Drug particle size influence on enteric beads produced by a droplet extrusion/precipitation method

This study proposes a novel binary crosslinked ternary multiple-unit system, collectively referred to as calcium-alginate-pectinate-cellulose acetophthalate gelispheres (CAPCA), for the purpose of obtaining linear, controlled drug release. This polymeric system, composed of sodium alginate, pectin, and cellulose acetophthalate, was developed through a binary crosslinking reaction in a composite aqueous system consisting of calcium and acetate ions. The crosslinking reaction was optimized in terms of maximizing drug release suppression and could be obtained by exposing the gelispheres for 24 hours to a combined aqueous solution of 15% w/v acetic acid and 2% w/v calcium chloride. The highly acidic nature of this solution (pH 1.9) was desirable for enhancing the drug entrapment efficiency of the gelispheres. Synchronization of matrix swelling and erosion appeared to be responsible for the attainment of zero-order drug release. However, such perfect synchronization was only achievable through application of the ternary polymeric combination presented in this work. The main advantages of the ternary system shown in this study over the previously presented binary calcium-alginate-pectinate system (CAP) proposed by Pillay and Fassihi (1999a, 1999b), was provision of extended drug release over 18 hours, minimization of late-phase drug release tapering, and provision of superior linearity in drug release profiles. Kinetic modeling of dissolution data using various power law equations highlighted the significance of matrix relaxation and erosion in modulation of drug release rate. In all cases of model fitting excellent correlation (r(2) > 0.98) was obtained between observed and predicted data. Textural profiling of crosslinked gelispheres reflected a significantly lower reduction in matrix resilience as the concentration of cellulose acetophthalate was increased in the gelisphere formulation. This may be attributed to the concentration-dependent matrix plastic-transforming property of cellulose acetophthalate.

show abstract

Robust Optimization of Alginate-Carbopol 940 Bead Formulations

López-Cacho

González‐R

Talero

et al. 2012

The Scientific World Journal

View full text Add to dashboard Cite

Formulation process is a very complex activity which sometimes implicates taking decisions about parameters or variables to obtain the best results in a high variability or uncertainty context. Therefore, robust optimization tools can be very useful for obtaining high quality formulations. This paper proposes the optimization of different responses through the robust Taguchi method. Each response was evaluated like a noise variable, allowing the application of Taguchi techniques to obtain a response under the point of view of the signal to noise ratio. A L 18 Taguchi orthogonal array design was employed to investigate the effect of eight independent variables involved in the formulation of alginate-Carbopol beads. Responses evaluated were related to drug release profile from beads (t 50% and AUC), swelling performance, encapsulation efficiency, shape and size parameters. Confirmation tests to verify the prediction model were carried out and the obtained results were very similar to those predicted in every profile. Results reveal that the robust optimization is a very useful approach that allows greater precision and accuracy to the desired value.

show abstract

Drug particle size influence on enteric beads produced by a droplet extrusion/precipitation method

Cited by 4 publications

References 6 publications

Electron microscope characterization of drug release from methacrylic acid-ethyl acrylate copolymer-coated cross-linked alginate-gelatine beads

Electron microscope characterization of drug release from methacrylic acid-ethyl acrylate copolymer-coated cross-linked alginate-gelatine beads

A Crosslinked Calcium-Alginate-Pectinate-Cellulose Acetophthalate Gelisphere System for Linear Drug Release

Robust Optimization of Alginate-Carbopol 940 Bead Formulations

Contact Info

Product

Resources

About