Stabilization of $alpha;-chymotrypsin at the CH2Cl2/water interface and upon water-in-oil-in-water encapsulation in PLGA microspheres

Protein inactivation and aggregation are serious drawbacks in the encapsulation of proteins in bioerodible polymers by water-in-oil-in-water (w/o/w) encapsulation. The model protein alpha-chymotrypsin was employed to investigate whether its stabilization towards the major stress factors in the w/o/w encapsulation procedure would allow for the encapsulation and release of non-aggregated and active protein. Due to the formation of amorphous aggregates alpha-chymotrypsin is an excellent sensor to probe unfolding events. Furthermore, its enzymatic activity is highly sensitive towards the presence of organic solvents. alpha-Chymotrypsin in aqueous solution showed substantial aggregation and activity loss when it was homogenized with CH(2)Cl(2) due to adsorption to the interface. Its w/o/w encapsulation in poly(lactic-co-glycolic)acid (PLGA) microspheres caused formation of 35% non-covalent aggregates and reduced the specific activity by 14%. Screening for efficient excipients revealed that co-dissolving the protein with maltose and polyethylene glycol (PEG, M(w) 5000) in the first aqueous phase reduced interface-induced protein aggregation and inactivation. Employing these excipients during encapsulation led to a reduction in alpha-chymotrypsin inactivation (10%) and aggregation (12%). Optimizing the effect of PEG by also dissolving the excipient in the organic phase prior to encapsulation further decreased the amount of non-covalent aggregates to 7% and loss in activity to 5%. The data obtained demonstrate that the w/o emulsification step is the main stress-factor in the w/o/w encapsulation procedure but subsequent encapsulation steps also cause some protein aggregation.