Biophysical characterization of type A botulinum neurotoxin (BoNT/A) complex along with its thermodynamic stability was assessed through a combination of various methods. BoNT/A exists as large complexes in association with neurotoxin associated proteins (NAPs). To evaluate its biophysical behavior, size-exclusion chromatography (SEC), multi-angled light scattering (MALS), enzyme linked immunosorbent assay (ELISA), and dynamic light scattering (DLS) were utilized. Initially, a single peak (peak 1) of SEC was observed at pH 6.0, and an additional peak (peak 2) appeared at pH 7.4 with a decrement of peak 1. Through MALS and ELISA, the peak 2 was determined to be BoNT/A dissociated from its complex. The dissociation was accelerated by time and temperature. At 37°C, dissociated BoNT/A self-associated at pH 7.4 in the presence of polysorbate 20. On the other hand, the dissociation was partly reversible when titrated back to pH 6.0. Overall, BoNT/A was more stable when associated with NAPs at pH 6.0 compared to its dissociated state at pH 7.4. The conventional analytical methods could be utilized to relatively quantify its amount in different formulations.
Biophysical characterization of type A botulinum neurotoxin (BoNT/A) complex along with its thermodynamic stability was assessed through a combination of various methods. BoNT/A exists as large complexes in association with neurotoxin associated proteins (NAPs). To evaluate its biophysical behavior, size-exclusion chromatography (SEC), multi-angled light scattering (MALS), enzyme linked immunosorbent assay (ELISA), and dynamic light scattering (DLS) were utilized. Initially, a single peak (peak 1) of SEC was observed at pH 6.0, and an additional peak (peak 2) appeared at pH 7.4 with a decrement of peak 1. Through MALS and ELISA, the peak 2 was determined to be BoNT/A dissociated from its complex. The dissociation was accelerated by time and temperature. At 37°C, dissociated BoNT/A self-associated at pH 7.4 in the presence of polysorbate 20. On the other hand, the dissociation was partly reversible when titrated back to pH 6.0. Overall, BoNT/A was more stable when associated with NAPs at pH 6.0 compared to its dissociated state at pH 7.4. The conventional analytical methods could be utilized to relatively quantify its amount in different formulations.
The effects of the manufacturing process and the regeneration of Shirasu porous glass (SPG) membranes were investigated on the reproducibility of protein precipitants, termed protein microbeads. Intravenous immunoglobulin (IVIG) was selected as a model protein to produce its microbeads in seven different cases. The results showed that the hydrophobically modified SPG membrane produced finer microbeads than the hydrophilic SPG membrane, but this was inconsistent when using the general regeneration method. Its reproducibility was determined to be mostly dependent on rinsing the SPG membrane prior to the modification and on the protein concentration used for emulsification. The higher concentration could foul and plug the membrane during protein release and thus the membrane must be washed thoroughly before hydrophobic modification. Moreover, the membrane regenerated by silicone resin dissolved in ethanol had better reproducibility than silicone resin dissolved in water. On the other hand, rinsing the protein precipitant with cold ethanol after the emulsification was not favorable and induced protein aggregation. With the addition of trehalose, the purity of the IVIG microbeads was almost the same as before microbeadification. Therefore, the regeneration method, protein concentration, and its stabilizer are key to the success of protein emulsification and precipitation using the SPG membrane.
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