Host-guest sensing by calixarenes on the surfaces

The present critical review reports on recent developments of optical nanoparticles based on the association of gold, silver, silica and quantum dots and calixarenes. These hybrid organic-inorganic compounds characterized by a thick organic layer self-assembled on the surface of a core of mineral surface atoms take advantage of the supramolecular recognition of luminescent calixarenes to fabricate nanodevices of nanoparticle size, capable of detecting metal cations, polyaromatic hydrocarbons and pesticides. Also presented is an explanation of the involvement of such nanoparticles in biochemical systems. This critical review provides an overview of their preparation, the manner in which they are characterized, and their use (108 references).

Chiral recognition of dextran sulfate with d- and l-cystine studied by multiwavelength surface plasmon resonance

A multiwavelength surface plasmon resonance (mwSPR) approach has been developed to study the chiral discrimination between D- and L-cystine (Cys). A monolayer of the two enantiomers was separately assembled on a pair of gold films of about 50 nm in thickness and their resonance wavelength shifts, Deltalambda, were measured under a continuous flow of an identical chiral probe solution. Dextran sulfate (DS) was found to be an excellent chiral probe because it has rich chiral centers and is large enough to produce sensitive mwSPR response. The chiral discrimination was investigated either by Deltalambda(max), the maximum resonance wavelength shift in recognition equilibrium, or by recognition kinetics (Deltalambda vs time). The equilibrium data showed that D-Cys yielded always the smaller Deltalambda(max) as compared to L-Cys at pH 5.0 or above. This differentiation was enlarged by raising the probe content and became naught at pH <4.5. The kinetic results showed that, as pH increased from 5.0 to 7.5, the non-equilibrium Deltalambda for D-Cys rose above the level for L-Cys at the first 30s of recognition but came back gradually to its equilibrium position after about 150 s, with crossing at 50--150 s depending on DS concentration. This phenomenon was thought to be the result of molecular orientation adjustment after DS binding to D-Cys. Both kinetic and thermodynamic mechanisms were thus considered to be deeply involved in the investigated chiral recognition system.