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ObjectiveTo analyze changes of the chemical composition in Euodiae Fructus before and after processing with Coptidis Rhizoma decoction, so as to provide scientific basis for elucidating the processing mechanism of this decoction pieces. MethodUltra-performance liquid chromatography-quadrupole-time-of-flight mass spectrometry (UPLC-Q-TOF/MS) was performed on a Titank C18 column (2.1 mm×100 mm, 1.8 μm), the mobile phase was 0.1% formic acid aqueous solution-acetonitrile for gradient elution, the column temperature was set at 40 ℃, the flow rate was 0.25 mL·min-1. Electrospray ionization (ESI) was used to scan in positive and negative ion modes, and the scanning range was m/z 50-1 250. The chemical constituents in Euodiae Fructus were identified before and after processing by reference substance comparison, database matching and literature reference, and MarkerView™ 1.2.1 software was used to normalize the obtained data, SIMCA-P 14.1 software was employed to perform principal component analysis (PCA) and orthogonal partial least squares-discriminant analysis (OPLS-DA) on MS data of raw and processed products to screen the differential components before and after processing. ResultA total of 50 compounds were identified, including 48 kinds of stir-fried products with Coptidis Rhizoma decoction and 44 kinds of raw products. After processing, six compounds were added, including danshensu, noroxyhydrastinine, oxyberberine, 13-methylberberrubine, protopine and canadine. However, two kinds of compounds, including (S)-7-hydroxysecorutaecarpine and wuchuyuamide Ⅱ, were not detected after processing. In general, after processing, the overall contents of phenolic acids and flavonoids decreased significantly, the overall content of limonoids increased, and the overall content of alkaloids did not decrease insignificantly. The results of PCA and OPLS-DA showed that there were significant differences in the composition and content of the chemical components of Euodiae Fructus before and after processing, and a total of 12 variables such as quercetin, dihydrorutaecarpine and dehydroevodiamine were obtained by screening. ConclusionEuodiae Fructus stir-fried with Coptidis Rhizoma decoction mainly contains phenolic acids, flavonoids, limonoids and alkaloids. The composition and content of the chemical components have some changes before and after processing. The addition of processing excipients and hot water immersion are the main reasons for the difference, which can provide experimental basis for interpretation of the processing mechanism of this characteristic processed products of Euodiae Fructus.
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ObjectiveBy comparing the composition and content changes of the volatile components in Atractylodis Rhizoma before and after processing with rice-washed water, the effect of rice-washed water processing on volatile components in Atractylodis Rhizoma was investigated. MethodHeadspace-gas chromatography-mass spectrometry (HS-GC-MS) was used to detect the volatile components in rhizomes of Atractylodes chinensis and A. lancea, and their processed products of rice-washed water. Chromatographic conditions were programmed temperature (starting temperature of 50 ℃ for 2 min, rising to 120 ℃ with the speed of 10 ℃·min-1, then rising to 170 ℃ at 2.5 ℃·min-1, and rising to 240 ℃ at 10 ℃·min-1 for 3 min), the inlet temperature was 280 ℃, the split ratio was 10∶1, and the solvent delay time was 3 min. The conditions of mass spectrometry were electron bombardment ionization (EI) with ionization temperature at 230 ℃ and detection range of m/z 20-650. Then the relative content of each component was determined by the peak area normalization method. SIMCA 14.1 software was used to perform unsupervised principal component analysis (PCA) and supervised orthogonal partial least squares-discriminant analysis (OPLS-DA) on each sample data, the differential components of Atractylodis Rhizoma and its processed products were screened by the principle of variable importance in the projection (VIP) value>1. ResultA total of 60 components were identified, among which 40 were rhizomes of A. chinensis and 38 were its processed products, 46 were rhizomes of A. lancea and 47 were its processed products. PCA and OPLS-DA showed that the 4 kinds of Atractylodis Rhizoma samples were clustered into one category respectively, indicating that the volatile components of the two kinds of Atractylodis Rhizoma were significantly changed after processing with rice-washed water, and there were also significant differences in the volatile components of rhizomes of A. lancea and A. chinensis. The compound composition of Atractylodis Rhizoma and its processed products was basically the same, but the content of the compounds was significantly different. The differential components were mainly concentrated in monoterpenoids and sesquiterpenoids, and the content of monoterpenoids mostly showed a decreasing trend. ConclusionAfter processing with rice-washed water, the contents of volatile components in rhizomes of A. lancea and A. chinensis are significantly changed, and pinene, 3-carene, p-cymene, ocimene, terpinolene, atractylon, acetic acid and furfural can be used as difference markers before and after processing.
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ObjectiveTo identify the chemical constituents of Alismatis Rhizoma before and after processing with salt-water by ultra-high performance liquid chromatography-quadrupole-time-of-flight mass spectrometry (UPLC-Q-TOF-MS), and to investigate the changes of terpenoids in Alismatis Rhizoma before and after processing with salt-water. MethodUPLC-Q-TOF-MS was used to detect with 0.1% formic acid aqueous solution (A)-acetonitrile (B)as mobile phase for gradient elution (0-0.01 min, 20%B; 0.01-5 min, 20%-40%B; 5-40 min, 40%-95%B; 40-42 min, 95%B; 42-42.1 min, 95%-20%B; 42.1-45 min, 20%B), electrospray ionization (ESI) was selected for collection and detection in positive ion mode with the scanning range of m/z 100-1 250 and ion source temperature at 500 ℃. The data were analyzed by PeakView 1.2.0.3, the components were identified according to the primary and secondary MS data, and combined with the reference substance and literature. After normalized treatment by MarkerView 1.2.1, the MS data were analyzed by principal component analysis (PCA) and orthogonal partial least squares-discriminant analysis (OPLS-DA), and then the differential components before and after processing were screened. The content changes of differential components were analyzed according to the relative peak area. ResultA total of 30 components were identified under positive ion mode, including 28 prototerpene triterpenes and 2 sesquiterpenes. The results of PCA and OPLS-DA showed that there were significant differences in components from Alismatis Rhizoma before and after processing with salt-water, and 10 differential components (alisol B 23-acetate, alisol I, alismol, 11-deoxy-alisol B 23-acetate, alisol B, alisol C, 11-deoxy-alisol B, alisol G, 11-deoxy-alisol C and alisol A) were screened, and the contents of alisol G and alisol A decreased significantly after processing. ConclusionUPLC-Q-TOF-MS can comprehensively and accurately identify the chemical constituents in raw and salt-processed products of Alismatis Rhizoma. It takes a great difference in the contents of chemical constituents before and after processing, and the difference of substituents is the main reason for this differences, which can provide reference for determining the material basis of efficacy changes of Alismatis Rhizoma before and after processing with salt-water.
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ObjectiveTo identify the chemical constituents of Alismatis Rhizoma before and after processing with salt-water by ultra-high performance liquid chromatography-quadrupole-time-of-flight mass spectrometry (UPLC-Q-TOF-MS), and to investigate the changes of terpenoids in Alismatis Rhizoma before and after processing with salt-water. MethodUPLC-Q-TOF-MS was used to detect with 0.1% formic acid aqueous solution (A)-acetonitrile (B)as mobile phase for gradient elution (0-0.01 min, 20%B; 0.01-5 min, 20%-40%B; 5-40 min, 40%-95%B; 40-42 min, 95%B; 42-42.1 min, 95%-20%B; 42.1-45 min, 20%B), electrospray ionization (ESI) was selected for collection and detection in positive ion mode with the scanning range of m/z 100-1 250 and ion source temperature at 500 ℃. The data were analyzed by PeakView 1.2.0.3, the components were identified according to the primary and secondary MS data, and combined with the reference substance and literature. After normalized treatment by MarkerView 1.2.1, the MS data were analyzed by principal component analysis (PCA) and orthogonal partial least squares-discriminant analysis (OPLS-DA), and then the differential components before and after processing were screened. The content changes of differential components were analyzed according to the relative peak area. ResultA total of 30 components were identified under positive ion mode, including 28 prototerpene triterpenes and 2 sesquiterpenes. The results of PCA and OPLS-DA showed that there were significant differences in components from Alismatis Rhizoma before and after processing with salt-water, and 10 differential components (alisol B 23-acetate, alisol I, alismol, 11-deoxy-alisol B 23-acetate, alisol B, alisol C, 11-deoxy-alisol B, alisol G, 11-deoxy-alisol C and alisol A) were screened, and the contents of alisol G and alisol A decreased significantly after processing. ConclusionUPLC-Q-TOF-MS can comprehensively and accurately identify the chemical constituents in raw and salt-processed products of Alismatis Rhizoma. It takes a great difference in the contents of chemical constituents before and after processing, and the difference of substituents is the main reason for this differences, which can provide reference for determining the material basis of efficacy changes of Alismatis Rhizoma before and after processing with salt-water.
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ObjectiveBy comparing the composition and content changes of the volatile components in Atractylodis Rhizoma before and after processing with rice-washed water, the effect of rice-washed water processing on volatile components in Atractylodis Rhizoma was investigated. MethodHeadspace-gas chromatography-mass spectrometry (HS-GC-MS) was used to detect the volatile components in rhizomes of Atractylodes chinensis and A. lancea, and their processed products of rice-washed water. Chromatographic conditions were programmed temperature (starting temperature of 50 ℃ for 2 min, rising to 120 ℃ with the speed of 10 ℃·min-1, then rising to 170 ℃ at 2.5 ℃·min-1, and rising to 240 ℃ at 10 ℃·min-1 for 3 min), the inlet temperature was 280 ℃, the split ratio was 10∶1, and the solvent delay time was 3 min. The conditions of mass spectrometry were electron bombardment ionization (EI) with ionization temperature at 230 ℃ and detection range of m/z 20-650. Then the relative content of each component was determined by the peak area normalization method. SIMCA 14.1 software was used to perform unsupervised principal component analysis (PCA) and supervised orthogonal partial least squares-discriminant analysis (OPLS-DA) on each sample data, the differential components of Atractylodis Rhizoma and its processed products were screened by the principle of variable importance in the projection (VIP) value>1. ResultA total of 60 components were identified, among which 40 were rhizomes of A. chinensis and 38 were its processed products, 46 were rhizomes of A. lancea and 47 were its processed products. PCA and OPLS-DA showed that the 4 kinds of Atractylodis Rhizoma samples were clustered into one category respectively, indicating that the volatile components of the two kinds of Atractylodis Rhizoma were significantly changed after processing with rice-washed water, and there were also significant differences in the volatile components of rhizomes of A. lancea and A. chinensis. The compound composition of Atractylodis Rhizoma and its processed products was basically the same, but the content of the compounds was significantly different. The differential components were mainly concentrated in monoterpenoids and sesquiterpenoids, and the content of monoterpenoids mostly showed a decreasing trend. ConclusionAfter processing with rice-washed water, the contents of volatile components in rhizomes of A. lancea and A. chinensis are significantly changed, and pinene, 3-carene, p-cymene, ocimene, terpinolene, atractylon, acetic acid and furfural can be used as difference markers before and after processing.
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Chronic tonsillitis is a high frequency disease.Chronic tonsillitis is called "Chronic Ru e" in traditional Chinese medicine(TCM),In addition to oral medicine treatment,the effect of external treatment for chronic tonsillitis is more significant.This article summarizes the clinical research progress of TCM external therapy in the treatment of chronic tonsillitis in recent years.
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<p><b>OBJECTIVE</b>To probe the effect of sodium para-aminosalicylate (PAS-Na) on concentration of amino acid neurotransmitters including glutamate (Glu), glutamine (Gln), glycine (Gly) and gamma-aminobutyric acid (GABA) in basal ganglia of subacute manganese (Mn)-exposed rats.</p><p><b>METHODS</b>Forty Sprague-Dawley male rats were randomly divided into the control, Mn-exposed, low dose PAS-Na (L-PAS) and high dose PAS-Na (H-PAS) groups. Rats in experiment groups received daily intraperitoneally injections of manganese chloride (MnCl₂ · 4H₂O, 15 mg/kg), while rats in control group received daily intraperitoneally injections of normal saline (NS), all at 5 days/week for 4 weeks. Then the rats in PAS groups followed by a daily subcutaneously dose of PAS-Na (100 and 200 mg/kg as the L-PAS and H-PAS groups, respectively) for another 3 and 6 weeks; while the rats in Mn-exposed and control group received NS. The concentrations of Glu, Gln, Gly and GABA in basal ganglia of rat was detected by the high performance liquid chromatography fluorescence detection technique.</p><p><b>RESULTS</b>After treating with PAS-Na for 3 weeks, the concentration of Gly in the Mn-exposed rats decreased to (0.165 ± 0.022) µmol/L (control = (0.271 ± 0.074) µmol/L, Mn vs control, t = 4.65, P < 0.05). After the further 6-week therapy with PAS-Na, the concentrations of Glu, Gln, Gly in the Mn-exposed rats were lower than those of the control rats ((0.942 ± 0.121), (0.377 ± 0.070), (0.142 ± 0.048), (1.590 ± 0.302), (0.563 ± 0.040), (0.247 ± 0.084) µmol/L; t = 7.72, 5.85, 4.30, P < 0.05); and also lower than in L-PAS and H-PAS groups, whose concentrations were separately (1.268 ± 0.124), (1.465 ± 0.196), (0.497 ± 0.050), (0.514 ± 0.103), (0.219 ± 0.034) µmol/L (L-PAS Glu and Gln vs Mn, t = 3.87, 3.77, P < 0.05; H-PAS Glu, Gln and Gly vs Mn, t = 6.78, 4.70, 3.42, P < 0.05).</p><p><b>CONCLUSION</b>The toxic effect of manganese on Glu, Gln and Gly in basal ganglia of Mn-exposed rats is obvious, especially appears earlier on Gly. The toxic effect still continues to develop when relieved from the exposure. PAS-Na may play an antagonism role in toxic effect of manganese on concentration of Glu, Gln and Gly in basal ganglia of Mn-exposed rats.</p>