真菌毒素具有细胞毒性、生殖毒性和免疫毒性，由其导致的农畜产品安全问题引发全球关注。目前在真菌毒素免疫学检测中普遍使用真菌毒素标准品或偶联毒素，给操作人员和环境造成严重的二次污染。为解决该问题，本项目以真菌毒素单克隆抗体为靶标，采用SELEX技术，分别筛选模拟4种真菌毒素表位的特异性单链DNA核酸适配子；应用SPR技术评估适配子的特异性、亲和力、解离常数，并解析其构象特征；通过核苷酸定点突变探索适配子的核心功能域，根据功能域寡核苷酸组成进行相应的化学修饰，获得更稳定、特异的适配子；将适配子与适配子、适配子与生物分子进行嵌合，构建模拟多种真菌毒素的嵌合适配子，进而替代相应的真菌毒素，建立基于免疫学原理的真菌毒素检测体系：实时快速的寡核苷酸免疫层析法、痕量的免疫磁酶分析法、高通量的寡核苷酸液相芯片等，创建真菌毒素的无毒、环保检测平台，为保障农畜产品安全和环境友好提供新的技术支持，项目具有原创性。

Mycotoxins are secondary metabolites mainly produced by different fungal species when they contaminate in different agro-products. They occur frequently in various food and feed commodities globally, leading to animal and human health risks and causing global concern on the food safety issues. More than four hundred mycotoxins have been identified and reported and the key important mycotoxins which are highly prevalent in the contaminated agro-food products are aflatoxins (AFs), deoxynivalenol (DON), fumonisins (FBs), zearalenone(ZEN), etc. Most mycotoxins are immunosuppressive agents and some are carcinogens, hepatotoxins, nephrotoxins, neurotoxins and reproductive toxicity. Accurate monitoring is the best way to control and reduce mycotoxin exposure. However, in the process of immunoassay monitoring, mycotoxins and conjugated toxin are still widely used as standard analytes or competitive antigen, which could harm the operators and contaminate the environment as the secondary pollution. .So, this project employ the SELEX (systematic evolution of ligands by exponential enrichment ) technology to screen the aptamers which can mimic the epitopes of aflatoxin B1/M1,zearalenone, fumonisin B1, and deoxynivalenol, etc., respectively. The targets are the F(ab)2 fragments of the specific monoclonal antibody against the mycotoxin. The aptamers characteristics such as the specificity, affinity, Kd, stability, conformational were analyzed using the surface plasmon resonance technique. The core functional domain will be determined using site-directed mutation approach. And then the site specified chemical modification will be carried out to improve the stabilities of the aptamers. Chimeric aptamer will be constructed employing many different possible types of chimerization strategies to generate more stable and efficient aptamers with aptamer–aptamer, aptamer–biomacromolecules and aptamer–nanoparticle. These reconstructed chimeras can mimic several different mycotoxins epitopes. The enzyme-linked oligonucleotide assays (ELONA) were developed using the single or chimeric aptamers which could replace the mycotoxins and conjugated toxins. Moreover, based on the ELONA, series of analytical methods, including immunochromatographic assay, immunomagnetic assay, and suspension array will be prepared, which have the advantages of rapidity, high sensitivity, and high-throughput, respectively. These methods can meet the needs for different purpose and different samples. A hypotoxic, environmental friendly testing platform will be built for the analysis of mycotoxins and other low weight molecules which having toxicity and harmful for human and animal. This project will establish a new immunological detection direction and provide strong technical supports for food safty.