Development of competitive inhibition ELISA as an effective potency test to analyze human rabies vaccines and assessment of the antigenic epitope of rabies glycoprotein

Development of an ELISA for an effective potency determination of recombinant rabies human monoclonal antibody

Rapid Fluorescence Focus Inhibition Test (RFFIT) is the most widely used cell-based assay to measure the potency of recombinant human rabies monoclonal antibodies. Nonetheless, RFFIT assay is time-consuming and it requires well-equipped biosafety level 2 facility, virulent live rabies virus cultures, permissive cell lines, and well-trained manpower. Therefore, the development of alternative methods to the RFFIT has been encouraged by the World Health Organization (WHO) expert working groups to overcome these barriers. An In-vitro ELISA test has been developed as an alternative to the RFFIT assay, for quantifying the rabies monoclonal antibody (mAb) potency using inactivated rabies virus vaccine (Rabivax-S). It is based on the specific interaction between the antigen and the antibody, that induces neutralizing antibody response to rabies virus. The ELISA was validated involving accuracy and precision within 20 % coefficient of variance. The validation has been done by 4PL standard curve with linearity r2 ˃ 0.98 and LLOQ of 0.3 μg/mL indicating high assay sensitivity. The specificity of the assay was ascertained by challenging with another homologous non-rabies humanized mAb, which does not show binding with the rabies virus. The indirect ELISA developed here, is precise, robust, and accurate to quantitate the potency of rabies monoclonal antibody. It is highly sensitive and has a broad range of detection. It is easy to perform, and it has a short turnaround time (results available in few hours). Furthermore, it is cost effective and can be performed with low-cost resource setting, as there is no requirement of handling the live cells and live virus and also BSL-2 Facility.

Variability of in vivo potency assays of whole-cell pertussis, inactivated polio, and meningococcal B vaccines

For the batch release of vaccines, potency release assays are required. Non-animal in vitro tests have numerous advantages and are preferred; however, several vaccines are still released using in vivo assays. Their major drawback is the inherent variability with its practical implications. We quantified the variability of in vivo potency release assays for whole-cell pertussis, inactivated polio and meningococcal B (MenB) vaccines which showed large CV (Coefficient of Variation) ranging from 34% to 125%. As inherent variability might potentially be attributed to the highly variable immune system between individual animals, we evaluated the antibody titres to four MenB antigens in 344 individual outbred mice. These varied strongly, with more than 100-fold differences in antibody titres in responsive mice. Furthermore, within individual mice there was generally no correlation between the strengths of the responses to the four antigens. A mouse with a very low or no response to one antigen in many cases exhibited a strong response to another antigen. The large differences between individual animals is likely a considerable contributor to the inherent variability of in vivo potency assays. Our data again support the notion that it is preferred to move away from in vivo potency assays for monitoring batch to batch consistency as part of vaccine batch release testing.

A time-resolved fluorescence immunoassay for rapid and precise automatic quality control of human papillomavirus type 68 VLPs in human papillomavirus vaccine

The effectiveness and necessity of human papillomavirus (HPV) vaccination to prevent HPV infection and cervical cancer are increasingly recognized by people. The 15-valent HPV vaccine, which protects against almost high-risk types of HPV viruses identified by WHO, has attracted much attention. However, as the valence of vaccines increases, quality control in the HPV vaccine production process is facing more challenges. The precise quality control of the HPV type 68 virus-like particles (VLPs), one of the unique components of the 15-valent HPV vaccine that distinguishes it from existing vaccines, is the new requirement for vaccine manufacturers. Here we developed a novel time-resolved fluorescence immunoassay (TRFIA) for rapid and precise automatic quality control of HPV68 VLPs in HPV vaccine. Two murine monoclonal antibodies specifically targeting the HPV68 L1 protein were used to establish a classical sandwich assay. Except for pretreating the vaccine sample, the whole analysis process was performed by a fully automated machine, which saves detection time and gets rid of manual error. Multiple experiments established that the current novel TRFIA can efficiently and reliably analyses HPV68 VLPs. Present novel TRFIA has exhibited merits with speed, robustness, high sensitivity with a minimum detection value of 0.08 ng/mL, considerable accuracy, a wide detection range (up to 1000 ng/mL) and excellent specificity. It is also expected to provide a new detection method for quality control for each HPV type VLPs. To summarize, the novel TRFIA is of great interest for application in HPV vaccine quality control.

Establishment of Sandwich ELISA for Quality Control in Rotavirus Vaccine Production

Non-replicating rotavirus vaccines are alternative strategies that may improve the protective efficacy of rotavirus vaccines in low- and middle-income countries. The truncated spike protein VP4 (aa26-476, VP4*)was a candidate antigen for the development of recombinant rotavirus vaccines, with higher immunogenicity and protective efficacy compared to VP8* and VP5* alone. This article describes the development of three genotype-specific sandwich ELISAs for P[4], P[6], and P[8]-VP4*, which are important for quality control in rotavirus vaccine production. Our results showed that the detection systems had good specificity for the different genotype VP4* and were not influenced by the E. coli host proteins. Moreover, the detection systems play an important role in determining whether the target protein was contaminated by VP4* proteins of other genotypes. They can also detect the adsorption rate of the adjuvant to the P[4], P[6], P[8]-VP4* protein during the process development. The three detection systems will play an important role in the quality control and process development of VP4* based rotavirus vaccines and facilitate the development of recombinant rotavirus vaccines.