Biological assays have dramatically improved in recent years due to the increasing use of living cells as "test tubes" for research studies. These cell-based assays have demanded that new technologies be developed for the life sciences in order to fully exploit the potential of designer drugs, stem cell engineering, and genetic medicine. The Allbritton Group is at the forefront of this technology development for biomedical and pharmaceutical research.
Traditional biochemical assays have limitations when used for assays in cells obtained from patients; therefore, the Allbritton Group has worked to develop new technologies that address critical needs for biochemical studies within live cells. The laboratory has pioneered advanced tools for analytical chemistry that now make it feasible to perform enzyme assays in individual cells taken directly from patients. In collaboration with colleagues David Lawrence and Marcey Waters in the Department of Chemistry and colleagues in the School of Medicine, the group is developing new chemical compounds that will act to report the abnormal behavior of specific enzymes in blood or biopsy specimens. This cell-by-cell measurement of enzyme activity in patients will have widespread value for individualizing or customizing patient therapy and will provide critical information for physicians using the new generation of molecularly targeted drugs used in the treatment of patients with cancer, autoimmune syndromes, neurodegenerative disorders, and a variety of other diseases.
Applying lithographic fabrication techniques from the computer industry, the DeSimone Group focuses on creating nanoscale particles using the PRINT©, Particle Replication in Non-wetting Templates, technology. Developed in DeSimone's lab, PRINT© enables precise control over particle features such as size, shape, chemical composition, deformability, and surface functionality. Multidisciplinary in nature, the DeSimone Group's research shows significant promise for novel applications in both life and materials science, ranging from improved vaccines to new medicines and targeted drug delivery approaches, to particulate surfactants and colloids for emerging technologies in robotics and displays.
We congratulate Assistant Professor James Cahoon as being one of eighteen national recipients of a David and Lucile Packard Foundation Fellowship. James was elected as one of the nation's most innovative early-career scientists and engineers receiving a 2014 Packard Fellowships for Science and Engineering. Each Fellow will receive a grant of $875,000 over five years to pursue their research.
"The Packard Fellowships are an investment in an elite group of scientists and engineers who have demonstrated vision for the future of their fields and for the betterment of our society," said Lynn Orr, Keleen and Carlton Beal Professor at Stanford University, and Chairman of the Packard Fellowships Advisory Panel. "Through the Fellowships program, we are able to provide these talented individuals with the tools and resources they need to take risks, explore new frontiers and follow uncharted paths."
Chancellor's Eminent Professor of Chemistry, Joseph DeSimone, has been elected to the Institute of Medicine, one of the highest honors in the fields of health and medicine a U. S. scientist can receive. His election to Institute of Medicine represents the third time he has been named a member of a U. S. National Academy. He was elected to the National Academy of Engineering in 2005 and the National Academy of Sciences in 2012. Fewer than 20 people in history have achieved election to all three U. S. National Academies, and he is the first individual in the state of North Carolina to be named to all three U. S. National Academies.
"DeSimone is a renaissance scientist," said Chancellor Carol L. Folt. "He was the first to successfully adapt manufacturing techniques from the computer industry to make advances in medicine, including next-generation approaches to cancer treatment and diagnosis. He provides a beautiful example of how transcending disciplines can revolutionize science and open up entirely new fields of study. We are very proud of what Professor DeSimone and his students have accomplished. He is a gifted and talented teacher and amazing University citizen."
Caitlin McMahon, a fourth year graduate student in the Alexanian Group, has been selected by the ACS Division of Organic Chemistry to receive a 2014-2015 Graduate Fellowship. Awardees for this highly competitive award are selected by an independent committee, and evidence of research accomplishments is an important factor in the selection process. Caitlin will travel to the 2015 National Organic Symposium to present a poster of her research.
Caitlin's research focuses on the development of metal-catalyzed organic reactions, with the goal of discovering new ways to form carbon-carbon bonds and expanding the methodology available to synthesize organic building blocks. More specifically, she has developed a palladium-catalyzed, intermolecular Heck-type reaction using alkyl electrophiles - significantly expanding the scope of the widely-utilized Heck reaction. She is currently studying carbonylative metal-catalyzed reactions, building functionalized organic molecules by forming two carbon-carbon bonds in one step under mild conditions.
As announced by Israeli Prime Minister Benjamin Netanyahu on October 6th, Arey Distinguished Professor of Chemistry, Thomas Meyer, is one of two winners of the 2014 Eric and Sheila Samson Prime Minister's Prize for Innovation in Alternative Fuels for Transportation. Professor Meyer is recognized as a world leader in solar fuel research.
The $1 million prize is awarded for breakthrough work into converting solar energy into electricity capable of powering transportation. "We are making a major multi-year effort so that we will not be dependent on fluctuations in the price of oil," Netanyahu said. "This prize gives the researchers true appreciation for their efforts." The Eric and Sheila Samson Prize, totaling $1 million, is the world’s largest monetary prize awarded in the field of alternative fuels, and is granted to scientists who have made critical advancements."
Congratulations to Dr. Meyer on receiving such a prestigious international honor," said UNC Chancellor Carol L. Folt. "Dr. Meyer is a superb example of the kind of innovation we champion here at UNC, using research to solve the world's most pressing problems. By pairing a basic scientific knowledge of photosynthesis with the latest advances in nanotechnology, Dr. Meyer and his team are bringing the world closer than ever to making solar energy a practical, reliable power source."
As described in Chemical Science, members of the Dempsey Group, in collaboration with the Meyer Group, used a layer-by-layer procedure to prepare chromophore–catalyst assemblies consisting of phosphonate-derivatized porphyrin chromophores and a phosphonate-derivatized ruthenium water oxidation catalyst on the surfaces of tin oxide and titanium dioxide mesoporous, nanoparticle films. In the procedure, initial surface binding of the phosphonate-derivatized porphyrin is followed in sequence by reaction with a zirconium salt and then with the phosphonate-derivatized water oxidation catalyst.
Fluorescence from both the free base and zinc porphyrin derivatives on tin oxide is quenched; substantial emission quenching of the zinc porphyrin occurs on titanium dioxide. Transient absorption difference spectra provide direct evidence for appearance of the porphyrin radical cation on tin oxide via excited-state electron injection. For the chromophore–catalyst assembly on tin oxide, transient absorption difference spectra demonstrate rapid intra-assembly electron transfer oxidation of the catalyst following excitation and injection by the porphyrin chromophore.
Biological systems have the ability to program reversible shape changes in response to cues from their environment. While a variety of adaptive and stimuli-responsive materials like hydrogels, liquid crystalline elastomers, and shape memory materials have been developed, mimicking programmable behavior in a reversible way remains elusive.
Work published in Macromolecules by the Sheiko and Ashby groups, in collaboration with the University of Connecticut, Brookhaven and Oak Ridge National Labs, has shown that semi-crystalline elastomers may undergo reversible switching between well-defined shapes without applying any external forces. This behavior stems from the correlated interplay between a crystalline scaffold and a network of chemical crosslinks, each capable of encoding a distinct shape. The universal mechanism of reversible shapeshifting affords interesting opportunities for minimally invasive surgery, shape programmable biomedical implants, surgical sealants, and hands-free packaging.
At the Department of Chemistry, we feel strongly that diversity is crucial to our pursuit of academic excellence, and we are deeply committed to creating a diverse and inclusive community. We support UNC's policy, which states that "the University of North Carolina at Chapel Hill is committed to equality of opportunity and pledges that it will not practice or permit discrimination in employment on the basis of race, color, gender, national origin, age, religion, creed, disability, veteran's status, sexual orientation, gender identity or gender expression."