Guest inclusion by native cyclodextrins in solid state and solutions: A review.

In many industrial applications, preparation of cyclodextrin (CD) inclusion complexes with drugs, food additives, dyes and components of essence oils is performed in solid mixtures, slurries or paste-like systems having lack of water to dissolve cyclodextrin and guest completely. Such systems need a different description than supplied by classical analysis of CD complexation in aqueous solutions. The main feature of solid-state guest inclusion is the phase transition from solid CD to solid inclusion compound.

Determination of Melting Parameters of Cyclodextrins Using Fast Scanning Calorimetry.

The first evidence of native cyclodextrins fusion was registered using fast scanning calorimetry (FSC) with heating rates up to 40,000 K s. The endothermal effects, detected at low heating rates, correspond to the decomposition processes. Upon the increase of the heating rate the onset of these effects shifts to higher temperatures, reaching a limiting value at high heating rates.

Smart Molecular Recognition: From Key-to-Lock Principle to Memory-Based Selectivity.

The formation and decomposition of inclusion compounds with a solid-solid phase transition may be very selective to the guest molecular structure. This selectivity may function in essentially different ways than defined by the classical concept of molecular recognition, which implies the preferential binding of complementary molecules. Solid inclusion compounds may take part as an initial or/and final state in several processes of different types summarized in this review, which selectivity is boosted by cooperativity of participating molecular crystals.

Smart control of guest inclusion by α-cyclodextrin using its hydration history.

Hydration history was found to control the inclusion capacity of α-cyclodextrin (aCD) for volatile organic guests, so that its level may be switched from zero to the stoichiometric value and back by the variation of aCD hydration/dehydration order and direction. Such variation of the inclusion capacity is caused by the balance of two water roles: the activation of guest inclusion and guest/water competition. These observed concurrent roles and the cooperativity of guest inclusion and hydration make possible the smart tuning of the guest inclusion by the subtle change of preparation procedure.

Size exclusion effect in binary inclusion compounds of α-cyclodextrin.

The size exclusion of guests by α-cyclodextrin (aCD) in binary host-guest systems was observed to be a key structure-property relationship for the choice of this host as a receptor. For this, vapor sorption isotherms of water and volatile organic compounds were determined using dry aCD, which show an inclusion threshold by sorbate activity corresponding to a phase transition of guest (or water) inclusion. These phase transitions were also characterized using X-ray powder diffractograms.

Unusually high efficiency of β-cyclodextrin clathrate preparation by water-free solid-phase guest exchange.

An effective preparation procedure is offered for β-cyclodextrin (bCD) clathrates with volatile guests of moderate hydrophilicity, which otherwise require a finely tuned optimization of the bCD/water/guest ratio. The proposed procedure includes guest exchange in a water-free bCD matrix. As a result, more stable clathrates with a higher inclusion capacity can be prepared than by direct saturation of dried or hydrated bCD.