Structural versatility of oxalamide-based compounds: a computational study on the isomerization of the oxalamide group and the structural preferences of the polyoxalamides

Quinoline-based antimalarial hybrid compounds

Quinoline-containing compounds, such as quinine and chloroquine, have a long-standing history as potent antimalarial agents. However, the increasing resistance of the Plasmodium parasite against these drugs and the lack of licensed malaria vaccines have forced chemists to develop synthetic strategies toward novel biologically active molecules. A strategy that has attracted considerable attention in current medicinal chemistry is based on the conjugation of two biologically active molecules into one hybrid compound. Since quinolines are considered to be privileged antimalarial building blocks, the synthesis of quinoline-containing antimalarial hybrids has been elaborated extensively in recent years. This review provides a literature overview of antimalarial hybrid molecules containing a quinoline core, covering publications between 2009 and 2014.

Methoxyoxalamido chemistry in the synthesis of novel amino linker and spacer phosphoramidites: a robust means for stability, structural versatility, and optimal tether length

We have developed a general route to the synthesis of novel amino linker and spacer phosphoramidites utilizing methoxyoxalamido (MOX) chemistry. The synthesis makes use of readily available and inexpensive primary aliphatic amino alcohols and diamines to produce a rich and diverse variety of phosphoramidites. Among these are monomers with exceptionally long (up to 56 atoms in length) amphipathic tethering arms. The chemistry bestows exceptional control over the physical characteristics within the tethers through the selection of appropriate building blocks. Furthermore, MOX chemistry enables fairly rapid assembly of these discrete-length tethers in a modular fashion. All novel phosphoramidites were successfully used in automated syntheses of 5'-modified oligonucleotides.

Comblike poly(alpha-alkyl gamma-glutamate)s: computer simulation studies of an intermediate thermal phase

Monte Carlo (MC) simulations have been used to study the structure of an intermediate thermal phase of poly(alpha-octadecyl gamma,D-glutamate). This is a comblike poly(gamma-peptide) able to adopt a biphasic structure that has been described as a layered arrangement of backbone helical rods immersed in a paraffinic pool of polymethylene side chains. Simulations were performed at two different temperatures (348 and 363 K), both of them above the melting point of the paraffinic phase, using the configurational bias MC algorithm. Results indicate that layers are constituted by a side-by-side packing of 17/5 helices. The organization of the interlayer paraffinic region is described in atomistic terms by examining the torsional angles and the end-to-end distances for the octadecyl side chains. Comparison with previously reported comblike poly(beta-peptide)s revealed significant differences in the organization of the alkyl side chains.