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Objective@#This study takes hydroxypropyl-β-cyclodextrin (HP-β-CD) as the inclusion materials to optimize the preparation technic of tea tree oil (TTO) and evaluate its pharmaceutical performance.@*Methods@#Take the production rate of HP-β-CD tea tree oil inclusion and entrapment rate as the evaluation index, taking the orthogonal test method to optimize the production technic of tea tree oil (HP-β-CD inclusion and using infrared (IR), differential thermal scanning (DSC) method to characterize the inclusion compound to analyze the stability of TTO-HP-β-CD.@*Results@#The best technic to produce HP-β-CD tea tree oil is as follow: the ratio of TTO and HP-β-CD should be equal to 1/10, at 40 ℃, within 1 h. The average drug loading shoud be 9.25% ± 3.25%. The IR, DSC characterization results showed that the characteristic peak of tea tree oil disappeared after the microspheres, which indicated the HP-β-CD encapsulated the tea tree oil with good compatibility. In 80 ℃ water bath, the TTO-HP-β-CD was stable with the retention rate 40% after 8 h, the retention rate was 4.32 times than that of the unwrapped tea tree oil.@*Conclusions@#The HP-β-CD tea tree oil obviously has higher rate of inclusion and stability. Therefore, it’s worth to promoting and being used in the pharmacy preparations and cosmetics field.
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Objective@#To set up a method to measure the content of baicaline, wogonoside, and paeonol in Jiedu-Zhixue Decoction extract and to measure their physico-chemical parameters.@*Methods@#By using HPLC analytical methods to measure the content of baicaline, wogonoside, and paeonol in Jiedu-Zhixue Decoction extract. The RP18 column was adopted, gradient eluted with mobile phase of acetonitrile-1% phosphoric acid water, flow rate was 1 ml/min, detection wavelength was 274 nm, and the column temperature was 30 ℃. The method quantitatively analyze the compound extracts of baicaline, wogonoside and paeonol were used.@*Results@#The method isrepeatable, stable with good recorey rates. The calibration curves of baicaline was in good linearity over the range of 0.191 2-1.147 2 μg. The calibration curves of wogonoside was in good linearity over the range of 0.041 5-0.207 4 μg. The calibration curves of paeonol was in good linearity over the range of 0.019 5-0.156 3 μg. There was no significant difference among the component of 3 different batches of Jiedu-Zhixue Decoction extract, and the pH value range was 5.240-5.753, relative density range was 0.846-0.889.@*Conclusions@#The method used in this stydy to measure the effective components of Jiedu-Zhixue Decoction extract was stable and feasible, which is suitable for quality control of Jiedu-Zhixue Decoction.
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Objective To optimize the extraction technology for Gegen-Shujin granules. Methods With yield of volatile oil as index, single factor tests were used to investigate effects of water, soaking time and distillation time on extraction technology of volatile oil. The water amount, extraction time and numbers of extraction as factors, the contents of puerarin and total solid as indexes, orthogonal test was employed to optimize the extraction technology of Gegen-Shujin granules. Results The optimical extraction technology conditions were as follows: Cinnamomi Ramulus, cinnamomi ramulus, notopterygium, turmeric were extracted to get volatile oil with eight-folds amount water of herbs for 6 hours; while the other herbs were boiled with ten-folds amount water of herbs and extrancted for two times, 1.5 hours each time. Conclusions This extraction process is reasonable and practical, and can guarantee the quality of preparation.
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Objective To optimize the formulation and preparation technology of hydroxy safflower yellow A solid lipid nanoparticles and evaluate its quality. Metheds Hydroxy safflower yellow A solid lipid nanoparticles were prepared by the method of hot melt emulsification ultrasonic-low temperature using hydroxypropyl methylcellulose as a lipid material and glyceryl monostearate as an emulsifier. Using entrapment efficiency as indexes, the amount of hydroxypropyl methylcellulose, purified water, glyceryl monostearate, and Tween 80 aqueous solution (1%) as factors, orthogonal test was applied to optimize the formulation and preparation technology. Dialysis method was used to measure encapsulation efficiency. The morphology and uniformity of the nanoparticles were observed by transmission scanning electron microscopy. The particle size, polydispersion index and Zeta potential were determined by nano-particle size analyzer. And hydroxy safflower yellow A solid lipid nanoparticles sustained releasing characteristics was evaluated by the percentage of cumulative drug release. Results The optimal process of prepared hydroxy safflower yellow A solid lipid nanoparticles was 5 mg of hydroxypropyl methylcellulose, 0.2 ml of purified water, 100 mg of glyceryl monostearate, and 1.8 ml of Tween 80 aqueous solution (1%). The size of the prepared nanoparticles was uniform and spherical. And the average particle size were (99.85 ± 3.04) nm, polydispersion index were (0.390 ± 0.021), Zeta potential were (-27.63 ± 2.12) mV, and the encapsulation efficiency of the hydroxy safflower yellow A solid lipid nanoparticles were (63.35 ± 2.65)%. The release rate of the nanoparticles was (44.35 ± 0.49)%. Conclusions The prepared hydroxy safflower yellow A solid lipid nanoparticles have good uniformity and good sustained release properties.
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Objective@#To optimize the extraction technology for Gegen-Shujin granules.@*Methods@#With yield of volatile oil as index, single factor tests were used to investigate effects of water, soaking time and distillation time on extraction technology of volatile oil. The water amount, extraction time and numbers of extraction as factors, the contents of puerarin and total solid as indexes, orthogonal test was employed to optimize the extraction technology of Gegen-Shujin granules.@*Results@#The optimical extraction technology conditions were as follows: Cinnamomi Ramulus, cinnamomi ramulus, notopterygium, turmeric were extracted to get volatile oil with eight-folds amount water of herbs for 6 hours; while the other herbs were boiled with ten-folds amount water of herbs and extrancted for two times, 1.5 hours each time.@*Conclusions@#This extraction process is reasonable and practical, and can guarantee the quality of preparation.
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Objective@#To optimize the formulation and preparation technology of hydroxy safflower yellow A solid lipid nanoparticles and evaluate its quality.@*Metheds@#Hydroxy safflower yellow A solid lipid nanoparticles were prepared by the method of hot melt emulsification ultrasonic-low temperature using hydroxypropyl methylcellulose as a lipid material and glyceryl monostearate as an emulsifier. Using entrapment efficiency as indexes, the amount of hydroxypropyl methylcellulose, purified water, glyceryl monostearate, and Tween 80 aqueous solution (1%) as factors, orthogonal test was applied to optimize the formulation and preparation technology. Dialysis method was used to measure encapsulation efficiency. The morphology and uniformity of the nanoparticles were observed by transmission scanning electron microscopy. The particle size, polydispersion index and Zeta potential were determined by nano-particle size analyzer. And hydroxy safflower yellow A solid lipid nanoparticles sustained releasing characteristics was evaluated by the percentage of cumulative drug release.@*Results@#The optimal process of prepared hydroxy safflower yellow A solid lipid nanoparticles was 5 mg of hydroxypropyl methylcellulose, 0.2 ml of purified water, 100 mg of glyceryl monostearate, and 1.8 ml of Tween 80 aqueous solution (1%). The size of the prepared nanoparticles was uniform and spherical. And the average particle size were (99.85 ± 3.04) nm, polydispersion index were (0.390 ± 0.021), Zeta potential were (-27.63 ± 2.12) mV, and the encapsulation efficiency of the hydroxy safflower yellow A solid lipid nanoparticles were (63.35 ± 2.65)%. The release rate of the nanoparticles was (44.35 ± 0.49)%.@*Conclusions@#The prepared hydroxy safflower yellow A solid lipid nanoparticles have good uniformity and good sustained release properties.
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Objective To optimize the preparation technology of thermo-reversible Yinhuang opthalimic gel by the central composite design-response surface method.Methods The poloxamer 407 and poloxamer 188 were used as the investigation factors, and the evaluation index was the gel temperature. Central composite design-response surface method was used to evaluate the mathematic relation between the evaluation index and tow investigation indexes to identify the optimum prescription.Results According to the quadratic models, it was found that there was reliable quantitative relation between the evaluation index and two investigation indexes,among which the optimun dosage was 20% for P407, 1% for P188, 0.1% for hyaluronic acid, 0.01% for benzalkonium chloride, 0.02% for EDTA.Conclusions This method is reliable and feasible, whicn can realize the prescription optimization of the gel.