N-trimethyl chitosan chloride-coated liposomes for the oral delivery of curcumin.

The aims of this study were to design the formulation of curcumin (CUR) liposomes coated with N-trimethyl chitosan chloride (TMC) and to evaluate in vitro release characteristics and in vivo pharmacokinetics and bioavailability of TMC-coated CUR liposomes in rats. The structure of synthesized TMC was examined by infrared spectroscopy, with the presence of trimethyl groups, and by proton nuclear magnetic resonance spectroscopy, indicating the high degree of substitution quaternization (65.6%). Liposomes, composed of soybean phosphotidylcholine, cholestrol, and D-α-tocopheryl polyethylene glycol 1000 succinate, were prepared by a thin-film dispersion method. Characteristics of the CUR liposomes, including entrapment efficiency (86.67%), drug-loading efficiency (2.33%), morphology, particle size (221.4 nm for uncoated liposomes and 657.7 nm for TMC-coated liposomes), and zeta potential (-9.63 mV for uncoated liposomes and +15.64 mV for TMC-coated liposomes) were investigated. Uncoated CUR liposomes and TMC-coated CUR liposomes showed a similar in vitro release profile. Nearly 50% of CUR was released from liposomes, whereas 80% of CUR was released from CUR propylene glycol solution. CUR incorporated into TMC-coated liposomes exhibited different pharmacokinetic parameters and enhanced bioavailability (C(max) = 46.13 µg/L, t(1/2) = 12.05 hours, AUC = 416.58 µg/L·h), compared with CUR encapsulated by uncoated liposomes (C(max) = 32.12 µg/L, t(1/2) = 9.79 hours, AUC = 263.77 µg/L·h) and CUR suspension (C(max) = 35.46 µg/L, t(1/2) = 3.85 hours, AUC = 244.77 µg/L·h). In conclusion, oral delivery of coated CUR liposomes is a promising strategy for poorly water-soluble CUR.

The development of stimuli-responsive polymeric micelles for effective delivery of chemotherapeutic agents.

Stimuli-responsive polymeric micelles, a novel category of polymeric micelles with response to endogenous or exogenous environments, show variable physicochemical properties as the variation of endogenous or exogenous circumstances. Because of differences between tumour tissues and normal tissues in physicochemical properties and sensitivity to variation of endogenous or exogenous environments, the application of chemotherapeutic agents loaded stimuli-responsive polymeric micelles are regarded as promising strategies for tumour treatment. In this article, the recent developments of chemotherapeutic agents loaded stimuli-responsive polymeric micelles, for example the preparation of novel stimuli-responsive polymeric micelles and the research progresses of action mechanisms of chemotherapeutic agents loaded micelles, were reviewed and discussed in detail. The advantages of stimuli-responsive chemotherapeutic agents loaded polymeric micelles in practical tumour treatment were also illustrated with the assistance of examples of stimuli-responsive polymeric micelles for antitumor agents delivery.

Redox-sensitive self-assembled nanoparticles based on alpha-tocopherol succinate-modified heparin for intracellular delivery of paclitaxel.

To remedy the problems riddled in cancer chemotherapy, such as poor solubility, low selectivity, and insufficient intra-cellular release of drugs, novel heparin-based redox-sensitive polymeric nanoparticles were developed. The amphiphilic polymer, heparin-alpha-tocopherol succinate (Hep-cys-TOS) was synthesized by grafting hydrophobic TOS to heparin using cystamine as the redox-sensitive linker, which could self-assemble into nanoparticles in phosphate buffer saline (PBS) with low critical aggregation concentration (CAC) values ranging from 0.026 to 0.093mg/mL. Paclitaxel (PTX)-loaded Hep-cys-TOS nanoparticles were prepared via a dialysis method, exhibiting a high drug-loading efficiency of 18.99%. Physicochemical properties of the optimized formulation were characterized by dynamic light scattering (DLS), transmission electron microscope (TEM) and differential scanning calorimetry (DSC). Subsequently, the redox-sensitivity of Hep-cys-TOS nanoparticles was confirmed by the changes in size distribution, morphology and appearance after dithiothreitol (DTT) treatment. Besides, the in vitro release of PTX from Hep-cys-TOS nanoparticles also exhibited a redox-triggered profile. Also, the uptake behavior and pathways of coumarin 6-loaded Hep-cys-TOS nanoparticles were investigated, suggesting the nanoparticles could be taken into MCF-7 cells in energy-dependent, caveolae-mediated and cholesterol-dependent endocytosis manners. Later, MTT assays of different PTX-free and PTX-loaded formulations revealed the desirable safety of PTX-free nanoparticles and the enhanced anti-cancer activity of PTX-loaded Hep-cys-TOS nanoparticles (IC50=0.79µg/mL). Apoptosis study indicated the redox-sensitive formulation could induce more apoptosis of MCF-7 cells than insensitive one (55.2% vs. 41.7%), showing the importance of intracellular burst release of PTX. Subsequently, the hemolytic toxicity confirmed the safety of the nanoparticles for intravenous administration. The results indicated the developed redox-sensitive nanoparticles were promising as intracellular drug delivery vehicles for cancer treatment.

Self-assembled micelles based on Chondroitin sulfate/poly (d,l-lactideco-glycolide) block copolymers for doxorubicin delivery.

Doxorubicin (DOX) is one of the most common chemotherapeutic agents for the treatment of various cancers, but its clinical usage is limited by dose-dependent cardiotoxicity. We have recently synthesized a series of Chondroitin sulfate/poly (d,l-lactideco-glycolide) block copolymers (Chs-b-PLGA) with different length of hydrophobic block by an end-to-end coupling strategy. The structure of the amphiphilic block copolymers with low critical micelle concentration (∼28mg/L) were confirmed by 1H NMR. The copolymers could self-assemble into stable micelles in aqueous environment with homogeneous size distribution and negative zeta potential. The hemolytic study indicated their excellent blood compatibility and potential application for intravenous administration. DOX can be efficiently encapsulated by the Chs-b-PLGA micelles. The DOX-loaded micelles showed a sustained and pH dependent drug release behavior. The cytotoxicity assay showed no associated toxicity with blank micelles while concentration-related cell inhibition with DOX-loaded micelles. Moreover, fast cellular uptake of DOX-loaded micelles was observed by fluorescent microscope. In vivo pharmacokinetics study showed that the Chs-b-PLGA micelles could significantly prolong the blood circulation time of DOX. The maximum tolerated dose (MTD) of DOX-loaded micelles in Kunming mice was about 2-fold higher of the MTD of free DOX, indicating a high tolerance of the DOX-loaded micelles. In conclusion, the Chs-b-PLGA micelles would be a potentially useful drug delivery system for cancer therapy.

Formulation optimization and bioavailability after oral and nasal administration in rabbits of puerarin-loaded microemulsion.

The main objective of the study was to investigate the efficacy of microemulsion (ME) to facilitate bioavailability of puerarin (PUE) after oral and nasal administration. The pseudo-ternary phase diagrams were constructed to screen the ME components and optimize the ME formulation. The optimized formulation for bioavailability assessment consisted of 20% Tween 80, 20% glycerin, and 1.6% ethyl oleate. The solubility (27.8 mg/mL) of PUE in ME was significantly improved compared to that (4.58 mg/mL) of crude PUE in water. The ME droplets were spherical with a mean particle diameter of 23.4 nm. After nasal (5 mg/kg) and oral (20 mg/kg) administration of a single dose of PUE as ME to fasted rabbits, the absolute bioavailability was 34.58% and 13.54%, respectively. It showed a shorter T(max) (0.75 h) for nasal administration than that (1.0 h) for oral administration of PUE-loaded ME. The C(max) of PUE-loaded ME was 0.55 µg/mL after nasal administration and 0.64 µg/mL after oral administration, respectively. The results showed that nasal administration might be a promising route to enhance the absorption of PUE in the form of ME.

Development of nanosuspension formulation for oral delivery of quercetin.

With the aim to enhance dissolution rate and oral bioavailability of quercetin, a poorly water-soluble drug, quercetin loaded nanosuspension (QT-NS) was fabricated by a tandem of nano-precipitation (NP) and high pressure homogenization (HPH) method. The formulation of nanosuspension was optimized by screening different stabilizers. Characterization of the original QT powder and QT-NS was carried out by transmission electron microscopy and scanning electron microscopy, X-ray diffraction (XRD) and dissolution tests. QT-NS presented a sphere-like shape under transmission electron microscopy with an average diameter of 393.5 nm and the zeta potential of -35.75 mV. XRD study suggested that QT was maintained in the state of crystalline during the fabrication process. The solubility of QT in nanosuspension was about 70-fold that of crude QT, and the dissolution of QT from QT-NS was increased as compared to that of the original QT powder. In plasma, QT-NS exhibited a significant reduction of clearance rate (2 +/- 0.1 mL/min vs. 15 +/- 4 mL/min) and increase of AUC(0-infinity), (53995 +/- 4126 microg/mL x min versus 3470 +/- 110.1 microg/mL x min) compared with the control suspension. Our results showed that the developed nanosuspension formulation had a great potential as a possible formulation of the poorly water-soluble QT to enhance the bioavailability.