PURPOSE: Preparation of spherical fine protein microparticles by the lyophilization of a protein-poly(ethylene glycol) (PEG) aqueous mixture was investigated. The main objective was to establish a method for preparing protein microparticles suitable for pharmaceutical production. METHODS: Aqueous solutions containing bovine serum albumin (BSA) and PEG at various mixing ratios were freeze-dried. The lyophilizates were dispersed in methylene chloride and subjected to particle size analysis. Analogous studies were performed using several model proteins. A phase diagram of the PEG-BSA aqueous system was obtained by the titration method. RESULTS: The particle size of BSA decreased as the PEG-BSA ratio increased. A bending point was observed in this relationship, at which the PEG-BSA ratio coincided with that of the critical point on the phase diagram of the PEG-BSA system. These results were explained by the freezing-induced condensation, followed by phase separation in the PEG-BSA system. CONCLUSIONS: Spherical fine protein microparticles were successfully obtained at high yield and without any activity loss under optimum conditions. This new technology could be applicable to proteins with a wide range of molecular weights, and is expected to be developed for dry powder inhalations or long-term sustained release microsphere formulations.
PURPOSE: Preparation of spherical fine protein microparticles by the lyophilization of a protein-poly(ethylene glycol) (PEG) aqueous mixture was investigated. The main objective was to establish a method for preparing protein microparticles suitable for pharmaceutical production. METHODS: Aqueous solutions containing bovineserum albumin (BSA) and PEG at various mixing ratios were freeze-dried. The lyophilizates were dispersed in methylene chloride and subjected to particle size analysis. Analogous studies were performed using several model proteins. A phase diagram of the PEG-BSA aqueous system was obtained by the titration method. RESULTS: The particle size of BSA decreased as the PEG-BSA ratio increased. A bending point was observed in this relationship, at which the PEG-BSA ratio coincided with that of the critical point on the phase diagram of the PEG-BSA system. These results were explained by the freezing-induced condensation, followed by phase separation in the PEG-BSA system. CONCLUSIONS: Spherical fine protein microparticles were successfully obtained at high yield and without any activity loss under optimum conditions. This new technology could be applicable to proteins with a wide range of molecular weights, and is expected to be developed for dry powder inhalations or long-term sustained release microsphere formulations.
Authors: Vincent F Fiore; Megan C Lofton; Susanne Roser-Page; Stephen C Yang; Jesse Roman; Niren Murthy; Thomas H Barker Journal: Biomaterials Date: 2009-10-20 Impact factor: 12.479
Authors: Nathalie Bock; Tim R Dargaville; Giles T S Kirby; Dietmar W Hutmacher; Maria A Woodruff Journal: Tissue Eng Part C Methods Date: 2015-12-14 Impact factor: 3.056