Chitosan-coated nanostructured lipid carriers of fenofibrate with enhanced oral bioavailability and efficacy.

Fenofibrate is frequently used to lower cholesterol levels in cardiovascular disease. Owing to its poor solubility and high gastrointestinal permeability, it is classified as a Biopharmaceutics Classification System class II compound. The aim of this study was to improve the solubility and bioavailability of fenofibrate by formulating it as fenofibrate-loaded nanostructured lipid carriers (FFB-NLCs) and coating it with a biodegradable polymer to allow controlled drug release. Chitosan-coated nanostructured lipid carriers (CF-NLCs) were prepared via an ultrasonication method using chitosan as the biodegradable polymer, stearic acid as the solid lipid, oleic acid as the liquid lipid, and Tween 80 as the surfactant. To study encapsulation efficiency and solubility conditions, stearic acid/oleic acid ratios were varied as 80/20, 70/30, 60/40, and 50/50 (mg/mg), by adjusting chitosan ratio. Chitosan is an adhesive polymer, coating the surface of the NLC to improve its bioavailability. All NLC formulations demonstrated a particle size of approximately 200 nm and a polydispersity index below 0.3. The encapsulation efficiencies of the NLC formulations were above 85%. For CF-NLCs, the solubility and encapsulation efficiency of fenofibrate were increased when compared with those of a commercial fenofibrate formulation. The pharmacokinetic and pharmacodynamic parameters of fenofibrate in the form of CF-NLCs were improved after oral administration. CF-NLCs can be used for allowing controlled release and improving the bioavailability and stability of fenofibrate.

Optimization of Polyarginine-Conjugated PEG Lipid Grafted Proliposome Formulation for Enhanced Cellular Association of a Protein Drug.

The purpose of this study was to develop an oral proliposomal powder of protein using poly-l-arginine-conjugated 1,2-distearoyl-sn-glycero-3-phosphoethanolamine-poly(ethylene glycol) (DSPE-PEG) (PLD) for enhancing cellular association upon reconstitution and to compare its effects with a non-grafted and PEGylated formulation. Cationic proliposome (CATL), PLD-grafted CATL (PLD-CATL), PEGylated CATL (PEG CATL), and PLD grafted-PEG CATL (PLD-PEG CATL) were prepared and compared. Successful conjugation between poly-l-arginine and DSPE-PEG was confirmed by 1H NMR and FT-IR. PLD was successfully grafted onto the proliposomal powder during the slurry process. Although reconstituted liposomal sizes of CATL and PLD-CATL were increased by agglomeration, PEGylation reduced the agglomeration and increased the encapsulation. The viabilities of cells treated with both CATL and PLD-CATL formulations were low but increased following PEGylation. With regard to cellular association, PLD-CATL enhanced cellular association/uptake more rapidly than did CATL. Upon PEGylation, PEG CATL showed a lower level of cellular association/uptake compared with CATL while PLD-PEG CATL did not exhibit the rapid cellular association/uptake as seen with PLD-CATL. However, PLD-PEG CATL still enhanced the higher cellular association/uptake than PEG CATL did without PLD. In conclusion, proliposomes with PLD could accelerate cellular association/uptake but also caused high cellular toxicity. PEGylation reduced cellular toxicity and also changed the cellular association pattern of the PLD formulation.

Improvement of the dissolution rate and bioavailability of fenofibrate by the supercritical anti-solvent process.

The purpose of this study was to improve solubility and oral bioavailability of fenofibrate via solid dispersion (SD) using a supercritical anti-solvent (SAS) process with amphipathic polymers P407 and TPGS. Solid dispersion techniques have been widely used to enhance the solubility and dissolution profiles of poorly soluble drugs. Fenofibrate is classified as a Biopharmaceutics Classification System class II compound because of its low solubility and high gastrointestinal permeability. Two copolymers were selected based on solubility and dissolution tests. Their physicochemical properties were compared with those prepared by conventional solvent evaporation (CSE). The SD formulations containing fenofibrate were successfully prepared using the SAS and CSE methods. The dissolution rate (%) of fenofibrate at 60 min was significantly improved compared with the solution of raw fenofibrate (19.5% ±â€¯3.7%) by 95.1% ±â€¯2.5% and 93.7% ±â€¯4.1% using the SAS and the CSE process, respectively. This approximately four-fold increase in dissolution rate indicates that oral bioavailability can be enhanced. In addition, pharmacokinetic study was analyzed using the area under the curve (AUC) and Cmax values of SAS-SD and CSE-SD in rats. The AUC was 2.1 times higher and Cmax was 1.9 times higher in SAS-SD, indicating higher concentrations of fenofibrate in the blood. In a pharmacodynamic study to evaluate the efficacy of the drug in hyperlipidemic rat models, SAS-SD showed strong lipid-lowering effects including cholesterol (1.9-fold) and triglycerides (3.3-fold), than CSE-SD. Taken together, these results suggested that SAS-SD has excellent potential as a formulation for the poorly soluble drug fenofibrate.

Overview of the Manufacturing Methods of Solid Dispersion Technology for Improving the Solubility of Poorly Water-Soluble Drugs and Application to Anticancer Drugs.

Approximately 40% of new chemical entities (NCEs), including anticancer drugs, have been reported as poorly water-soluble compounds. Anticancer drugs are classified into biologic drugs (monoclonal antibodies) and small molecule drugs (nonbiologic anticancer drugs) based on effectiveness and safety profile. Biologic drugs are administered by intravenous (IV) injection due to their large molecular weight, while small molecule drugs are preferentially administered by gastrointestinal route. Even though IV injection is the fastest route of administration and ensures complete bioavailability, this route of administration causes patient inconvenience to visit a hospital for anticancer treatments. In addition, IV administration can cause several side effects such as severe hypersensitivity, myelosuppression, neutropenia, and neurotoxicity. Oral administration is the preferred route for drug delivery due to several advantages such as low cost, pain avoidance, and safety. The main problem of NCEs is a limited aqueous solubility, resulting in poor absorption and low bioavailability. Therefore, improving oral bioavailability of poorly water-soluble drugs is a great challenge in the development of pharmaceutical dosage forms. Several methods such as solid dispersion, complexation, lipid-based systems, micronization, nanonization, and co-crystals were developed to improve the solubility of hydrophobic drugs. Recently, solid dispersion is one of the most widely used and successful techniques in formulation development. This review mainly discusses classification, methods for preparation of solid dispersions, and use of solid dispersion for improving solubility of poorly soluble anticancer drugs.