Pulmonary liposomal formulations encapsulated procaterol hydrochloride by a remote loading method achieve sustained release and extended pharmacological effects.

Drug inhalation provides localized drug therapy for respiratory diseases. However, the therapeutic efficacy of inhaled drugs is limited by rapid clearance from the lungs. Small hydrophilic compounds have short half-lives to systemic absorption. We developed a liposomal formulation as a sustained-release strategy for pulmonary delivery of procaterol hydrochloride (PRO), a short-acting pulmonary ß2-agonist for asthma treatment. After PRO-loaded liposomes were prepared using a pH gradient (remote loading) method, 100-nm liposomes improved residence times of PRO in the lungs. PRO encapsulation efficiency and release profiles were examined by screening several liposomal formulations of lipid, cholesterol, and inner phase. Although PRO loading was not achieved using the conventional hydration method, PRO encapsulation efficiency was >60% using the pH gradient method. PRO release from liposomes was sustained for several hours depending on liposomal composition. The liposomal formulation effects on the PRO behavior in rat lungs were evaluated following pulmonary administration in vivo. Sustained PRO release was achieved using simplified egg phosphatidylcholine (EPC)/cholesterol (8/1) liposome in vitro, and greater PRO remnants were observed in rat lungs following pulmonary administration. Extended pharmacological PRO effects were observed for 120min in a histamine-induced bronchoconstriction guinea pig model. We indicated the simplified EPC/cholesterol liposome potential as a controlled-release PRO carrier for pulmonary administration.

Characterization of a doxorubicin liposome formulation by a novel in vitro release test methodology using column-switching high-performance liquid chromatography.

A novel in vitro release test methodology for a liposome formulation was developed using a column-switching high-performance liquid chromatography (HPLC) system. Doxorubicin (DXR) liposome formulations were used as a model. A DXR liposome formulation was dispersed into a release medium, and the dispersion fluid was directly injected at predetermined time points into the column-switching HPLC system. To evaluate the release profile, this system can be used for determining the released and encapsulated DXR in the liposome formulation separately. Comparison with a conventional in vitro release test methodology by dialysis revealed that the methodology developed by column-switching HPLC had no rate-limiting process of membrane permeation of the drug (which is occasionally observed in the dialysis method). The in vitro release profiles of DXR liposome formulations were well characterized using the method developed by column-switching HPLC, and different in vitro release characteristics were revealed. The developed method did not require a large amount of sample or a complicated pretreatment. In addition, the developed column-switching HPLC system was applicable for characterization of the encapsulation profile of liposome formulations.

Rapid determination of the encapsulation efficiency of a liposome formulation using column-switching HPLC.

The feasibility of a rapid automated method for determination of the encapsulation efficiency (EE) of a liposome formulation using a column-switching HPLC system was confirmed by employing several types of liposome formulations containing doxorubicin (DXR). A suspension of DXR liposome was injected directly into an online solid-phase extraction (SPE) system comprising a Diol SPE column and an ODS SPE column connected in series. Free (not encapsulated) DXR was trapped on the Diol SPE column, whereas encapsulated DXR was eluted without interaction. The eluted encapsulated DXR was trapped on the ODS SPE column after being extracted from the inner phase of the liposome by mixing with an organic solvent. Trapped free and encapsulated DXR were eluted sequentially and analyzed separately by gradient HPLC. The time taken by this automated method was only 25min, whereas conventional methods such as ultracentrifugation are time consuming and labor intensive. Validation results and comparison with ultracentrifugation suggested that our method was sufficiently accurate and sensitive to be used to evaluate EE of a liposome formulation without complicated pretreatment.