项目名称: 基于理论计算的膝沟藻毒素分子印迹固相萃取机理研究
项目编号: No.41506092
项目类型: 青年科学基金项目
立项/批准年度: 2016
项目学科: 天文学、地球科学
项目作者: 连子如
作者单位: 山东大学
项目金额: 20万元
中文摘要: 我国近海的麻痹性贝毒中毒事件,以膝沟藻毒素居多,分子印迹固相萃取技术在分离纯化领域已被广泛应用,在微藻毒素的提纯中则研究较少,其对毒素的固相萃取机理有待研究。因此,开展膝沟藻毒素的提取纯化研究,阐明其分离机理,对保障我国水产品安全和保护人类健康具有重要的理论和实际意义。.本项目拟以分子印迹技术为基础,制备对膝沟藻毒素具有特异性选择吸附能力的分子印迹微球,结合固相萃取技术,利用自制固相萃取柱,对微小亚历山大藻(Alexandrium minutum)有毒藻株中的膝沟藻毒素GTX1,4和GTX2,3进行提取纯化,通过实验优化固相萃取条件,建立一套有效的膝沟藻毒素分子印迹固相萃取方法,同时运用理论计算全局反应路径图方法中的假想力诱导反应揭示该提纯方法的分子识别机制和固相萃取机理,为分子印迹固相萃取微藻毒素提供理论依据,为微藻毒素的分离纯化开辟新的途径,以推动我国微藻毒素领域的深入研究。
中文关键词: 膝沟藻毒素;分子印迹固相萃取;机理研究;理论计算
英文摘要: Recently, poisoning incidents from paralytic shellfish toxins caused by the consumption of shellfish were often reported in China. Gonyautoxins have posed a serious hazard to public health and threatens shellfish aquaculture in the coastal region. Molecularly imprinted solid-phase extraction (MISPE) presents the high specificity, selectivity and sensitivity of the molecular recognition mechanism and the high resolving power of separation methods. However, there has been no reports on the isolation study of gonyautoxins based on MISPE. Molecular recognition and isolation mechanism also need to be investigated. So, solid-phase extraction of gonyautoxins and mechanism study using molecular imprinting technology have important significances to monitor seafood safety and protect the health of consumers.. In this study, a highly selective sample cleanup procedure combined with MISPE will be developed for the isolation of gonyautoxins from Alexandrium minutum extract samples. Molecularly imprinted polymer microspheres will be prepared using the dummy template molecule. The polymer microspheres will be used as a selective sorbent for the solid-phase extraction of GTXs and the MISPE protocols were optimized. An innovative and effective extraction method based on MISPE will be established. In order to get a deeper insight into the recognition mechanism of imprinted polymers adsorbing gonyautoxins and to explain solid-phase extraction process, theoretical calculations based on Artificial Force Induced Reaction of Global Reaction Route Mapping will be employed in the research. The results will offer a sound basis for the high selective isolation of gonyautoxins from the interference matrix. Moreover, the study will open up new ways to effective isolation of marine toxins and promote further study in the field of micro-algae toxins.
英文关键词: Gonyautoxins;Molecularly imprinted solid-phase extraction;Mechanism study;Theoretical calculation