Dynamic combinatorial chemistry (DCC) is a powerful method for synthesising complex molecules and identifying unexpected receptors. Chapter 1 gives an overview of the concept of DCC and its applications, and discusses its evolution to date.Chapter 2 describes the discovery of a new generation of donor-acceptor [2]catenanes in aqueous dynamic combinatorial systems. The assembly of these [2]catenanes is promoted by a high salt concentration (1 M NaNO3), which raises the ionic strength and encourages hydrophobic association. More importantly, a mechanism that explains and predicts the structures formed is proposed, giving a fundamental insight into the role played by hydrophobic effect and donor-acceptor interactions in this process. Building on these results, Chapter 3 describes the assembly in high salt aqueous libraries of a larger structure: a [3]catenane. Remarkably, the [3]catenane exhibits strong binding interactions with a biologically relevant target – spermine – in water under near-physiological conditions. Its synthesis is improved if the salt is replaced by a sub-mM concentration of spermine, acting as a template. Chapter 4 explores in further detail how subtle variations in the building block design influence the selective formation of either [2] or [3]catenanes. This last section underlines both the advantages and the limitations of the method developed in Chapter 3. After a short conclusion (Chapter 5), Chapter 6 gives experimental details.
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机译:动态组合化学(DCC)是一种合成复杂分子并识别意外受体的有力方法。第1章概述了DCC的概念及其应用,并讨论了其发展历程。第2章介绍了在水性动态组合系统中发现新一代供体-受体[2]邻苯二酚的方法。高盐浓度(1 M NaNO3)促进了这些[2]儿茶酚的组装,从而提高了离子强度并促进了疏水缔合。更重要的是,提出了一种解释和预测所形成结构的机制,从而对疏水作用和供体-受体相互作用在该过程中所起的作用提供了基本的认识。在这些结果的基础上,第3章介绍了在较大结构的高盐水溶液文库中的组装:[3]环烷。值得注意的是,[3]环戊烷在接近生理条件下的水中与生物相关靶标-精胺具有很强的结合相互作用。如果将盐替换为亚mM浓度的精胺(用作模板),则会改善其合成。第4章进一步探讨了构建模块设计中的细微变化如何影响[2]或[3]邻苯二酚的选择性形成。最后一部分强调了第3章中开发的方法的优点和局限性。简短总结(第5章)后,第6章提供了实验细节。
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