Scale-up issues during sterile filtration of glycoconjugate vaccines.

Several recent studies have provided important insights into the factors controlling the sterile filtration of glycoconjugate vaccines; however, this work has been limited to small-scale disk filters with very uniform flow distribution. The objective of this study was to examine the scale-up of the sterile filtration step using a glycoconjugate drug substance made from a single polysaccharide serotype. Experimental data were obtained during constant flux filtration through 0.22 µm Durapore® polyvinylidene difluoride (PVDF) membranes, both with small discs and with the Opticap® XL2 pleated cartridge. The transmembrane pressure increased rapidly during the glycoconjugate filtration due to membrane fouling, with the rate of pressure increase being more pronounced in the pleated cartridge. Additional insights into the fouling behavior were obtained using confocal microscopy by in situ labeling of the glycoconjugate captured within the filter media using an Alexa Fluor fluorescent dye. Glycoconjugate deposition occurred only within the first 5-15 µm of the 0.22 µm Durapore® membrane at both scales, with more variability in the deposition pattern observed for the pleated filter due to the non-uniform flow distribution in the Opticap® XL2 cartridge. These results provide important insights into the underlying fouling behavior during sterile filtration of glycoconjugate vaccines as well as a framework for the scale-up of the sterile filter step in glycoconjugate biomanufacturing.

Prefiltration enhances performance of sterile filtration for glycoconjugate vaccines.

Recent studies have reported very low capacity during sterile filtration of glycoconjugate vaccines due to rapid fouling of the sterile filter. The objective of this study was to explore the potential for significantly increasing the capacity of the sterile filter through the use of an appropriate prefilter. Data were obtained using prefilters with different pore size and chemistry, with the sterile filtration performed at constant filtrate flux using 0.22 µm nominal pore size Durapore® polyvinylidene difluoride membranes. Prefiltration through 5 µm pore size Durapore® or Nylon prefilters nearly eliminated the fouling of the sterile filter, leading to more than a 100-fold reduction in the rate of pressure increase for the sterile filter. This dramatic improvement in sterile filter performance was due to the removal of large components (greater than 1 µm in size) as confirmed by dynamic light scattering. These results demonstrate the potential of using large pore size prefilters to significantly enhance the performance of the sterile filtration process for the production of important glycoconjugate vaccines.

Fouling Behavior during Sterile Filtration of Different Glycoconjugate Serotypes Used in Conjugate Vaccines.

PURPOSE: Sterile filtration can be a particular challenge when processing very large glycoconjugate vaccines. The objective of this study was to examine the sterile filtration performance of a series of glycoconjugate vaccines produced by coupling different polysaccharide serotypes to an immunogenic protein. METHODS: Sterile filtration was performed at constant filtrate flux using 0.22 µm pore size Durapore® polyvinylidene fluoride membranes. Glycoconjugates were characterized by dynamic light scattering, rheological measurements, and nanoparticle tracking analysis (NTA). Confocal microscopy was used to examine glycoconjugate capture profiles within the membrane. Transmembrane pressure data were analyzed using a recently developed fouling model. RESULTS: All glycoconjugates deposited in a narrow band near the entrance of the Durapore® membranes. The rate of fouling varied significantly for the different serotypes, with the fouling parameter correlated with the fraction of glycoconjugates larger than 200 nm in size. CONCLUSIONS: The fouling behavior and sterile filter capacity of the different glycoconjugate serotypes are determined primarily by the presence of large species (>200 nm in size) as determined by nanoparticle tracking analysis. The modified intermediate pore blockage model provides a framework for predicting the sterile filtration performance for these glycoconjugate vaccines.