Sixteen capillary electrophoresis applications for viral vaccine analysis.

A broad range of CE applications from our organization is reviewed to give a flavor of the use of CE within the field of vaccine analyses. Applicability of CE for viral vaccine characterization, and release and stability testing of seasonal influenza virosomal vaccines, universal subunit influenza vaccines, Sabin inactivated polio vaccines (sIPV), and adenovirus vector vaccines were demonstrated. Diverse CZE, CE-SDS, CGE, and cIEF methods were developed, validated, and applied for virus, protein, posttranslational modifications, DNA, and excipient concentration determinations, as well as for the integrity and composition verifications, and identity testing (e.g., CZE for intact virus particles, CE-SDS application for hemagglutinin quantification and influenza strain identification, chloride or bromide determination in process samples). Results were supported by other methods such as RP-HPLC, dynamic light scattering (DLS), and zeta potential measurements. Overall, 16 CE methods are presented that were developed and applied, comprising six adenovirus methods, five viral protein methods, and methods for antibodies determination of glycans, host cell-DNA, excipient chloride, and process impurity bromide. These methods were applied to support in-process control, release, stability, process- and product characterization and development, and critical reagent testing. Thirteen methods were validated. Intact virus particles were analyzed at concentrations as low as 0.8 pmol/L. Overall, CE took viral vaccine testing beyond what was previously possible, improved process and product understanding, and, in total, safety, efficacy, and quality.

Four-step approach to efficiently develop capillary gel electrophoresis methods for viral vaccine protein analysis.

Vaccines against infectious diseases are urgently needed. Therefore, modern analytical method development should be as efficient as possible to speed up vaccine development. The objectives of the study were to identify critical method parameters (CMPs) and to establish a set of steps to efficiently develop and validate a CE-SDS method for vaccine protein analysis based on a commercially available gel buffer. The CMPs were obtained from reviewing the literature and testing the effects of gel buffer dilution. A four-step approach, including two multivariate DoE (design of experiments) steps, was proposed, based on CMPs and was verified by CE-SDS method development for: (i) the determination of influenza group 1 mini-hemagglutinin glycoprotein; and (ii) the determination of polio virus particle proteins from an inactivated polio vaccine (IPV). The CMPs for sample preparation were incubation temperature(s) and time(s), pH, and reagent(s) concentration(s), and the detection wavelength. The effects of gel buffer dilution revealed the CMPs for CE-SDS separation to be the effective length, the gel buffer concentration, and the capillary temperature. The four-step approach based on the CMPs was efficient for the development of the two CE methods. A four-step approach to efficiently develop capillary gel electrophoresis methods for viral vaccine protein analysis was successfully established.

New capillary gel electrophoresis method for fast and accurate identification and quantification of multiple viral proteins in influenza vaccines.

Current methods for the identification and/or quantification of viral proteins in influenza virus and virosome samples suffer from long analysis times, limited protein coverage and/or low accuracy and precision. We studied and optimized capillary gel electrophoresis (CGE) in order to achieve faster and enhanced characterization and quantification of viral proteins. Sample preparation as well the composition of the gel buffer was investigated in order to achieve adequate protein separation in relatively short times. The total sample preparation (reduction and deglycosylation) could be carried out efficiently within two hours. Hydrodynamic injection, separation voltage, and capillary temperature were optimized in full factorial design. The final method was validated and showed good performance for hemagglutinin fragment 1 (HA1), hemagglutinin fragment 2 (HA2), matrix protein (M) and nucleoprotein (NP). The CGE method allowed identification of different virus strains based on their specific protein profile. B/Brisbane inactivated virus and virosome samples could be analyzed within one day. The CGE results (titers) were comparable to single radial immune-diffusion (SRID), but the method has the advantage of a much faster time to results. CGE analysis of A/Christchurch from upstream process demonstrated the applicability of the method to samples of high complexity. The CGE method could be used in the same analyte concentration range as the RP-HPLC method, but showed better precision and accuracy. Overall, the total analysis time for the CGE method was much shorter, allowing analysis of 100 samples in 4 days instead of 10 days for SRID.