压力灭活的黄热病17DD病毒：对疫苗研发的启示

Pressure-inactivated yellow fever 17DD virus: implications for vaccine development.

作者信息

Gaspar Luciane P, Mendes Ygara S, Yamamura Anna M Y, Almeida Luiz F C, Caride Elena, Gonçalves Rafael B, Silva Jerson L, Oliveira Andréa C, Galler Ricardo, Freire Marcos S

机构信息

Programa de Vacinas Virais, Instituto de Tecnologia em Imunobiológicos, Fundação Oswaldo Cruz, Rio de Janeiro, RJ, Brazil.

出版信息

J Virol Methods. 2008 Jun;150(1-2):57-62. doi: 10.1016/j.jviromet.2008.03.002.

DOI:10.1016/j.jviromet.2008.03.002

PMID:18420285

Abstract

The successful Yellow Fever (YF) vaccine consists of the live attenuated 17D-204 or 17DD viruses. Despite its excellent record of efficacy and safety, serious adverse events have been recorded and influenced extensive vaccination in endemic areas. Therefore, alternative strategies should be considered, which may include inactivated whole virus. High hydrostatic pressure has been described as a method for viral inactivation and vaccine development. The present study evaluated whether high hydrostatic pressure would inactivate the YF 17DD virus. YF 17DD virus was grown in Vero cells in roller bottle cultures and subjected to 310MPa for 3h at 4 degrees C. This treatment abolished YF infectivity and eliminated the ability of the virus to cause disease in mice. Pressure-inactivated virus elicited low level of neutralizing antibody titers although exhibited complete protection against an otherwise lethal challenge with 17DD virus in the murine model. The data warrant further development of pressure-inactivated vaccine against YF.

摘要

成功的黄热病（YF）疫苗由减毒活17D - 204或17DD病毒组成。尽管其在有效性和安全性方面有着出色的记录，但仍有严重不良事件被记录下来，并影响了流行地区的广泛疫苗接种。因此，应考虑替代策略，这可能包括灭活全病毒。高静水压已被描述为一种病毒灭活和疫苗开发的方法。本研究评估了高静水压是否会使YF 17DD病毒灭活。YF 17DD病毒在滚瓶培养的Vero细胞中生长，并在4℃下承受310MPa压力3小时。这种处理消除了YF的传染性，并消除了病毒在小鼠中致病的能力。压力灭活病毒引发的中和抗体滴度水平较低，尽管在小鼠模型中对17DD病毒的致死性攻击表现出完全的保护作用。这些数据为进一步开发针对黄热病的压力灭活疫苗提供了依据。

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压力灭活的黄热病17DD病毒：对疫苗研发的启示

Pressure-inactivated yellow fever 17DD virus: implications for vaccine development.

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