Design and Synthesis of α-Anomeric Diacetylene-Containing Glycosides as Photopolymerizable Molecular Gelators.

Glycolipids with diacetylene functional groups are fascinating compounds with many practical uses. Among these, diacetylene-containing gelators are especially important because they can form photopolymerizable gels, which are useful stimuli-responsive materials. Inspired by the unique properties of diacetylene-containing gelators and to understand the structural influences especially the location of the diacetylene functional groups on the self-assembling properties, a series of 15 novel N-acetyl-d-glucosamine derivatives with the diacetylene functional group introduced at the anomeric position were designed and synthesized. The diacetylene function is attached to the sugar through α-glycosylation with the distance from the anomeric oxygen being varied from one, two, and three methylene groups, and the other side contains hydroxyl, carboxyl, phenyl, and alkyl substituents. Remarkably, all compounds can form self-assembled gels in one or more selected solvents. A majority of these synthesized diacetylene glycosides are effective gelators for ethanol/water (v/v 1:1), dimethyl sulfoxide/water (v/v 1:1), and toluene, and one compound also formed a hydrogel at 1.0 wt %. Typically, these glycosides form gels that are photopolymerizable to afford red-colored gels. Scanning electronic microscopy indicated that the gelators formed helices, fibers, and planar sheet-like morphologies. The chemical structures of the derivatives affected their gelation properties and responses to UV treatment. The carboxylic acid-functionalized derivative 17 was able to immobilize basic solutions and form transparent gels. We expect that these diacetylene glycosides especially the hydroxyl and carboxylic acid derivatives will be useful as stimuli-responsive glycolipids for biomedical research.

Synthesis and self-assembling properties of 4,6-O-benzylidene acetal protected D-glucose and D-glucosamine ß-1,2,3-triazole derivatives.

Sugar based low molecular weight gelators (LMWGs) are useful small molecules that can form reversible supramolecular gels with many applications. Selective functionalization of common monosaccharides has resulted in several classes of effective LMWGs. Recently we found that certain peracetylated sugars containing anomeric triazole functional groups were effective gelators. In this study we synthesized two series of 4,6-O-benzylidene acetal protected ß-1,2,3-triazolyl glycoside of D-glucose and N-acetyl D-glucosamine derivatives and evaluated their self-assembling properties in a few solvents. Several gelators were obtained and the gelation properties of these compounds rely on the structures of the 4-triazolyl substituents. Typically, alkyl derivatives resulted in effective gelation in organic solvents and aqueous mixtures of ethanol and dimethyl sulfoxide. But further acetylation of these compounds resulted in loss of gelation properties. The gels were characterized using optical microscopy, rheology, and FTIR spectroscopy. We also analyzed the molecular assemblies, using 1H NMR spectroscopy to probe the influences of the hydroxyl, amide, and triazole functional groups. Naproxen was used as a model drug and it formed co-gels with compound 25 in DMSO water mixtures. Using UV spectroscopy, we found that naproxen was slowly released from the gel to aqueous solution. The general structure and gelation trend obtained here can be useful in designing sugar based biomaterials. We expect that further structural optimization can lead to more effective gelators that are compatible with different drug molecules for encapsulation and sustained release.

Synthesis and gelation property of a series of disaccharide triazole derivatives.

Low molecular weight gelators are important for the study of supramolecular chemistry and have useful applications for biomaterials. Glycomimetics that are easily accessible and have useful gelation properties are especially interesting molecules. In this research, nine per-O-acetyl lactosyl- and thirteen per-O-acetyl maltosyl triazole derivatives were synthesized and analyzed. Most of the maltosyl triazoles and one of the lactosyl derivatives were found to be effective molecular gelators. The supramolecular gels were characterized using rheology and optical microscopy and they exhibited morphologies ranging from fibers to planar sheets. The self-assembling properties of selected lactosyl and maltosyl triazole derivatives were studied using 1H NMR spectroscopy at different temperatures. The NMR studies revealed that the triazole moiety in these compounds played an important role in the formation of the supramolecular assembly, but the sugar moiety configurations are more influential towards gelation. Naproxen and chloramphenicol were used as the model drugs to assess the potential of these compounds in drug delivery applications. A pH responsive gelator showed faster delivery of chloramphenicol at mild basic conditions than neutral conditions. The effective disaccharide triazole-based molecular gelators are useful for the preparation of advanced soft materials that have potential applications as matrix for immobilization of drugs or biomolecules.

Copper-Catalyzed Asymmetric Propargylation of Cyclic Aldimines.

The copper-catalyzed asymmetric propargylation of cyclic aldimines is reported. The influence of the imine trimer to inhibit the reaction was identified, and equilibrium constants between the monomer and trimer were determined for general classes of imines. Asymmetric propargylation of a diverse series of N-alkyl and N-aryl aldimines was achieved with good to high asymmetric induction. The utility was demonstrated by a titanium catalyzed hydroamination and reduction to generate the chiral indolizidines (-)-crispine A and (-)-harmicine.