Chiral recognition by supramolecular porphyrin-hemicucurbit[8]uril-functionalized gravimetric sensors

Enantiorecognition of a chiral analyte usually requiresthe abilityto respond with high specificity to one of the two enantiomers ofa chiral compound. However, in most cases, chiral sensors have chemicalsensitivity toward both enantiomers, showing differences only in theintensity of responses. Furthermore, specific chiral receptors areobtained with high synthetic efforts and have limited structural versatility.These facts hinder the implementation of chiral sensors in many potentialapplications. Here, we utilize the presence of both enantiomers ofeach receptor to introduce a novel normalization that allows the enantio-recognitionof compounds even when single sensors are not specific for one enantiomerof a target analyte. For this purpose, a novel protocol that permitsthe fabrication of a large set of enantiomeric receptor pairs withlow synthetic efforts by combining metalloporphyrins with (R,R)- and (S,S)-cyclohexanohemicucurbit[8]uril is developed. The potentialitiesof this approach are investigated by an array of four pairs of enantiomericsensors fabricated using quartz microbalances since gravimetric sensorsare intrinsically non-selective toward the mechanism of interactionof analytes and receptors. Albeit the weak enantioselectivity of singlesensors toward limonene and 1-phenylethylamine, the normalizationallows the correct identification of these enantiomers in the vaporphase indifferent to their concentration. Remarkably, the achiralmetalloporphyrin choice influences the enantioselective properties,opening the way to easily obtain a large library of chiral receptorsthat can be implemented in actual sensor arrays. These enantioselectiveelectronic noses and tongues may have a potential striking impactin many medical, agrochemical, and environmental fields

Propanediurea-Based Molecular Clips Bind Halide Anions: An Insight into the Mechanism of Cucurbituril Formation

The synthesis and supramolecular properties of the first methylene-bridged propanediurea-based dimers are described. These dimers, bearing an aromatic sidewall, have the shape of molecular clips. Unlike glycoluril-based dimers, these clips neither dimerize nor accept any organic guests, due to their small cavities. Both propanediurea- and glycoluril-based dimers bind halide anions on the convex side of the molecules, even in highly polar organic solvents. This observation brings new insights into the mechanism of cucurbituril formation

A Cucurbituril Derivative That Exhibits Cation-Modulated Self-Assembly

Cucurbiturils are the most potent artificial receptors known for many organic molecules in water. However, little is known about their supramolecular chemistry in organic solvents. Here we present a new cucurbituril derivative, <b>1</b>, and investigate its supramolecular properties in methanol. The macrocycle resembles a five-membered cucurbituril in which four glycoluril units are replaced with propanediurea. Macrocycle <b>1</b> can bind to one cation such as potassium or anilinium via each of its opposed portals. The stability of these complexes in methanol at nanomolar concentrations exceeds that of complexes between metal cations and crown ethers. Moreover, macrocycle <b>1</b> forms a self-assembled tetrameric aggregate in the solid state and in methanol. The tetramer is stabilized by the addition of up to 1 equiv of a cation but is fully disassembled in the presence of 2 equiv of the cation. Cations can thus be used to tune the aggregation of <b>1</b> in solution

A Cucurbituril Derivative That Exhibits Cation-Modulated Self-Assembly

Cucurbiturils are the most potent artificial receptors known for many organic molecules in water. However, little is known about their supramolecular chemistry in organic solvents. Here we present a new cucurbituril derivative, <b>1</b>, and investigate its supramolecular properties in methanol. The macrocycle resembles a five-membered cucurbituril in which four glycoluril units are replaced with propanediurea. Macrocycle <b>1</b> can bind to one cation such as potassium or anilinium via each of its opposed portals. The stability of these complexes in methanol at nanomolar concentrations exceeds that of complexes between metal cations and crown ethers. Moreover, macrocycle <b>1</b> forms a self-assembled tetrameric aggregate in the solid state and in methanol. The tetramer is stabilized by the addition of up to 1 equiv of a cation but is fully disassembled in the presence of 2 equiv of the cation. Cations can thus be used to tune the aggregation of <b>1</b> in solution

A Cucurbituril Derivative That Exhibits Cation-Modulated Self-Assembly

Cucurbiturils are the most potent artificial receptors known for many organic molecules in water. However, little is known about their supramolecular chemistry in organic solvents. Here we present a new cucurbituril derivative, <b>1</b>, and investigate its supramolecular properties in methanol. The macrocycle resembles a five-membered cucurbituril in which four glycoluril units are replaced with propanediurea. Macrocycle <b>1</b> can bind to one cation such as potassium or anilinium via each of its opposed portals. The stability of these complexes in methanol at nanomolar concentrations exceeds that of complexes between metal cations and crown ethers. Moreover, macrocycle <b>1</b> forms a self-assembled tetrameric aggregate in the solid state and in methanol. The tetramer is stabilized by the addition of up to 1 equiv of a cation but is fully disassembled in the presence of 2 equiv of the cation. Cations can thus be used to tune the aggregation of <b>1</b> in solution

Cyclohexanohemicucurbit[8]uril forms inclusion complexes with heterocycles and removes sulfuric guests from water via solid-phase extraction

We found that cyclohexanohemicucurbit[8]uril encapsulates five- and six-membered sulfur- and oxygen-containing unsubstituted heterocycles and can be used as a selective sorption material for the extraction of sulfur-heterocycles like 1,3-dithiolane and α‑lipoic acid from water