Preparation, Characterization, and Selection of Optimal Forms of (S)-Carvedilol Salts for the Development of Extended-Release Formulation.

(S)-carvedilol (S-CAR) is the dominant pharmacodynamic conformation of carvedilol, but its further development for extended-release formulation is restricted by its poor solubility. This study aimed to prepare and screen S-CAR salts that could be used to improve solubility and allow extended release. Five salts of S-CAR with well-known acid counterions (i.e., phosphate, hydrochloride, sulfate, fumarate, and tartrate) were produced using similar processes. However, these salts were obtained with water contents of 1.60-12.28%, and their physicochemical properties differed. The melting points of phosphate, hydrochloride, and tartrate were 1.1-1.5 times higher than that of the free base. The solubility of S-CAR salts was promoted to approximately 3-32 times higher than that of the free base at pH 5.0-8.0. Typical pH-dependent solubilities were evidently observed in S-CAR salts, but considerable differences in solubility properties among these salts were observed. S-CAR phosphate and hydrochloride possessed high melting points, considerable solubility, and excellent chemical and crystallographic stabilities. Accordingly, S-CAR phosphate and hydrochloride were chosen for further pharmacokinetic experiments and pharmaceutical study. S-CAR phosphate and hydrochloride extended-release capsules were prepared using HPMC K15 as the matrix and presented extended release in in vitro and in vivo evaluations. Results implied that water molecules in the hydrated salt were a potential threat to the achievement of crystal stability and thermostability. S-CAR phosphate and hydrochloride are suitable for further development of the extended-release formulation.

Optimization of lipid materials in the formulation of S-carvedilol self-microemulsifying drug-delivery systems.

OBJECTIVES: The blocking effect of S-carvedilol (S-CAR) on the beta-adrenoceptor is about 100 times stronger than that of the right-handed conformation. However, further development is restricted because of its poor bioavailability caused by its low solubility and high first-pass effect. In the study, S-CAR self-microemulsifying drug-delivery systems (SMEDDSs) were established, and the effects of different lipid materials on the absorption and metabolism of S-CAR were investigated. METHODS: Six kinds of lipid materials with different chemical structures including oleic acid, glycerol monooleate, glycerol trioleate, oleoyl macrogol-6 glycerides, soybean lecithin, and α-tocopherol were selected to be the oil phase. The S-CAR SMEDDSs were prepared by the same ratio. In vitro characteristics, in vitro release, in situ intestine absorption, and bile excretion, as well as the in vivo characteristic of relative bioavailability, were determined. KEY FINDINGS: The lipid structure significantly affected physical characteristics, the absorption and excretion rates of S-CAR SMEDDSs. The findings of rat-intestine perfusion experiments showed that the S-CAR SMEDDSs decreased the bile-excretion rate of S-CAR. Compared with the S-CAR group, the oleic acid and soybean lecithin groups decreased the bile excretion to 32% and 45%, respectively. Pharmacokinetic studies showed that the AUCs of these two groups were about 1.9 and 1.7 times more than that of the S-CAR group, and the mean retention time was extended. CONCLUSION: The SMEDDS using ionic lipids (oleic acid or soybean lecithin) as oil phase can increase the oral bioavailability of S-CAR by increasing the solubility and reducing the first-pass effect.