Molecular Imprinting of Cyclodextrin Supramolecular Hydrogels Improves Drug Loading and Delivery.

Cyclodextrin-based controlled delivery materials have previously been developed for controlled release of different therapeutic drugs. In this study, a supramolecular hydrogel made from cyclodextrin-based macromonomers is subjected to molecular imprinting to investigate the impact on release kinetics and drug loading, when compared with non-imprinted, or alternately imprinted hydrogels. Mild synthesis conditions are used to molecularly imprint three antibiotics-novobiocin, rifampicin, and vancomycin-and to test two different hydrogel chemistries. The release profile and drug loading of the molecularly imprinted hydrogels are characterized using ultraviolet spectroscopy over a period of 35 days and compared to non-imprinted, and alternately imprinted hydrogels. While only modest differences are observed in the release rate of the antibiotics tested, a substantial difference is observed in the total drug-loading amount possible for hydrogels releasing drugs which has been templated by those drugs. Hydrogels releasing drugs which are templated by other drugs do not show improved release or loading. Analysis by FTIR does not show substantial incorporation of drug into the polymer. Lastly, bioactivity assays confirmed long-term stability and release of incorporated antibiotics.

Pseudopolyrotaxane Formation in the Synthesis of Cyclodextrin Polymers: Effects on Drug Delivery, Mechanics, and Cell Compatibility.

Numerous groups have reported the use of cyclodextrin (CD)-based polymers for drug delivery applications due to their capacity to form inclusions with small molecule drugs, delaying the rate of drug release beyond that of diffusion alone (termed "affinity-based" drug delivery). Herein we demonstrate synthesis and characterization of a new family of CD-based polymers, some as pseudopolyrotaxanes, generated under mild (aqueous, room temperature) conditions. The formation of these new affinity polymers results in broad mechanical properties. Three diglycidylether cross-linkers which vary in length from 0 to 10 ethylene glycol units were examined. Pseudopolyrotaxane formation was found only with the highest-length cross-linker, noted first by a sharp change in both material properties and then confirmed by chemical signature. Materials were thoroughly evaluated by NMR, DSC, DMA, TGA, XRD, and FTIR. Cross-linker choice was also tested for impact on drug loading and delivery capacity, using antibiotics as model drugs. Chemically similar polymers without showing affinity rapidly saturated in loading experiments, while affinity materials showing high capacity for drug loading, even beyond the solubility limit of the drugs. When using the polymers with these new cross-linkers, affinity-based drug delivery is maintained: the materials are capable of antibiotic delivery, and clearance of Staphylococcus aureus, at least an order of magnitude better than diffusion-only control polymers. In cell compatibility studies, CD-based polymers were shown to have low overt cell toxicity and even resisted cell adhesion, presumably due to their highly hydrated state.