离子-烃和/或离子-离子相互作用：在合成主体中的直接和反转的侯氏效应。

Ion-Hydrocarbon and/or Ion-Ion Interactions: Direct and Reverse Hofmeister Effects in a Synthetic Host.

机构信息

Department of Chemistry , Tulane University , New Orleans , Louisiana 70118 , United States.

出版信息

J Am Chem Soc. 2018 Mar 21;140(11):4092-4099. doi: 10.1021/jacs.8b00196. Epub 2018 Mar 13.

DOI:10.1021/jacs.8b00196

PMID:29533064

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10668597/

Abstract

A combination of H NMR spectroscopy, DLS, and turbidity measurements reveal that polarizable anions engender both the Hofmeister and reverse Hofmeister effects in positand 2. Host 2 possesses two principal and distinctly different binding sites: a "soft" nonpolar pocket and a "hard" crown of ammonium cations. NMR spectroscopy reveals that anion affinity to both sites is comparable, with each site showing characteristic selectivities. NMR spectroscopy also reveals that anions competitively bind to the pocket and induce the Hofmeister effect in host-guest binding at very low concentrations (∼2 mM). Furthermore, the suite of techniques utilized demonstrates that anion binding to both sites leads to charge attenuation, aggregation, and finally precipitation (the reverse Hofmeister effect). Anion-induced precipitation generally correlated with affinity, and comparisons between the free host and its adamantane carboxylate (Ada-CO) complex reveals that the reverse Hofmeister effect is attenuated by blocking anion binding/charge attenuation at the nonpolar pocket.

摘要

NMR 光谱、DLS 和浊度测量的组合表明，可极化阴离子在正离子 2 中产生 Hofmeister 和逆 Hofmeister 效应。主体 2 具有两个主要且明显不同的结合位点：一个“软”非极性口袋和一个“硬”铵阳离子冠。NMR 光谱表明，两个位点对阴离子的亲和力相当，每个位点都表现出特征选择性。NMR 光谱还表明，阴离子竞争性地结合到口袋中，并在非常低的浓度（约 2mM）下诱导主客体结合的 Hofmeister 效应。此外，所使用的一整套技术表明，阴离子结合到两个位点会导致电荷衰减、聚集，最终沉淀（逆 Hofmeister 效应）。阴离子诱导的沉淀通常与亲和力相关，并且自由主体与其金刚烷羧酸酯（Ada-CO）配合物之间的比较表明，通过阻止非极性口袋中阴离子的结合/电荷衰减，逆 Hofmeister 效应会减弱。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/e005/10668597/ee438f564d88/nihms-1944090-f0002.jpg

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