ABSTRACT
Ensuring complete viral inactivation is critical for the safety of vaccines based on an inactivated virus. Detection of residual infectious virus is dependent on sensitivity of the assay, sample volume analyzed and the absence of interference with viral infection. Here we describe the development and qualification of a sensitive cell-based assay for the detection of residual infectious West Nile Virus (WNV). The results of the assay are in good agreement with the assumption that at low concentrations the number of infectious units in relatively small samples follows a Poisson distribution. The assay can detect 1 infectious unit with a confidence of 99%, provides statistical controls for interference and can easily be scaled up to test large amounts of vaccine material. Furthermore, we show equivalence in sensitivity between the cell-based assay and an in vivo assay for detection of infectious WNV. Finally, the assay has been used for successful release testing of clinical lots of inactivated WNV vaccine. Given the principle and generic setup of the method we envision broad applicability to the detection of very low concentrations of infectious virus.
Subject(s)
Propiolactone/pharmacology , Vaccines, Inactivated , Virus Inactivation , West Nile Virus Vaccines , West Nile virus/pathogenicity , Animals , Animals, Suckling , Cell Line , Chlorocebus aethiops , Disease Models, Animal , Mice , Mice, Inbred C3H , Vero Cells , West Nile Fever/mortality , West Nile Fever/virology , West Nile virus/drug effects , West Nile virus/isolation & purification , West Nile virus/physiologyABSTRACT
Influenza viruses for vaccine production are currently grown on embryonated eggs. This manufacturing system conveys many major drawbacks such as inflexibility, cumbersome down stream processing, inability of some strains to replicate on eggs to high enough yields, and selection of receptor-binding variants with reduced antigenicity. These limitations emphasize the need for a cell line-based production system that could replace eggs in the production of influenza virus vaccines in a pandemic proof fashion. Here we present the efficient propagation of influenza A and B viruses on the fully characterized and standardized human cell line PER.C6.