The transport effect of submicron emulsions on 5-flurouracil topical application.

Water-in-oil submicron emulsions were used as carrier for the topical delivery of 5-fluorouracil (5FU). The effect of components such as level and hydrophilic-lipophilic balance (HLB) value of surfactant, type of cosurfactant, and drug concentration on the delivery capability of drug in the receptor fluid and in the various skin layers (stratum corneum, epidermis and dermis) were evaluated. The result showed the submicron emulsion could increase the transdermal and deposition of 5FU compared with the aqueous control. Submicron emulsion with surfactant at HLB of 6.0 had higher deposition amount of drug in epidermis layer. The deposition amount of drug in the skin layers increased with increased amounts of surfactant and drug loading of submicron emulsion. However, the 0.2% 5FU-load submicron emulsion showed a comparable deposition effect in various skin layers with the commercial product (5%, Efudix®), which indicated that the submicron emulsions could be a promising drug vehicle for topical application.

The effect of submicron emulsion systems on transdermal delivery of kaempferol.

In this study, submicron emulsions have been employed as a carrier for the topical application of kaempferol. The effect of components of submicron emulsions on the physicochemical properties and permeation capability of drug were evaluated. In case of drug-loaded submicron emulsions, the cumulative amount over 12 h (Q(12 h)), lag time and deposition in skin amount ranged from 13.0±3.4 to 236.1±21.2 µg/cm(2), 1.7 to 5.3 h, and 1.10 to 7.76 µg/cm(2), respectively, which indicated that the permeation parameters of kaempferol were markedly influenced by the component ratio. Kaempferol dispensed in isopropyl myristate was used as the control. The Q(12 h), lag time and deposition amount in skin were 4.2±1.8 µg/cm(2), 6.0 h and 2.25±0.60 µg/cm(2), respectively. The data showed that used appropriate submicron emulsions as vehicle could significantly increase the Q(12 h) and deposition amount in skin and shorten the lag time, demonstrating that submicron emulsions have a potent enhancement effect for kaempferol transdermal delivery.

Formulation optimization of estradiol microemulsion using response surface methodology.

The aim of the current study was to find an optimal estradiol-loaded microemulsion with higher permeation rate and shortened lag time (LT) for transdermal application by using a response surface methodology (RSM) and constrained mixture design. Isopropyl myristate (X1 ), distilled water (X2 ), and ethanol (X3 ) were selected as independent variables, whereas the viscosity of microemulsion and permeation parameters including the cumulative amount at 24 h (Q24h ) and LT of estradiol-loaded microemulsion through skin were set as dependent variables. The result showed that the three independent variables had a remarkable effect (p < 0.05) on the dependent variables. Moreover, the predicted and observed values of these three dependent variables of the optimal microemulsion formulations, which were produced by the RSM optimization technique, were close, demonstrating that RSM was a useful technique for optimizing pharmaceutical formulations. However, the experimental estradiol-loaded microemulsion with higher permeation rate was expected to provide effective therapeutic concentration in a workable administration area.