Interfacial effects play a critical role in perturbing the properties of polymeric materials. The average properties of polymer materials with substantial specific interfacial area, e.g., ultrathin films, nanorods, and polymer nanocomposites, often deviate significantly from the bulk responses. Much of the past research has focused on systems in which free...
While metabolic engineering can enable the sustainable bioproduction of new materials, efforts are often impeded by pathway bottlenecks. To mitigate the effects of toxic or reactive intermediates and resource competition resulting from heterologous pathway incorporation, bacterial microcompartments (MCPs) have recently been considered for engineered compartmentalization in bacterial host organisms. MCPs...
Two-step, solar thermochemical water splitting using nonstoichiometric oxides has emerged as an attractive approach for large-scale hydrogen production. Perovskite-structured oxides, with their wide tunability, offer the potential for high fuel productivity at moderate operating temperatures. Given the vast chemical space, the materials development effort is carried out here in combination...
Nucleic acids not only are the building blocks of life but also a class of attractive macromolecular therapeutics. However, the delivery of therapeutic oligonucleotides into cells has been a major challenge due to their large size and highly negatively charged backbone. Spherical nucleic acids (SNAs) are a class of emerging...
The need to rapidly develop and produce life-saving vaccines and therapeutics is critical for overcoming pandemics in a global economy. Recent advances in automation and cell-free systems have opened new avenues for expediting optimization and production of biologic vaccines and therapeutics. A key consideration for the development of protein biologics...
Conventional polymer network materials, e.g., rubber tires, cannot be efficiently recycled for high-value applications because of their permanent network structures. Therefore, at the end of use, none or only a small fraction of the economic value can be recovered from these materials. Scrapped tires demonstrate well this issue along with...
The effective capture and detoxification of chemical warfare agents (CWAs) is a pressing need in the modern world. Materials are needed for both the destruction of weapon stockpiles and personal protection via fabric coatings or respirators. Attractive candidates for these applications include metal–organic frameworks (MOFs) – highly crystalline materials composed...
Cells are primarily comprised of metal ions, small molecules, proteins, lipids, and nucleic acids. The ability to probe these molecules in single living cells can shed new light on chemical processes inside of cells or allow disease diagnosis based on molecular profiling. However, there exists a lack of tools that...
Metal-organic frameworks are crystalline, nanoporous materials formed by metal nodes connected by organic ligands. MOFs represent an exciting approach to materials design where a material with desired properties can be made by choosing the compatible nodes, linkers and topologies independently. MOFs are highly porous and have high surface areas...
Recent advances in combinatorial chemistry, synthetic biology, and ‘omics’ research require high-throughput methods for performing and analyzing thousands to millions of reactions in one day. However, it is a challenge to engineer high-throughput systems that can autonomously conduct and analyze such a large number of reactions in a generalizable and...