Quercetin-containing self-assemble proliposome preparation and evaluation.

The purpose of this study was to develop a liquid self-assemble proliposome for quercetin oral delivery. This liquid proliposome was prepared by dissolving phospholipids, surfactants and drug in ethanol. There was only one step in the preparation process of this liquid self-assemble proliposome and no special devices were required. The mechanism about proliposome transformation was discussed. Quercetin proliposomes with different cremorphor RH40 concentrations (0%, 20%, 23%, 26%, 30%) were prepared. The particle size and polydispersity index decreased as cremorphor RH40 concentration increased. Meantime, the drug entrapped efficiency decreased slightly with an increase in cremorphor RH40 concentration. The in vitro drug release showed prolonged drug release in case of proliposome and the release of quercetin was slower when cremorphor RH40 concentration was higher. The absorption of quercetin and its in vivo bioavailability were significantly improved by proliposome, which was evidenced by the in situ intestinal absorption and pharmacokinetic study. Besides, the obtained quercetin proliposome was with good stability when stored at room temperature. In conclusion, quercetin liquid self-assemble proliposome was successfully prepared. It could transform into liposomal vesicle with satisfied particle size and polydispersity index instantly when cremorphor RH40 was added. Cremorphor RH40 concentration in the formulation should below 26% to get higher drug entrapped efficiency (>90%) and less irritation. The drug release was affected by the cremorphor RH40 concentration and the required drug release could be obtained by adjusting cremorphor RH40 content. The enhanced bioavailability showed liquid self-assemble proliposome could be a promising vehicle for the oral delivery of quercetin.

A micelle-like structure of poloxamer-methotrexate conjugates as nanocarrier for methotrexate delivery.

The purpose of this study was to develop a novel featured and flexible methotrexate (MTX) formulation, in which MTX was physically entrapped and chemically conjugated in the same drug delivery system. A series of poloxamer-MTX (p-MTX) conjugates was synthesized, wherein MTX was grafted to poloxamer through an ester bond. p-MTX conjugates could self-assemble into micelle-like structures in aqueous environment and the MTX end was in the inner-core of micelles. Moreover, free MTX could be physically entrapped into p-MTX micelles hydrophobic core region to increase the total drug loading. Importantly, the resulting MTX-loaded p-MTX micelles showed a biphasic release of MTX, with a relative fast release of the entrapped MTX (about 6-7h) followed by a sustained release of the conjugated MTX. The pharmacokinetics study showed that the mean residence time (MRT) was extended in the case of MTX-loaded p-MTX micelles, indicating a delayed MTX elimination from the bloodstream and prolonged in vivo residence time. Besides, the area under curve (AUC) of MTX-loaded p-MTX micelles was greater than free MTX, indicating a drug bioavailability improvement. Overall, MTX-loaded p-MTX micelles might be a promising nanosized drug delivery system for the cancer therapy.

Combination of ß-cyclodextrin inclusion complex and self-microemulsifying drug delivery system for photostability and enhanced oral bioavailability of methotrexate: novel technique.

In the present study, we prepared an inclusion complex of methotrexate (MTX) with ß-cyclodextrin (ß-CD) in order to decrease its photosensitivity and enhance its aqueous solubility. Then we incorporated this inclusion complex in a self-microemulsifying drug delivery system (SMEDDS) overall to increase its oral bioavailability. The inclusion complex has been prepared by freeze drying method and characterized by differential scanning calorimetry (DSC), ultraviolet (UV), and infrared (IR) spectroscopy assays. The proper molecular ratio of MTX/ß-CD was found to be of 1:7, and the water-solubility of MTX was increased in an average of 10-fold. The photostability studies showed that the MTX became stable on exposure to light. Construction of pseudoternary diagrams were investigated to prepare a MTX/ß-CD inclusion complex loaded SMEDDS which was characterized by measuring the particle size and the zeta-potential. The optimum formulation of SMEDDS was a system consisting of ethyl oleate, tween 80, and propylene glycol with a mean droplet size of 39.42 nm. In vitro drug release in different pH media showed that the release profile of MTX from the MTX/ß-CD loaded SMEDDS was influenced by the pH of the release medium and presented the characteristics of a sustained release profile. Finally, in-vivo studies showed an enhancement of the bioavailability of MTX from the MTX/ß-CD loaded SMEDDS form of 1.57-fold. We concluded that the ß-CD inclusion complex loaded SMEDDS improved the chemical and physiological properties of MTX and could be a promising means for the delivery of MTX and other unstable and lipophilic drugs by oral route.