ABSTRACT
Salvianolic acids and tanshinones are main hydrophilic and lipophilic extracts from Salvia Miltiorrhiza with significant anti-pulmonary fibrosis effects. The aim of this study was to prepare a co-micronized salvianolic acids-tanshinones composite powder for inhalation using a planetary ball mill. The micronization process parameters were optimized by central composite design (CCD) and response surface methodology (RSM). Treatment time, rotation speed and the ball/sample weight ratio were selected as the independent variables, and the volume fraction of particle size in 1-5 μm was taken as the dependent variable. The powder properties were evaluated by scanning electron microscopy (SEM), laser diffraction and X-ray powder diffraction (XRPD). The powder flow and hygroscopicity were determined with repose angle, compressibility index and critical relative humidity(CRH). According to the results, the salvianolic acids-tanshinones composite powder produced in optimal conditions had a narrow and unimodal particle size distribution and a smaller D₅₀ of 2.33 μm. The volume fraction of particle size in 1-5 μm was 80.82%. The repose angle was (50.60±1.13) °, and the critical relative humidity is about 77%. After being micronized, the particle size significantly reduced, and the number of amorphous substances slightly increased, with no significant changes in powder flow and hygroscopicity. These findings indicate that the grinding method with a planetary ball mill can be used to co-micronize various components with different properties and prepare composite drug powders for dry powder inhalation.
ABSTRACT
The objective of the study was to prepare and evaluate the quality of curcumin-piperinedual drug loaded self-microemulsifying drug delivery system(Cur-PIP-SMEDDS). Simplex lattice design was constructed using optimal oil phase, surfactant and co-surfactant concentration as independent variables, and the curcumin and piperine were used as model drugs to optimize Cur-PIP-SMEDDS formulation. In the present study, the drug loadings of curcumin and piperine, mean particle size of Cur-PIP-SMEDDS were made as indicators, and the experiment design, model building and response surface analysis were established using Design Expert 8. 06 software to optimize and verify the composition of SMEDDS formulation. The quality of Cur-PIP-SMEDDS was evaluated by observing the appearance status, transmission electron microscope micrographs and determining particle diameter, electric potential, drug entrapment efficiency and drug loading of it. As a result, the optimal formulation of SMEDDS was CapryoL 90-Cremophor RH40-TranscutoL HP (10:60:30). The appearance of Cur-PIP-SMEDDS remained clarified and transparent, and the microemulsion droplets appeared spherical without aggregation with uniform particle size distribution. The mean size of microemulsion droplet formed from Cur-PIP-SMEDDS was 15.33 nm, the drug loading of SMEDDS for Cur and PIP were 40.90 mg · g(-1) and 0.97 mg · g(-1), respectively, the drug entrapment efficiency were 94.98% and 90.96%, respectively. The results show that Cur-PIP-SMEDDS can increase the solubility and stability of curcumin significantly, in the expectation of enhancing the bioavailability of it. Taken together, these findings can provide the reference to a preferable choice of the Cur formulation and contribute to therapeutic application in clinical research.