Cyclosporine release and distribution in ophthalmic emulsions determined by pulsatile microdialysis.

An in vitro release test based on pulsatile microdialysis (PMD) is presented for the purpose of measuring the release of cyclosporine from ophthalmic emulsions, along with a method to determine the drug distribution within the oil-rich globule, surfactant-rich micelle and aqueous phases of the emulsion formulation. Compositionally equivalent formulations containing 0.05% cyclosporine were prepared with similar physical parameters (globule size, viscosity, surface tension zeta potential, osmolality, pH) but made with different manufacturing conditions. Emulsions were made by ultrasonication, using different ultrasonication times (22-49 min) and temperatures (50-82 °C). Formulations were stored at room temperature (20 °C) and PMD was performed under two conditions, one in which the receiving medium temperature was 20 °C, and another in which the receiving medium temperature was 35 °C to mimic the temperature change expected when a drop of formulation is administered to the eye. The PMD release data were taken at release times of 20, 40, 60, 90, 120, 180, 300 and 600 s. All experiments showed a qualitatively similar release pattern, with a rapid initial rate of drug release (Release-1) for the first few minutes, followed by a much slower release (Release-2). In addition, imposing a sudden temperature change on the formulation was observed to affect the release, with some formulations releasing faster into receiver media at 35 °C than at 20 °C, while others released faster into 20 °C than 35 °C receiver media. The drug distribution was also calculated from PMD release data into 20 °C receiver media using a novel release kinetics model. The drug distribution varied among the formulations, with 54-77% of the cyclosporine in the oil phase of the emulsions. PMD is a promising method to evaluate how manufacturing-induced differences affect the distribution and release kinetics of cyclosporine within the emulsion formulation.

An improved method for the characterization of supersaturation and precipitation of poorly soluble drugs using pulsatile microdialysis (PMD).

In current pharmaceutical drug discovery, most candidates are poorly soluble in water, which can result in poor bioavailability. To overcome this problem, formulations that create supersaturation of the drug are a well-studied alternative. Characterizing the dissolution from these systems is challenging because conventional methods, such as sampling with a syringe then filtering with a 0.2-0.45 µm filter before an HPLC assay, can overestimate the concentration of dissolved drug by allowing nuclei or small precipitated particles to pass, which then dissolve in the HPLC mobile phase. Nuclei and small particles can also cause overestimation of the dissolved concentration when using optical methods. Such overestimations can lead to failure of in vivo prediction of drug bioavailability from supersaturated systems. This paper reports a novel method to determine the free dissolved drug concentration in a dissolution medium using pulsatile microdialysis (PMD). Ibuprofen was used as a model drug for determining precipitation and supersaturation. Supersaturation was induced chemically by changing pH, and also by dissolution/release from an in-house formulation. The adaptation of a previously developed PMD model is summarized, and experimental results comparing dissolved concentrations determined using PMD and direct sampling by syringe and filtering are presented.