Stafslien Shane J, Bahr James A, Feser Jason M, Weisz Jonathan C, Chisholm Bret J, Ready Thomas E, Boudjouk Philip
Center for Nanoscale Science and Engineering, North Dakota Sate University, 1805 NDSU Research Park Drive, Fargo, North Dakota 58102, USA.
J Comb Chem. 2006 Mar-Apr;8(2):156-62. doi: 10.1021/cc050047m.
Combinatorial, high-throughput capabilities have been established to aid in the rapid development of new and effective antifouling marine coatings for naval applications. A biological screening process involving marine bacteria was developed that allows for rapid and effective quantification of bacterial biofilm growth and retention on large numbers of coating surfaces in parallel. The screening process involves (1) multiwell plate modifications for coating deposition, (2) deposition of combinatorial coating libraries via an automated liquid dispensing robot, (3) coating thickness measurements of cured coatings, (4) preconditioning of coatings via immersion in deionized water, (5) bacterial incubation, (6) plate processing, and (7) data analysis for identification of promising candidates. The details of the method developed are described in this document.
已建立组合式高通量能力,以助力快速开发用于海军应用的新型高效防污海洋涂层。开发了一种涉及海洋细菌的生物筛选方法,该方法能够并行快速有效地量化细菌生物膜在大量涂层表面上的生长和附着情况。筛选过程包括:(1)对多孔板进行改性以沉积涂层;(2)通过自动液体分配机器人沉积组合涂层库;(3)测量固化涂层的厚度;(4)将涂层浸入去离子水中进行预处理;(5)细菌培养;(6)平板处理;(7)数据分析以识别有潜力的候选涂层。本文档描述了所开发方法的详细内容。