixture containing saponins by LC-MSn, including ophiopogonin Ra, Tb, ophiopogonin D', borneol glycoside, ophiopogonin C and Liriope muscari baily saponins C. Conclusion:The established TLC method, which has significant advantages such as high specificity and sensitivity, can be applied to the characteristic identification of decoction pieces and standard decoction of Ophiopogonis Radix, the identification of compound preparations containing Ophiopogonis Radix, and the distinction of Ophiopogonis Radix and Liriopes Radix, thus serving as an effective method to qualitatively identify Ophiopogonis Radix and its compound preparations.
Objective:To establish the quality evaluation methods of Asparagi Radix decoction pieces and its standard decoction. Method:Ten batches of Asparagi Radix standard decoction were prepared. High performance liquid chromatography-evaporative light scattering detection method (HPLC-ELSD) was established for the determination of protodioscin and protoneodioscin in Asparagi Radix decoction pieces and its standard decoction, and the fingerprint detection of Asparagi Radix decoction pieces with acetonitrile-water as mobile phase for gradient elution. UHPLC-LTQ-Orbitrap-MS/MS was used to identify ten main common peaks in the fingerprint with acetonitrile-0.1% formic acid solution as mobile phase for gradient elution, electrospray ionization (ESI) and positive and negative ion mode scanning were employed, the detection range was m/z 100-1 400. Result:The total content of protodioscin and protoneodioscin in Asparagi Radix decoction pieces was 0.41%-0.72%, and their total content in Asparagi Radix standard decoction was 0.33%-0.59%, the transfer rate of these two components was 73.6%-98.3%. The dry extract yield of the standard decoction was 59.0%-73.0%, and its pH was 4.9-5.6. There were 10 common peaks in the fingerprint, and all of them were saponins, including protoneodioscin, protodioscin, aspacochioside A and its isomer, methyl protodioscin, asparagoside F, (25R)-26-O-β-D-glucopyranosyl-furostan-5, 20-diene-3β, 26-diol-3-O-[α-L-rhamnopyranosyl (1→2)]-[β-D-glucopyranosyl (1→4)-α-L-rhamnopyranosyl (1→4)]-β-D-glucopyranoside, 26-O-β-D-glucopyranosyl-furostan-20 (22)-ene-3β, 26-diol-3-O-[α-L-rhamnopyranosyl (1→2)]-[α-L-rhamnopyranosyl (1→4)]-β-D-glucopyranoside, pseudodiosgenin, aspacochioside C. Conclusion:In this paper, the quality evaluation methods of Asparagi Radix decoction pieces and its standard decoction are established, and these methods are stable and feasible, which can provide reference for the quality control of pharmaceutical preparations containing Asparagi Radix.
The quality evaluation method for standard decoction of Chinese herbal slices is the basis for the quality evaluation of granules and preparations of classical formula(decoction)of traditional Chinese medicine. This study aimed to establish a method for the determination of quercetin-3-O-glucuronic acid in Nelumbinis Folium(NF)and its standard decoction, so as to provide reference for the quality control of NF and its standard decoction. Fifteen batches of representative NF were collected to prepare standard decoction, and the parameters of dry extract rate, transfer rate of index component, and pH value were calculated. HPLC was used to establish the content determination method for quercetin-3-O-glucuronic acid in NF and its standard decoction. The concentration range of quercetin-3-O-glucuronic acid in the standard decoction of NF was 1.09-3.06 g·L~(-1), while the concentration range of nuciferine was 0.01-0.17 g·L~(-1). The average extraction rate of NF standard decoction was(14.4±2.6)%, the average transfer rate of quercetin-3-O-glucuronic acid was(70.7±18.6)%, and the average transfer rate of nuciferine was(9.6±5.4)%. Compared with Nuciferine, quercetin-3-O-glucuronic acid had a high content and stable transfer rate in standard decoction, and was recommended to be the quality control marker for NF and its standard decoction. This paper establishes a quality evaluation method for NF standard decoction, and can provide reference for the quality control of all preparations derived from NF and its decoction.
Chromatography, High Pressure Liquid , Drugs, Chinese Herbal/chemistry , Flowers/chemistry , Medicine, Chinese Traditional , Nelumbo/chemistry , Quality Control
The arrenotokous toxicity of triptolide was evaluated, and the rate of sperm abnormality, the changes of the lipid peroxide, the enzyme activity and the hormone in male rats were observed. With the negative and positive control group, the healthy rats were respectively given by gavage triptolide suspension at the dose of 0.025, 0.05, 0.1 mg x kg(-1) for 30 days. Then the rats were killed for the measurement of the indicators in testis and serum, as well as the study on the sperm abnormality. The results showed that the positive control group had significant difference, compared with the negative control group. The content of SOD, LDH, G-6-PD, Na+ -K+ -ATPase, Ca+ -Mg+ -ATPase decreased significantly in 0.05 mg x kg(-1) group, and reduced more obviously with exposure to the dose of 0.1 mg x kg(-1). The levels of GSH-Px and beta-G showed a significant decrease in the testis of rats only at the dose of 0.1 mg x kg(-1). Nevertheless, the MDA levels, the FSH levels and the LH levels showed no significant difference. The deformity rate of sperm increased significantly in 0.05 mg x kg(-1) group and 0.1 mg x kg(-1) group. The results indicated the triptolide had the effect of the lipid peroxidation to damage Spermatogenic cells, Sertolis cells and Leydig cells. At the same time, the triptolide interfered not only with the energy supply process of aerobic and anaerobic glycolysis,but also with the energy utilization in testis by affecting the activities of testis marker enzymes, and produced a damage chain of the male reproductive system
Animals , Male , Rats , Diterpenes , Toxicity , Drugs, Chinese Herbal , Toxicity , Epoxy Compounds , Toxicity , Lipid Peroxidation , Organ Size , Phenanthrenes , Toxicity , Rats, Wistar , Reproduction , Spermatozoa , Congenital Abnormalities , Metabolism , Testis , Metabolism , Tripterygium , Chemistry , Toxicity
