A Hexapodal Capsule for the Recognition of Anions

We herein describe the preparation, characterization, and recognition characteristics of novel hexapodal capsule 1 composed of two benzenes joined by six hydrogen bonding (HB) groups to encircle space. This barrel-shaped host was obtained by reversible imine condensation of hexakis-aldehyde 2 and hexakis-amine 3 in the presence of oxyanions or halides acting as templates. Fascinatingly, capsule 1 includes 18 HB donating (C-sp(2 )-H and N-H) and 12 HB accepting groups (C=O and C= N) surrounding a binding pocket (78 angstrom(3)). In this regard, the complexation of fluoride, chloride, carbonate, sulfate, and hydrogen phosphate was probed by NMR spectroscopy (DMSO) and X-ray diffraction analysis to disclose the adaptive nature of 1 undergoing an adjustment of its conformation to complement each anionic guest. Furthermore, the rate by which encapsulated chloride was substituted by sulfate or hydrogen phosphate was slow (>7 days) while the stability of [SO4 subset of 1](2-) was greatest in the series with K-a > 10(7) M-1 in highly competitive DMSO. With facile access to 1, the stage is set to probe this modular, polyvalent, and novel host to further improve the extraction of tetrahedral oxyanions from waste and the environment or control their chemistry in living systems.

Automated summary

This study describes the preparation, structure, and recognition capabilities of a novel hexapodal capsule 1. The capsule shows high adaptability in complexation reactions with various anionic guests, with its structure adjusting to complement each guest. Additionally, the stability of sulfate ions within the capsule in competitive DMSO is notable, suggesting potential applications in controlling chemical reactions.