使用磺化硅胶进行功能化反式环辛烯的大规模流动光化学合成。
Large-Scale Flow Photochemical Synthesis of Functionalized trans-Cyclooctenes Using Sulfonated Silica Gel.
作者信息
Darko Ampofo, Boyd Samantha J, Fox Joseph M
机构信息
Department of Chemistry, University of Tennessee, Knoxville, TN, 37996.
Department of Chemistry and Biochemistry, University of Delaware, Newark DE 19716.
出版信息
Synthesis (Stuttg). 2018 Dec;50(24):4875-4882. doi: 10.1055/s-0037-1610240.
Abstract
Functionalized -cyclooctenes are useful bioorthogonal reagents that are typically prepared using a flow photoisomerization method where the product is captured by AgNO on silica gel. While this method is effective, the leaching of silver can be problematic when scaling up syntheses. It is shown here that Ag(I) immobilized on tosic silica gel can be used to capture -cyclooctene products at higher loadings without leaching. It is demonstrated that the sulfonated silica gel can be regenerated and reused with similar yields over multiple runs. Nine different -cyclooctenes were synthesized, including those commonly utilized in bioorthogonal chemistry as well as new amine and carboxylic acid derivatives.
摘要
官能化的环辛烯是有用的生物正交试剂,通常采用流动光异构化方法制备,产物在硅胶上被硝酸银捕获。虽然这种方法有效,但放大合成时银的浸出可能会有问题。本文表明,负载在对甲苯磺酸硅胶上的Ag(I)可用于在更高负载量下捕获环辛烯产物而无浸出。结果表明,磺化硅胶可多次再生和重复使用,产率相似。合成了九种不同的环辛烯,包括生物正交化学中常用的那些以及新的胺和羧酸衍生物。
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