On the connection between nonmonotonic taste behavior and molecular conformation in solution: The case of rebaudioside-A.

The diterpene steviol glycoside, rebaudioside A, is a natural high potency non-caloric sweetener extracted from the leaves of Stevia rebaudiana. This compound shows a parabolic change in sweet taste intensity with temperature which contrasts with the general finding for other synthetic or natural sweeteners whose sweet taste increases with temperature. The nonmonotonic taste behavior was determined by sensory analysis using large taste panels. The conformational landscape of rebaudioside A was established at a range of temperatures by means of nuclear magnetic resonance and molecular dynamics simulation. The relationship between various conformations and the observed sweetness of rebaudioside A is described.

Oxime decorated cavitands functionalized through solvent-assisted grinding.

In order to assemble supramolecular capsules, there is a need for reliable and effective synthetic methods for decorating cavitand-based host structures with appropriate functional groups. The synthesis of four different cavitands of significantly different depth and interior volume functionalized with four aldoxime groups capable of forming homomeric or heteromeric capsules through hydrogen bonding is reported. The final step in each synthesis, the aldehyde to oxime transformation, has been achieved in excellent yields through 'solvent assisted grinding'.

Facile synthesis and supramolecular chemistry of hydrogen bond/halogen bond-driven multi-tasking tectons.

Hydrogen bonds and halogen bonds can be used as synthetic vectors without structural interference as long as the primary molecular recognition events are designed around a careful combination of geometric and electrostatic complementarity. In addition, a one-step procedure for the synthesis of tectons equipped with powerful hydrogen- and halogen-bond donors is presented.

Halogen bonding or close packing? Examining the structural landscape in a series of Cu(II)-acac complexes.

A series of four bifunctional ligands based on ß-diketonate moieties bearing methyl (2), chloro (3), bromo (4) and iodo (5) substituents and their corresponding Cu(II) complexes have been synthesized and crystallographically characterized in order to explore the possibility of using halogen bonds for the directed assembly of predictable architectures in coordination chemistry. The four ligands have characteristic O-H···O intramolecular hydrogen bonds and the structure of ligand 2 is close packed whereas, ligands 3, 4 and 5 contain extended 1-D architectures based on C=O···X halogen bonds. In each case, the halogen-bond donor seeks out the most powerful halogen-bond acceptor (based on electrostatic considerations). In the corresponding Cu(II) complexes the coordination chemistry remains a constant throughout the series, the four-coordinate metal ion sits in a slightly distorted square-planar arrangement, and there are no unexpected appearances of coordinated or non-coordinated solvent molecules. Furthermore, the most powerful halogen-bond acceptors have been almost depleted of charge as a result of metal chelation and none of the potential halogen-bond interactions are capable of competing with the head-to-head close packing that is observed in the methyl, chloro, and bromo, substituted Cu(II) complexes. The enhanced polarizability of the iodine atom, produces a more electropositive surface which means that this structure cannot accommodate a linear head-to-head arrangement due to electrostatic repulsion, and thus [Cu(5)(2)] adopts a unique close-packed structure very different from the other three iso-structural complexes, [Cu(2)(2)]-[Cu(4)(2)].