PEGylated niosomes-mediated drug delivery systems for Paeonol: preparation, pharmacokinetics studies and synergistic anti-tumor effects with 5-FU.

This work describes the preparation of a PEGylated niosomes-mediated drug delivery systems for Paeonol, thereby improving the bioavailability and chemical stability of Paeonol, prolonging its cellular uptake and enhancing its synergistic anti-cancer effects with 5-Fu. PEGylated niosomes, which are prepared from biocompatible nonionic surfactant of Spans 60 and cholesterol, and modified with PEG-SA. Pae-PEG-NISVs were evaluated in vitro and in vivo. The cytotoxicity of Pae-PEG-NISVs was investigated against HepG2 cells. Fluorescence microscope was used to detect the apoptotic morphological changes. Growth inhibition assays were carried out to investigate whether Pae-PEG-NISVs could enhance the antiproliferative effects of Pae co-treated with 5-FU on HepG2 cells. The optimized Pae-PEG-NISVs had mean diameters of approximately 166 nm and entrapment efficiency (EE) of 61.8%. Furthermore, the in vitro release study of Paeonol from PEGylated niosomes exhibited a relatively prolonged release profile for 12 h. Pharmacokinetic studies in rats after i.v. injection showed that Pae-PEG-NISVs had increased elimination half-lives (t1/2, 87.5 versus 17.0 min) and increased area under the concentration-time curve (AUC0-t, 38.0 versus 19.48 µg/ml*min) compared to Paeonol solution. Formulated Paeonol had superior cytotoxicity versus the free drug with IC50 values of 22.47 and 85.16 µg/mL at 24 h on HepG2 cells, respectively, and we found that low concentration of Pae-PEG-NISVs and 5-Fu in conjunction had obviously synergistic effect. Our results indicate that the PEG-NISVs system has the potential to serve as an efficient carrier for Paeonol by effectively solubilizing, stabilizing and delivering the drug to the cancer cells.

[Optimization of formulation of Fufang Danshen immediate release tablet by colligation score].

OBJECTIVE: To optimize the formulation of immediate release tablet. METHOD: The immediate release tablet was prepared by using dry granules. The preparation was optimized by using orthogonal design which took the flow property of granules, the hardness, the disintegrating time and the dissolution rate of the tablet as indices. RESULT: The optimized formulation contained 40% microcrystalline cellulose, 10% sodium carboxymethyl starch and 15% dextrin. The hardness disintegrating time and T50 of the tablet were 4.5 kg, 3 min, 5 min respectively. CONCLUSION: It is successful to prepare on immediate release tablet using the optimized formula above.

Layer-by-layer assembly of chitosan stabilized multilayered liposomes for paclitaxel delivery.

Paclitaxel (PTX) loaded multilayered liposomes were prepared using layer-by-layer assembly in an effort to improve the stabilization of the liposomal compositions for PTX delivery. Stearyl amine was used to provide positive charge to the PTX-liposomes, and subsequently coated with anionic polyacrylic acid (PAA) followed by cationic chitosan. Various process variables were optimized and the optimum formulation was found to have particle size of 215 ± 17 nm, zeta potential of +27.9 ± 3.4 mV and encapsulation efficiency of 70.93 ± 2.39%. The lyophilized chitosan-PAA-PTX-liposomes formulation was stable in simulated gastrointestinal fluids and at different environmental conditions (4 °C and 25 °C). In vitro drug release experiments demonstrated that chitosan-PAA-PTX-liposomes formulation exhibited obvious sustained release behaviors compared to PTX-liposomes. Furthermore, chitosan-PAA-PTX-liposomes formulation revealed enhanced PTX induced cytotoxicity in human cervical cancer cell culture experiments compared to PTX-liposomes. In conclusion, the approach presented herein will provide a promising solution for PTX delivery.