Single radial immunodiffusion as a method for the assay of the acellular pertussis vaccine components, pertussis toxoid, filamentous haemagglutinin and pertactin.

The development of acellular pertussis vaccines has raised a number of issues relevant to the control of these products. Of particular importance is the need for robust and accurate in vitro assays for the antigen content of the vaccines which might contain up to five different antigen components, each of which needs to be independently assayed. This paper describes a simple method for the quantification of three component antigens. Because relatively high doses of purified antigens are used in those preparations, the elimination of residual toxicity is a major concern. This is achieved by genetic modification of chemical treatment. The latter results in modification of the immunological reactivity of the antigens making direct assay by such methods as ELISA ineffective. A single radial diffusion technique using polyclonal antisera for the assay of pertussis toxoid (PTxd), chemically treated filamentous haemagglutinin (FHA) and pertactin (69 kDa) has been developed. The method uses low concentrations of antisera, allowing accurate and reproducible quantification of antigen content as low as 25 microg/ml of protein for pertussis toxoid and filamentous haemagglutinin and 5 microg/ml for pertactin. Since by the addition of detergent, diffusible subunits are produced irrespective of the original physical state of the antigens, the assay is suitable for assay of these antigens after detoxification/or stabilization by chemical treatment and is able to determine the differences between preparations which have the same protein concentration but different antigenic contents. This provides a means for assuring the consistency of the antigens after detoxification/or chemical stabilization which could be used as an in-process control method for acellular pertussis vaccines.     

Evaluation of an in vitro assay system as a potential alternative to current histamine sensitization test for acellular pertussis vaccines

The histamine sensitization test (HIST) is a lethal test for batch release of acellular pertussis or its combination vaccines (ACV). Large numbers of animals have been used and it is difficult to standardize. Therefore there is an urgent need to develop an in vitro alternative to HIST.An in vitro test system has been developed as a potential alternative to HIST, to examine both the functional domains of PT based on a combination of enzyme coupled-HPLC (E-HPLC) and carbohydrate binding assays. We describe here an international collaborative study, which involved sixteen laboratories from 9 countries to assess the methodology transferability of the in vitro test system and its suitability for the testing of three different types of ACV products that are currently used worldwide. This study also evaluated further the relationship between the in vivo activity by HIST and the in vitro assay system.The results showed that the methodology of the E-HPLC and carbohydrate binding assays are transferable between laboratories worldwide and is suitable for the three types of ACV products included in the study. Although direct correlation between the in vitro assay system and the in vivo HIST (temperature reduction assay) for each individual vaccine lot cannot be established due to the large variation in the HIST results, the observation that the mean estimates of the in vitro and in vivo activities gave the same rank order of the three vaccine types included in the study is encouraging. The in vitro systems provide reproducible product specific profiles which supports their use as a potential alternative to the HIST.     

Investigation of an Aerosol Challenge Model as Alternative to the Intracerebral Mouse Protection Test for Potency Assay of Whole Cell Pertussis Vaccines

The current potency test for whole cell pertussis vaccines, the intracerebral mouse protection test, is still the only assay which has shown a correlation with protection in children. However, it has considerable disadvantages as it uses a severe challenge procedure and the results tend to show significant intra- and inter-laboratory variation. An alternative assay based on non-lethal aerosol challenge of mice has been investigated as a replacement for the current intracerebral mouse protection test. Evaluation of this indicated that the aerosol system allowed consistent inoculation of bacteria into mice and gave good reproducibility. The protective capacity of different vaccine preparations was distinguished by this assay. Furthermore, the viable counts of Bordetella pertussis in the lungs of challenged mice were immunisation dose-dependent, which allowed the relative potency of vaccines to be calculated. Comparison of potency of five batches of vaccine from different manufacturers assayed by both the intracerebral and the aerosol challenge methods ranked the vaccines in identical order. The results suggest that this method has potential for use as a potency test for whole cell pertussis vaccine which would result in a great reduction in the number of animals used. It would also replace the lethal challenge by a non-lethal procedure and thereby avoid the use of the severe intracerebral challenge procedure.