水产动物口服疫苗的研究进展

doi:10.13560/j.cnki.biotech.bull.1985.2017-0805

摘要/Abstract

摘要： 疫苗的使用能够有效地提高水产动物对水产常见疾病的抵抗力，减少疾病的发生与传染，减少化学类药物的使用，降低对环境的污染程度，减少治理环境的经济损失。其中注射疫苗费时费力，易损伤鱼体；浸泡疫苗需要量大，易产生强应激反应；而口服疫苗能够适用于各种体型的鱼类，避免了注射和浸泡两种接种方式存在的问题，是较为理想的免疫方式。目前水产口服疫苗中，聚合微球体和生物被膜制备的佐剂疫苗可使抗原成分免受各种消化酶类影响而被广泛应用，但在实际生产中的使用成本较高。通过非致病性的微生物如细菌等来表达疫苗中的抗原成分，制备而成的生物载体疫苗，使用成本低，免疫效果好，但安全性评价周期长，大规模批量化生产有难度。综述了几种主要的水产口服疫苗的现状和关键技术，在未来的工作中应重点解决疫苗安全性、临床适用性等问题，研制出生产成本低、免疫效果好的口服疫苗。

关键词: 水产动物, 免疫, 口服, 疫苗, 形式

Abstract: The application of vaccines may effectively improve their resistances against various common diseases in aquaculture，thus decrease the possibility of the incidence of diseases and infections，reduce the use of chemical drugs，eliminate the environmental pollution，and even decrease economic losses from environmental governances. Vaccination by injection is time-consuming and easily causes injuries to fishes. Vaccination by immersion needs high dosages and thus easily results in strong stress reaction. The oral vaccine can be applied to any variety and size of fish，thus may avoid the problems by injection or immersion，and it is an ideal immune approach. Among the present oral vaccines，the adjuvants like polymeric microspheres and biofilm used to prevent the antigens in vaccine from the effects of all digestive enzymes are widely applied；however，the cost is quite high in field application. Biological carrier can be a genetic engineering vaccine with antigens delivery work by non-pathogenic microorganisms，such as bacteria. These biological carrier vaccines are actually in low costs for application and induce a solid immunization effect，however，the cycle of safety evaluation is long and there is difficulty in large-scale production. This paper reviews the status and key technologies of different forms and formulations of main oral vaccines. Also the paper prospects that the study on aquatic animal oral vaccines should focus on vaccine safety and applicability in the future research work，and developing oral vaccine simultaneously in lower cost and better immunization effect.

Key words: aquatic animal, immunity, oral, vaccine, forms

刘世旭 ,王庆 ,方珍珍 ,常藕琴 ,曾伟伟 ,黄志斌. 水产动物口服疫苗的研究进展[J]. 生物技术通报, 2018, 34(6): 30-37.

LIU Shi-xu ,WANG Qing ,FANG Zhen-zhen ,CHANG Ou-qin ,ZENG Wei-wei ,HUANG Zhi-bin. Research Advance on Oral Vaccine for Aquatic Animals[J]. Biotechnology Bulletin, 2018, 34(6): 30-37.

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