Computational studies unlock the secrets of cellulose for more sustainable and disease resistant crops
MELBOURNE, Australia: Scientists from IBM Research, the University of Melbourne and the University of Queensland have moved a step closer to identifying the nanostructure of cellulose – the basic structural component of plant cell walls. (more…)
Researchers from North Carolina State University and the Chinese Academy of Sciences have found an easy way to modify the molecular structure of a polymer commonly used in solar cells. Their modification can increase solar cell efficiency by more than 30 percent.
Polymer-based solar cells have two domains, consisting of an electron acceptor and an electron donor material. Excitons are the energy particles created by solar cells when light is absorbed. In order to be harnessed effectively as an energy source, excitons must be able to travel quickly to the interface of the donor and acceptor domains and retain as much of the light’s energy as possible. (more…)
Applications range from protective coating to sterilize hospital surfaces and medical equipment or as an injection to more effectively treat patients
SAN JOSE, Calif. – 24 Jan 2013: Researchers from IBM and the Institute of Bioengineering and Nanotechnology revealed today an antimicrobial hydrogel that can break through diseased biofilms and completely eradicate drug-resistant bacteria upon contact. The synthetic hydrogel, which forms spontaneously when heated to body temperature, is the first-ever to be biodegradable, biocompatible and non-toxic, making it an ideal tool to combat serious health hazards facing hospital workers, visitors and patients.
Traditionally used for disinfecting various surfaces, antimicrobials can be found in traditional household items like alcohol and bleach. However, moving from countertops to treating drug resistant skin infections or infectious diseases in the body are proving to be more challenging as conventional antibiotics become less effective and many household surface disinfectants are not suitable for biological applications. (more…)
UCLA-created nanoscale protein containers could aid drug, vaccine delivery
UCLA biochemists have designed specialized proteins that assemble themselves to form tiny molecular cages hundreds of times smaller than a single cell. The creation of these miniature structures may be the first step toward developing new methods of drug delivery or even designing artificial vaccines.
“This is the first decisive demonstration of an approach that can be used to combine protein molecules together to create a whole array of nanoscale materials,” said Todd Yeates, a UCLA professor of chemistry and biochemistry and a member of the UCLA–DOE Institute of Genomics and Proteomics and the California NanoSystems Institute at UCLA. (more…)
Researchers at Yale University have developed a new way of exposing the atomic attachments that keep complex molecules in precise alignment. The new method could provide insight into the mechanics of a variety of molecular structures, potentially aiding efforts to manipulate them for drug discovery and other purposes.
“The method appears likely to become a central tool for the characterization of processes that depend on supramolecular associations,” said Mark Johnson, a Yale chemistry professor and the principal investigator of the technique, which is described in a paper published this month in the journal Science. Supramolecular associations are interactions taking place between molecules, rather than within them. (more…)
