Development of the loratadine gel for enhanced transdermal delivery.

BACKGROUND: The oral administration of loratadine, an antihistamine, can have a variety of adverse side effects, such as headache, fatigue, and nausea, because of the transient high blood concentration. To avoid these effects, loratadine can be administered using a transdermal drug delivery system. METHOD: This study examined the effects of the drug concentration on drug release from prepared hydroxypropyl methylcellulose gels using a synthetic cellulose membrane at 37 degrees C. The drug concentrations tested were 0.1%, 0.2%, 0.3%, 0.4%, and 0.5% (w/w). The effect of temperature on drug release from the 0.3% loratadine gels was evaluated at 27 degrees C, 32 degrees C, 37 degrees C, and 42 degrees C. Various types of penetration enhancers, such as glycols, glycerides, propylene glycol derivatives, nonionic surfactants, and fatty acids, were incorporated in the gel formulation to increase the level of drug permeation. RESULTS: The rate of drug release increased with increasing drug concentration or temperature. The activation energy for the release of the drug was 5.714 kcal/mol for 0.3% loratadine gel. Among all the enhancers used in this study, polyoxyethylene 2-stearyl ether showed the best enhancing effect. The enhancement factor of the loratadine gel containing the polyoxyethylene 2-stearyl ether was 2.03 compared with that of the loratadine system containing no enhancer. CONCLUSIONS: These results suggest that the topical gel formulation of loratadine containing a penetration enhancer could be developed to enhance the penetration of loratadine.

Enhanced controlled release of loratadine from the ethylene-vinyl acetate matrix containing plasticizer.

An ethylene-vinyl acetate (EVA) matrix containing plasticizer was prepared as a potential controlled release system for loratadine. The EVA matrix containing loratadine was prepared as the transdermal device using casting methods. The solubility of loratadine according to the volume fraction of PEG 400 was determined. The effects of the drug concentration, temperature, and plasticizers on the release of the drug were determined at 37 degrees C using 40% PEG 400 solution as the receptor medium using the modified Keshary-Chien cell. Some types of plasticizers. such as citrates and phthalates, were used to prepare the pores and increase the flexibility of the EVA matrix. The solubility test according to the PEG 400 volume fraction revealed the highest solubility in the 40% PEG 400 solution. The rate of drug released from the EVA matrix increased with increasing temperature and drug loading. There was a linear relationship between the release rate and the square root of the loading dose. The activation energy for drug release from the EVA matrix with a loading dose of 1%, 2%, 3%, 4%, and 5% was estimated to be 6.83, 6.80, 6.77, 6.71, and 6.65 kcal/mol, respectively Among the plasticizers used, diethyl phthalate showed the highest level of loratadine release. In conclusion, an EVA matrix containing plasticizer could be used to enhance the controlled release of loratadine.