Self-dispersing lipid formulations for improving oral absorption of lipophilic drugs.

The main purpose of this review is to provide a current and general overview of the existing self-dispersing formulations resulting from dilution into emulsions, microemulsions and surfactant dispersions. The systematic approach used and the presentation of the various physico-chemical and biopharmaceutical aspects should facilitate the comprehension of this interesting field and clarify the main considerations involved in designing and characterizing a specific self-dispersing drug delivery system. Studies have shown that the self-emulsification process is specific to the nature of the oil/surfactant pair, surfactant concentration, oil/surfactant ratio and temperature at which self-emulsification occurs. It was suggested that the ease of emulsification could be associated with the ease by which water penetrates into the various liquid crystalline (LC) or gel phases formed on the surface of the droplet. Numerous bioavailability studies carried out in animals and humans, reviewed in the present study, suggest that hydrophobic drugs are better absorbed when administered in self-dispersing lipid formulations (SDLFs). Examples which illustrate the beneficial use of SDLFs for drug absorption enhancement are presented. This review outlines SDLFs as one of the most promising approaches to overcome the formulation difficulties of these hydrophobic/lipophilic drugs.

Charge-dependent interaction of self-emulsifying oil formulations with Caco-2 cells monolayers: binding, effects on barrier function and cytotoxicity.

A positively charged self-emulsifying oil formulation (SEOF), aimed to enhance oral bioavailability of drugs poorly soluble in water, was recently developed. In the present study the Caco-2 cell model was used for the investigation of the charge-dependent interactions of this SEOF with human intestinal epithelial cells. The positively charged emulsions affected the barrier properties of the cell monolayer at high concentrations and reduced the cell viability. However, at the dilution with aqueous phase used in the present study (1:2000), the positively charged SEOF did not induce any detectable cytotoxic effect. The binding of the fluorescent dye DiIC(18)(3) was much higher from the positively charged SEOF, compared to the negatively charged formulation, suggesting an increased closer adhesion of the droplets to the cell surface due to the electrostatic attraction. No transepithelial transport of this compound across Caco-2 cell monolayers was observed with any SEOF formulation.

Interaction of a self-emulsifying lipid drug delivery system with the everted rat intestinal mucosa as a function of droplet size and surface charge.

PURPOSE: To investigate the interaction of positively charged self-emulsifying oil formulations (SEOF) following aqueous dilution as a function of resulting emulsion droplet charge and size with rat everted intestinal mucosa, adherent mucus layer and Peyer's patches, using cyclosporine A (CsA) as a lipophilic model drug. METHODS: Droplet size determination (TEM technique) and zeta-potential measurements were used to characterize the resulting emulsions. For the ex vivo interaction study, the well-known rat intestine everted sac technique was used in combination with confocal microscopy. RESULTS: The positively charged oil droplets formed by SEOF dilutions at ratios of 1/50 and 1/10 elicited the stronger interaction with the mucosal surface. The positive charge of the smaller droplets was more readily neutralized, and even reversed in aqueous solutions containing moderate subphysiological mucin concentrations. Parameters such as droplet size, negativity of the epithelial mucosa potential and presence of the mucus layer on the epithelial surface affected drug mucosa uptake and the adhesion of the positively charged droplets to the rat intestinal mucosa. CONCLUSIONS: The enhanced electrostatic interactions of positively charged droplets with the mucosal surface are mostly responsible for the preferential uptake of CsA from the positively charged droplets as compared to negatively charged droplets irrespective of the experimental conditions used. The increased uptake of the CsA from the negatively charged oil droplets was consistent with the dilution extent, as expected, whereas in the positively charged droplets, an intermediate droplet size range was identified resulting in optimum drug uptake and clearly suggesting that drug uptake was not consistent with either dilution extent or droplet size.

Positively charged self-emulsifying oil formulation for improving oral bioavailability of progesterone.

A self-emulsifying oil formulation (SEOF) comprised of Tween 80, benzyl alcohol (BA), ethyl oleate (EO), and oleylamine (OA), able to produce positively charged submicron emulsions upon aqueous or buffer dilution, was developed and characterized. The positive charge of the formulation was attributed to the localization of the cationic lipid, OA, at the oil/water interface of the diluted SEOFs. Binary phase diagram analysis of the basic lipophilic system showed that the SEOF elicited progressive inverse phase behavior under continuous aqueous phase dilution. At infinite dilution fine submicron o/w emulsions were formed only when BA concentrations did not exceed 50% in the formulation. The self-emulsification process was not markedly affected by the variation in pH over the entire physiological range. The neurotoxic effects observed in acute toxicity studies with the concentrated emulsion containing 3% BA obtained from the dilution of the SEOF vehicle were attributed to the BA since a simple aqueous solution at the same BA dose caused similar adverse effects. However, no toxic effects were noticed when the dose administered was 30 times the potential dose that could probably be administered to humans. Comparative oral bioavailability studies in young female rats using several different liquid dosage forms of progesterone indicated that of those studied, only the positively charged SEOF could be considered a potential effective dosage form for oral administration of progesterone since it elicited the highest and most satisfactory absorption profile.