Abstract
Many factors are capable of influencing the mechanism of drug release from pellets prepared by extrusion-spheronization. This study was designed to elucidate the effect of polymer type and loading and the effect of processing variables on the rate and mechanism of drug release from ibuprofen pellets coated using aqueous polymeric dispersions. Qualitative and quantitative assessment of the success of the film coating process and the quality of the resultant films is made using scanning electron microscopy and in-vitro dissolution testing. The importance of plasticizer in polymeric film formation is also discussed. Uncoated pellets containing 60, 70 and 80% ibuprofen were coated with aqueous polymeric dispersions of polymethacrylates, ethylcellulose and silicone elastomer films. The high drug loading of these pellets adds special interest to this study. Drug release from uncoated pellets appears to follow first-order kinetics. The application of a polymeric membrane to uncoated cores has the effect of retarding drug release. There appears to be a critical coating level below which core coverage by the polymer is incomplete, drug release is diffusion controlled and first-order release kinetics are observed. Above a defined polymer level, drug release appears to be membrane controlled and zero-order kinetics are observed. The presence of plasticizer in the polymeric film imparts a hydrophilic component to an otherwise hydrophobic membrane. This enhances the penetration of aqueous solvent into the pellet core during in-vitro dissolution testing, increasing the rate of drug release. Scanning electron micrographs reveal the nature of these hydrophilic pores, beneath which a fine tortuous skeletal network of drug-depleted core is exposed.