Mechanism and application of a microcapsule enabled multicatalyst reaction.

In this paper, we describe the development and application of a multistep one-pot reaction that is made possible by the site isolation of two otherwise incompatible catalysts. We prepared a microencapsulated amine catalyst by interfacial polymerization and used it in conjunction with a nickel-based catalyst for the transformation of an aldehyde to a Michael adduct via a nitroalkene intermediate. The amine-catalyzed conversion of an aldehyde to a nitroalkene was found to proceed through an imine rather than a nitroalcohol. Kinetic studies indicated that the reaction is first order in both the nickel catalyst and the shell of the encapsulated amine catalyst. Furthermore, we provide evidence against interaction between amine and nickel catalysts and present kinetic data that demonstrates that there is a rate enhancement of the Michael addition due to the urea groups on the surface of the microencapsulated catalyst. We applied our one-pot reaction to the development of a new synthetic route for pregabalin that proceeds with an overall yield of 74%.

Microcapsule enabled multicatalyst system.

We present a new microencapsulated catalyst and report its use in a tandem multicatalyst reaction. Using an encapsulation technique, we developed an active, site-isolated amine catalyst that is capable of catalyzing the addition of nitromethane to an aldehyde. When a second Lewis acid catalyst is added, the nitroalkene intermediate is trapped and converted to the corresponding Michael adduct. We show that if the amine catalyst is not encapsulated, the two catalysts cannot function together. Moreover, if the two reactions are performed in sequence rather than in tandem, the first reaction results in an undesired dinitro product and the desired Michael adduct is not formed.

Removable colored coatings based on calcium alginate hydrogels.

This article describes the creation of a nontoxic, biodegradable coating using calcium alginate and FD&C approved dyes. The coating is robust but is rapidly removed upon treatment with disodium ethylenediamine tetraacetate (EDTA). Dye leaching from calcium alginate films was studied, and it was determined that the efficiency of dye retention is proportional to the degree of cross-linking. Degradation rates were studied on calcium alginate beads serving as a model for a coating. We determined that degradation rates depend on the gel's cross-linking and on the amount of EDTA used. Bead size also influenced the degradation rates; smaller beads degraded faster than larger beads. We show that the coating can be used as an easily removable and environmentally friendly logotype on an artificial turf surface. Applications of these coatings can be extended to food, cosmetic, medicinal, and textile uses and to wherever nontoxic, easily removable colored coating is desired.

One-pot multi-step synthesis: a challenge spawning innovation.

Creating one-pot synthetic routes is a challenge that is already spawning new chemistry, enzymes, materials, and mechanistic insight. Through one-pot reactions, the chemical products that add value to our lives can be produced with less waste and greater economic benefits. Within this Emerging Area, we describe models for designing one-pot reactions as well as advanced catalysts created to facilitate their realization.

Residual structure in the repeat domain of tau: echoes of microtubule binding and paired helical filament formation.

The microtubule-associated protein tau is found aggregated into paired helical filaments in the intraneuronal neurofibrillary tangle deposits of victims of Alzheimer's disease (AD) and other related dementias. Tau contains a repeat domain consisting of three or four 31-32-residue imperfect repeats that forms the core of tau filaments and is capable of self-assembling into filaments in vitro. We have used high-resolution NMR spectroscopy to characterize the structural properties of the three-repeat domain of tau at the level of individual residues. We find that three distinct regions of the polypeptide corresponding to previously mapped microtubule interaction sites exhibit a preference for helical conformations, suggesting that these sites adopt a helical structure when bound to microtubules. In addition, we directly observe a marked preference for extended or beta-strand-like conformations in a stretch of residues between two of the helical regions, which corresponds closely to a region previously implicated as an early site of beta-strand structure formation and intermolecular interactions leading to paired helical filament (PHF) formation. This observation supports the idea that this region of the protein plays a crucial role in the formation of tau aggregates. We further show that disulfide-bond-mediated dimer formation does not affect and is not responsible for the observed structural preferences of the protein. Our results provide the first high-resolution view of the structural properties of the protein tau, are consistent with an important role for beta structure in PHF formation, and may also help explain recent reports that tau filaments contain helical structure.