Extraction of effective components of Psoralea corylifolia and efficacy evaluation in the treatment of vitiligo / 中国药房

OBJECTIVE To extract the effective components of Psoralea corylifolia and evaluate its efficacy in the treatment of vitiligo. METHODS The concentrations of psoralen， isopsoralen， neobavaisoflavone， corylin， psoralidin， corylifolinin， and bakuchiol in P. corylifolia extract were determined by ultra-performance liquid chromatography. Based on the analytic hierarchy process （AHP） and Plackett-Burman design， with the concentrations of the 7 components as evaluation indexes and the crushing degree， ethanol concentration， and soaking time as factors， the extraction process of P. corylifolia was optimized by Box-Behnken response surface methodology and the validation test was conducted. Zebrafish were divided into blank control group， positive control group （8-methoxypsoralen， 10.8 μg/mL）， and low-， medium-， and high-concentration groups of P. corylifolia extract （500， 1 000， 2 000 μg/mL）， with 6 fish in each group. The effects of P. corylifolia extract on the melanin production of zebrafish were studied by density analysis. RESULTS The best extraction process was P. corylifolia powder over 60 meshes and soaked in 80% ethanol for 72 hours. The average comprehensive score of three validation experiments was 98.27， with an RSD of 1.36%， and the relative error was 1.02% compared with the predicted value of the fitting equation （97.28）. Compared with the blank control group， the melanin pigmentation of zebrafish in the low-， medium-， and high-concentration groups of P. corylifolia extract was significantly increased （P＜0.01）. CONCLUSIONS The optimized extraction process of P. corylifolia is reasonable and feasible， and the obtained P. corylifolia extract can significantly promote the production of melanin in zebrafish.

Optimization of extraction process of prescription medicinal materials of compound Yangshe granules / 药学实践杂志

Objective Optimizing the extraction process of prescription medicinal materials of hospital preparation of compound Yangshe granules. Methods A high performance liquid chromatograph (HPLC) quantitative method was established for deacetyl asperulosidicacid methyl ester (DME) and ferulic acid (FC) of the active ingredient. Based on the content of DME, FC and the yield of extract, the extraction process of compound Yangshe granule extract was optimized using central composite design-response surface methodology. Results The established HPLC method of quantification of active components in compound Yangshe granules met the requirements of method validation. The optimal extraction process optimized by central composite design-response surface methodology were as follows: the weight of extraction solvent was 12 times of the medicinal slices, the alcohol concentration was 73% and the extraction time was 60 min. Conclusion In this study, the quantitative method of active components in compound Yangshe granule by HPLC has been successfully established, and the optimized extraction process is simple and easy to operate with good repeatability.

Optimization of extraction process of polysaccharide from Baihe dihuang decoction and study on its anti-anxiety and anti-depression efficacy / 中国药房

OBJECTIVE To optimize the extraction process and to primarily evaluate the anti-anxiety and anti-depression efficacy of polysaccharide from Baihe dihuang decoction. METHODS Based on Plackett-Burman experimental design， using the comprehensive score of yield and content of polysaccharide as indicators， with extraction time， water amount， alcohol precipitation concentration as factors， Box-Behnken response surface methodology was used to optimize the extraction process of polysaccharide from Baihe dihuang decoction； and the validation test was conducted. Forty ICR mice were divided into control group， venlafaxine group [positive control， 13.5 mg/（kg·d）]， Baihe dihuang polysaccharide high-dose and low-dose groups [5.28， 2.64 g/（kg·d），by raw material]， with 10 mice in each group （half male and half female）. Administration groups were given corresponding drug solution intragastrically， and control group was given water 10 mL/kg intragastrically， once a day， for 7 test， forced swimming test and tail suspension test were used to evaluate the effects of the extract prepared by the optimal process on the anxiety-like and depression-like behavior of mice； enzyme-linked immunosorbent assay was used to detect the effects of the extract on the levels of neurotransmitter in cerebral tissue of mice. RESULTS The optimal extraction process of Baihe dihuang decoction was： the water amount of 25 times， extract time of 1.5 hours， and alcohol precipitation concentration of 70%. In 3 times of validation test， the average yield and content of polysaccharide were 33.10% and 0.62 mg/mg， the relative deviations of which from the predicted values （36.14% and 0.65 mg/mg） were 8.40% and 4.62% respectively （RSD＜2%， n＝3）. The polysaccharide extract of Baihe dihuang decoction could effectively increase the percentages of open-arms entry， the percentages of open-arms time， the total distance of voluntary activities and the activity distance in central area， and significantly shortened the immobility time of forced swimming test and tail suspension test （P＜0.05 or P＜0.01）. The polysaccharide extract could significantly increase the levels of 5-hydroxytryptamine， norepinephrine （except for the Baihe dihuang polysaccharide low-dose group） and gamma-aminobutyric acid in cerebral tissue of mice， while significantly decrease the levels of glutamic acid （except for the Baihe dihuang polysaccharide low-dose group） （P＜0.05 or P＜ 0.01）. CONCLUSIONS The optimized extraction process of polysaccharide from Baihe dihuang decoction is stable and feasible， and the obtained polysaccharide extract has obvious anti-anxiety and anti-depression effect in vivo.

Optimization of water extraction process of Maxing kechuan granules / 中国药房

OBJECTIVE To optimize the water extraction process of Maxing kechuan granules. METHODS With the contents of ephedrine hydrochloride， bergenin， prim-O-glucosylcimifugin， 5-O-methylvisamin， naringin and hesperidin and the rate of extraction as the evaluation indexes， the weight was determined by the analytic hierarchy process（APH）-entropy weight method， and the comprehensive score was calculated as the response value. Based on the single-factor test， the Box-Behnken response surface method was used to investigate the factors， and the best water extraction process of Maxing kechuan granules was optimized； process validation was also carried out. RESULTS The best water extraction process of Maxing kechuan granules optimized was as follows： soaking for 40 minutes， adding 8 times water， and extracting for 180 minutes. After three validation tests， the comprehensive score was 94.82 （RSD＝0.96%， n＝3）， which had a small difference from the predicted value of 94.64. CONCLUSIONS The water extraction process of Maxing kechuan granules is stable and reliable， which can provide a reference for the development of the preparation.

Optimization of ethanol reflux extraction process of Ziziphi Spinosae Semen- Schisandrae Sphenantherae Fructus based on network pharmacology combined with response surface methodology / 中国中药杂志

The present study optimized the ethanol extraction process of Ziziphi Spinosae Semen-Schisandrae Sphenantherae Fructus drug pair by network pharmacology and Box-Behnken method. Network pharmacology and molecular docking were used to screen out and verify the potential active components of Ziziphi Spinosae Semen-Schisandrae Sphenantherae Fructus, and the process evaluation indexes were determined in light of the components of the content determination under Ziziphi Spinosae Semen and Schisandrae Sphenantherae Fructus in the Chinese Pharmacopoeia(2020 edition). The analytic hierarchy process(AHP) was used to determine the weight coefficient of each component, and the comprehensive score was calculated as the process evaluation index. The ethanol extraction process of Ziziphi Spinosae Semen-Schisandrae Sphenantherae Fructus was optimized by the Box-Behnken method. The core components of the Ziziphi Spinosae Semen-Schisandrae Sphenantherae Fructus drug pair were screened out as spinosin, jujuboside A, jujuboside B, schisandrin, schisandrol, schisandrin A, and schisandrin B. The optimal extraction conditions obtained by using the Box-Behnken method were listed below: extraction time of 90 min, ethanol volume fraction of 85%, and two times of extraction. Through network pharmacology and molecular docking, the process evaluation indexes were determined, and the optimized process was stable, which could provide an experimental basis for the production of preparations containing Ziziphi Spinosae Semen-Schisandrae Sphenantherae Fructus.

Optimization of extraction process of Chuanxiong Rhizoma-Gastrodiae Rhizoma based on network pharmacology and multi-index orthogonal test / 中国中药杂志

To optimize the extraction process of Chuanxiong Rhizoma-Gastrodiae Rhizoma herb pair by network pharmacology combined with analytic hierarchy process(AHP)-entropy weight method and multi-index orthogonal test. The potential active components and targets of Chuanxiong Rhizoma-Gastrodiae Rhizoma were screened by network pharmacology and molecular docking, and the process evaluation indexes were determined with reference to the Chinese Pharmacopoeia(2020 edition). The core components of Chuanxiong Rhizoma-Gastrodiae Rhizoma were determined as gastrodin, parishin B, parishin C, parishin E, ferulic acid, and 3-butylphthalide. With the extraction volume of each indicator and yield of dry extract as comprehensive evaluation indicators, the extraction conditions were optimized by the AHP-entropy weight method and orthogonal test as the ethanol volume of 50%, the solid-liquid ratio of 1∶8(g·mL~(-1)), extraction for three times, and 1.5 h each time. Through network pharmacology and molecular docking, the process evaluation index was determined, and the optimized process was stable and reproducible for the extraction of Chuanxiong Rhizoma-Gastrodiae Rhizoma herb pair, which could provide reference for in-depth research.

Optimization of microwave-assisted extraction of green tea polyphenols by response surface methodology / 药学实践杂志

Objective To optimize the microwave-assisted extraction process of green tea polyphenols. Methods The extraction yield of tea polyphenols was figured up by building the standard curve of gallic acid and examining the concentration of tea polyphenols in green tea extract with the introduction of a correction factor. The effects of four single factor levels of microwave extraction time, microwave output power, liquid-to-material yield, and ethanol volume fraction on the extraction yield of tea polyphenols were primarily studied in this experiment. The response surface was applied to further optimize the extraction process of green tea polyphenols after exploring the appropriate range of four single factor levels. Results The optimal extraction process was as follows: extraction time 37 s, microwave output power 350 w, material - liquid yield 1∶45 (g/ml), ethanol volume fraction 55%, and the actual extraction yield of tea polyphenols was 25.65%, which was not much different from the theoretical value. Conclusion The microwave-assisted green tea polyphenol extraction process optimized by response surface methodology is time-saving and practicable, and the extraction yield is high.

Comparison of the fingerprint and multi-component contents between Liuwei dihuang powder decoction pieces and traditional decoction pieces with different decocting time / 中国药房

OBJECTIVE To compare the change law of multi-components in the extraction process between Liuwei dihuang powder decoction pieces and traditional decoction pieces （hereinafter referred to as powder decoction pieces and traditional decoction pieces）， and to provide scientific basis for the modern technology research of Liuwei dihuang formula. METHODS Taking powder decoction pieces and traditional decoction pieces as samples， the samples were taken when soaking for 60 min， at 0， 5， 10， 15， 20， 25， 30， 40， 50， 60 min of the first decocting and at 5， 10， 20， 30， 40 min of the second decocting， respectively. HPLC method was used to establish the fingerprints of 2 kinds of decoction pieces with different decocting time. The similarity evaluation and peak identification were performed. The contents of 8 components including 5-hydroxyfurfural， catechin， monoglycoside， loganin， swertin glycoside， dihydroquercetin， paeonol and benzoyl paeoniflorin were all determined. RESULTS With different decocting time， the similarties between 2 kinds of decoction pieces and their respective control fingerprints R were all greater than 0.98. In the fingerprints of traditional decoction pieces， five chromatographic peaks were identified， namely， 5- hydroxyfurfural， monetin， swertiaoside， dihydroquercetin and paeonol； in the fingerprints of powder decoction pieces， six chromatographic peaks were identified， namely， 5-hydroxyfurfural， monoglycoside， swertiamarin， dihydroquercetin， paeonol and benzoyl paeoniflorin. The results of content determination showed that in the first 5 minutes of the first decocting， the decocting rate of almost all the ingredients in the powder decoction pieces was faster than that of the traditional decoction pieces； after 40 min， the contents of other active ingredients were lower than those of traditional decoction pieces except for 5-hydroxyfurfural and paeonol. In the process of second decocting， except for paeonol and loganin， the contents of other ingredients in powder decoction pieces were higher than that in traditional decoction pieces； catechin was completely decocted from the traditional decoction pieces in the first decocting， while it could still be detected in the powder decoction pieces in the second decocting. There was little difference in the total decocted amount of the 8 ingredients in the two decoction pieces. CONCLUSIONS The chemical composition of powder decoction pieces of Liuwei dihuang formula has no obvious advantages compared with traditional decoction pieces， and can not save the decocting time and the amount of medicinal materials.

Study on the application of model transfer technology in the extraction process of Xiao'er Xiaoji Zhike oral liquid / 药学学报

The modernization and development of traditional Chinese medicine has led to higher standards for the quality of traditional Chinese medicine products. The extraction process is a crucial component of traditional Chinese medicine production, and it directly impacts the final quality of the product. However, the currently relied upon methods for quality assurance of the extraction process, such as simple wet chemical analysis, have several limitations, including time consumption and labor intensity, and do not offer precise control of the extraction process. As a result, there is significant value in incorporating near-infrared spectroscopy (NIRS) in the production process of traditional Chinese medicine to improve the quality control of the final products. In this study, we focused on the extraction process of Xiao'er Xiaoji Zhike oral liquid (XXZOL), using near-infrared spectra collected by both a Fourier transform near-infrared spectrometer and a portable near-infrared spectrometer. We used the concentration of synephrine, a quality control index component specified by the pharmacopoeia, to achieve rapid and accurate detection in the extraction process. Moreover, we developed a model transfer method to facilitate the transfer of models between the two types of near-infrared spectrometers (analytical grade and portable), thus resolving the low resolution, poor performance, and insufficient prediction accuracy issues of portable instruments. Our findings enable the rapid screening and quality analysis of XXZOL onsite, which is significant for quality monitoring during the traditional Chinese medicine production process.

Optimization of extraction process and evaluation of the antibacterial and anti-inflammatory activity of blumeatin from Blumea balsamifera / 中国药房

OBJECTIVE To optimize the extraction process of blumeatin from Blumea balsamifera and to evaluate its antibacterial and anti-inflammatory activity. METHODS The content of blumeatin in the extract of B. balsamifera was determined by HPLC. On the basis of the single factor experiment， the extraction technology of blumeatin was optimized by the Box-Behnken response surface method with the volume fraction of ethanol， liquid-solid ratio and extraction time as the factors， using the yield of blumeatin as index. Microdilution method was used to determine the antibacterial activity of blumeatin against Streptococcus pyogenes， Staphylococcus aureus， Streptococcus agalactiae， Streptococcus mutans， Bacillus subtilis and Micrococcus luteus. The anti-inflammatory activity of blumeatin was evaluated by ear swelling test and capillary permeability test in mice. RESULTS The optimal extraction technology was as follows： ethanol concentration of 90%， liquid-material ratio of 15∶1， extraction time of 2 h at 80 ℃； the yield of blumeatin using this extraction process was 1.97 mg/g. The minimum inhibitory concentrations of blumeatin for S. pyogenes， S. aureus， S. agalactiae， S. mutans， B. subtilis and M. luteus were 50.00， 200.00， 400.00， 400.00， 800.00 and 1 600.00 μg/mL， respectively； the minimum bactericidal concentrations of blumeatin for S. pyogenes and S. aureus were 400.00 and 1 600.00 μg/mL， respectively. Blumeatin could significantly inhibit the ear swelling induced by xylene and capillary permeability induced by acetic acid in mice（P＜0.05 or P＜0.01）. CONCLUSIONS The optimized extraction technology of blumeatin is stable and feasible. The extracted blumeatin has a certain antibacterial effect against S. pyogenes and a good anti-inflammatory activity.

Optimization of extraction technology of total saponins from Trillium tschonoskii Rhizome by response surface method / 国际中医中药杂志

Objective:To optimize the ethanol reflux extraction process of total saponins in total saponins of Trillium tschonoskii Rhizome. Methods:On the basis of single factor tests, making the total extraction rate of three main compounds [paris saponin Ⅵ, paris saponin Ⅶ and pennogenin-3- O-α-L-rhamnopyranosyl-(1→4)-[O-α-L-rhamnopyranosyl (1→2)]- O-β-D-glucopyranoside (PRRG)] as the indicator, the optimal extraction parameter was selected with the main influencing factors: the ethanol concentration, solid-liquid ratio, and extraction time by the central composite design-response surface method.Results:The optimal extraction parameter for the ethanol extract of total saponins of Trillium tschonoskii Rhizome was as follows: ethanol concentration 69%, extraction time 1.9 h, and solid liquid ratio 1∶9.7. The binomial fitting complex correlation coefficient r = 0.966 1, and the deviation between the extracted predicted value and the actual value is 4.68%. Conclusion:The central composite design-response surface method is simple and reliable for the optimization of extraction process of total saponins of Trillium tschonoskii Rhizome.

Advances on Chemical Constituents of Essential Oils from Perillae Folium and Their Pharmacological Effect：A Review / 中国实验方剂学杂志

Perilla frutescens is a traditional medicinal and edible plant widely distributed in China and enjoys an extensive usage. P. frutescens contains multiple essential oils， which are composed of monoterpenes， sesquiterpenes， and their oxygen-containing derivatives. Compared with other parts of P. frutescens， Perillae Folium produce more oils， with volatile oils as the main constituents. There are many active substances in the volatile oils from Perillae Folium， mainly including perillaldehyde， perillaketone， perillaalcohol， D-limonene， β-caryophylene， etc. Such factors as germplasm， growth environment， extraction method， cultivation time， and harvest period all can trigger changes in volatile oil constituents and content from Perillae Folium. The volatile oils from Perillae Folium have diverse pharmacological effects like anti-oxidation， anti-bacteria， anti-inflammation， vasodilation， anti-tumor， and anti-depression， implying its high clinical application value. However， the chemical constituents in volatile oils from Perillae Folium are complex and unstable and their pharmacological activities are affected by many factors， so the safety and effectiveness of clinical medication fail to be guaranteed， which may has impeded the rational and effective use of these volatile oils. Many scholars in China and abroad have conducted a lot of research on the volatile oils from Perillae Folium， but there is currently no systematic and comprehensive research report on the chemical constituents of volatile oils from Perillae Folium and their pharmacological effects. This paper reviewed the relevant domestic and foreign literature， analyzed the development status of volatile oils from Perillae Folium， and summarized their extraction process， chemical constituents， and pharmacological actions， aiming to provide a reference for their further development， clinical application， and risk assessment.

Content determination and extraction process of macrocyclic polyphenols from Penthorum chinense Pursh / 药学实践杂志

Objective To establish an HPLC method for simultaneous assay of macrocyclic polyphenols from Penthorum chinense Pursh, pinocembrin-7-O-[4'', 6''-(S)-hexahydroxydiphenoyl]-β-D-glucose (PHG), pinocembrin-7-O-[3''-O-galloyl-4'', 6''-(S)-hexahydroxydiphenoyl]-β-D-glucose (PGHG) and pinocembrin dihydrochalcone-7-O-[3''-O-galloyl-4'', 6''-(S)-hexahydroxydiphenoyl]-β-D-glucoside or thonningianin A (THA), and optimize the extraction process. Methods The total extraction rate of PHG, PGHG, THA was used as an investigated index to analyze the extracts from Penthorum chinense Pursh. Orthogonal design was applied to evaluate solvent amount, extraction time, solvent concentration and extraction times as the influencing factors for the optimal extraction process of macrocyclic polyphenols from Penthorum chinense Pursh. Results When this content assay method was adopted, there were good linear relationships for PHG, PGHG, THA in the linear range. The recoveries were between 100.90% to 102.04% with the RSDs below 1.5%. The optimal extraction process was involved in cutting Penthorum chinense Pursh into 3-5 cm, adding 10 times 80% ethanol aqueous solution by volume and refluxing 2 hours twice. The extraction rate of macrocyclic polyphenols was above 90% with this process. Conclusion This assay method is accurate, stable, and repeatable. The optimized extraction process is stable and feasible for further development and utilization.

Study on preparation extraction process of Linggui Zhugan Decoction / 中国中药杂志

To verify the appropriate preparation process of extracts for the solid substance benchmark of Linggui Zhugan Decoction. The extracts were prepared by different preparation processes, namely the traditional process(process 1), the extract combined with volatile oil separated from traditional process extract liquid(process 2), the modern secondary reflux extraction process(process 3) and the process that volatile oil was extracted first, then prepared according to the traditional process, and combined with extract(process 4); based on the characteristic spectrum, index components of cinnamaldehyde, glycyrrhizin, ammonium glycyrrhizinate, cinnamic acid, and the dry extract rate of process 1, the differences and similarities of four extracts were compared. The results showed that the similarity of the characteristic spectrum of process 2, process 4 and process 1 were all greater than 0.97, while there was no significant difference for the content of 4 quality control components and dry extract rate; the similarity of the characteristic spectrum of process 3 and process 1 was 0.91, the absolute peak area of 13 out of 21 peaks and the relative peak area of 7 peaks increased significantly, and the content of 3 out of 4 quality control components and dry extract rate also significantly increased. In conclusion, the material standards of extracts by the process 2 and 4 are consistent with that of the traditional process, so the two processes are suitable.

Critical quality attribute assessment of big brand traditional Chinese medicine: online NIR quality control research on boiling time during extraction process / 中国中药杂志

Assessment of the status property(boiling time) is a challenge for the quality control of extraction process in pharmaceutical enterprises. In this study, the pilot extraction process of Phellodendron chinense was used as the research carrier to develop an online near-infrared(NIR) quality control method based on the status property(boiling time). First, the NIR spectra of P. chinense were collected during the two pilot-scale extraction processes, and the status property(boiling time) was assessed by observing the state of bubbles in the extraction tank using a transparent window during the extraction process, which was then used as a reference standard. Based on the moving block standard deviation(MBSD) algorithm, the assessment model using online NIR spectra for boiling time during extraction process was established. In addition, the model was optimized as follows: standard normal variable(SNV) for spectral pretreatment, modeling band of 800-2 200 nm, and window size of 4. The results showed that, with 0.002 0 as the MBSD model threshold, the boiling time can be accurately assessed using online NIR spectra during extraction process. Furthermore, the principal component analysis-moving block standard deviation(PCA-MBSD) model was developed by our group to reduce the influence of online NIR spectral noise and background signal on the model, and the number of principal components was optimized into 2 in the PCA-MBSD model. The results showed that, with 0.000 075 as the PCA-MBSD model threshold, the boiling time can be accurately assessed using online NIR spectra during extraction process, with improved reliability. This study can provide a assessment method for boiling time during extraction process using online NIR spectra, which can replace the empirical judgment in manual observation, and realize the digitalization of the extraction process for big brand traditional Chinese medicine.

Judgment on decocting endpoint of decoction in "Treatise on Febrile Diseases" and "Treatise on Differentiation and Treatment of Epidemic Febrile Disease" / 中草药

The time of decocting plays an important role in ensuring the clinical efficacy of Chinese medicine decoction and the quality of traditional Chinese medicine, but from ancient times to the present, the judgment of the endpoint of Chinese medicine decoction has always been a technical problem. In this paper, the decocting time and the judgment methods in the Chinese medicine classics "Treatise on Febrile Diseases" and "Treatise on Differentiation and Treatment of Epidemic Febrile Disease" were analyzed. Certain laws of decocting time were found. It was demonstrated that the main factors affecting the decocting time were the disease, the efficacy of the prescriptions, the drug properties, and the characteristics of the medicine, etc. Combined with modern research results, the judgment method of the endpoint of traditional Chinese medicine decoction was expounded, hoping to seek a reasonable scientific basis for the boiling time of Chinese medicine decoction and the extraction process of modern Chinese medicine preparation, and provide a theoretical basis for ensuring the clinical efficacy of Chinese medicine decoction and the quality of Chinese medicine preparations.

Analysis and Identification of Sesquiterpenes in Alpinia oxzphylla Miq Based on UPLC-Q-Orbitrap HRMS / 中草药

Objective: To establish a rapid and accurate analytical method for the identification of complex system of traditional Chinese medicine, and to systematically clarify the chemical composition of sesquiterpenes in Alpinia oxyphylla. Method: On the basis of optimizing the extraction process of sesquiterpenes, the accurate molecular weight and secondary fragment ions information of unknown compounds were captured by ultra-high performance liquid chromatography-quadrupole/orbitrap high resolution mass spectrometry (UHPLC-Q-Orbitrap HRMS). Compared with the relative retention time and mass spectrometry data of the reference substance, combined with relevant references and databases, the sesquiterpene unknown compounds in the fruits of A. oxyphylla were accurately and rapidly characterized. Results: A total of 24 sesquiterpenes were identified and classified into four categories according to their skeleton structure, including nine eudesmane-type, six cadinane-type, eight eremophilane-type, and one oplopanone-type. Conclusion: In this study, the established analytical method was used to realize the rapid and accurate identification of sesquiterpenes in the fruits of A. oxyphylla, which provided a theoretical basis for the research on the pharmacodynamic substance basis and quality control of the fruits of A. oxyphylla.

Optimization of Extraction Process of Thymol and Carvacrol in Origanum vulgare by Box-Behnken Design-Response Surface Methodology / 中国药学杂志

OBJECTIVE: To optimize the extraction process of thymol and carvacrol in Origanum vulgare by Box-Behnken design-response surface methodology. METHODS: On the basis of single factor experiment, taking the sum of extraction rates of thymol and carvicol as the evaluation index, Box-Behnken design was used to investigate the effects of ethanol concentration, liquid-solid ratio and medicinal powder on the extraction rate. RESULTS: The optimal extraction parameters were as follows: ethanol concentration was 80%, liquid to solid ratio was 13∶1 (mL/g), medicinal powder passing through 40 meshes was used, and the highest extraction rate was 694.80 μg•g-1, with a small deviation from the predicted value. CONCLUSION: The optimal extraction method is simple, with low cost and good predictivity, and it can provide experimental basis for further large-scale production of thymol and carvacrol in Origanum vulgare.

Optimal extraction of indirubin from Isatidis Folium based on Plackett-Burman design combined with central composite design-response surface methodology / 中草药

Objective: To investigate the significance of each influencing factor and optimize the process of extracting indirubin from Isatidis Folium by Plackett-Burman design combined with central composite design-response surface methodology (CCD-RSM). Methods: Plackett-Burman experimental design was used to screen the main influencing factors, and CCD-RSM was used to optimize the extraction process of indirubin. With the concentration of ethanol, the ratio of material to liquid, and the extraction time as independent variables and the extraction amount of indirubin as dependent variable, the optimum extraction process of indirubin from Isatidis Folium was predicted and analyzed by multiple linear regression and binomial fitting models with independent and dependent variables and the three-dimensional surface graph. Results; The optimal extraction process of indirubin was as follows: ethanol concentration 62%, solvent/sample ratio of 26, and extraction time 9 min. Under these conditions, the maximal extraction rate of indirubin was 4.37 mg/g which was consistent with model predictions. Conclusion: The optimal process is simple and convenient for extracting indirubin from Isatidis Folium with high precision, reproducibility, and predictability.

Optimization of extraction process of Modified Yangyin Qingfei Decoction by Box-Behnken response surface methodology based on analytic hierarchy process / 中草药

Objective: To optimize the extraction process of Modified Yangyin Qingfei Decoction (MYQD). Methods: The effects of ethanol concentration, extraction time and extraction times on the optimization of extraction process of MYQD were investigated by multiple indicators comprehensive scoring and Box-Behnken response surface methodology. The content of verbascoside, chlorogenic acid, paeonol, and glycyrrhizic acid was simultaneously determined by HPLC, and the method of analytic hierarchy process was used to calculate the weight coefficient. Results: The optimum extraction process was as follow: using 69% ethanol for once extraction for 68 min. Conclusion: The optimum extraction process is simple and feasible, and the extraction efficiency of components is high, which can provide reference for the extraction process of MYQD.