Computational models greatly benefit metabolic engineering efforts by helping to elucidate experimental observations and predict engineering targets for improved cellular performance. Additionally, supplementing experimental efforts with computational modeling can reduce the loss of time and resources in the lab by narrowing down testing conditions. In optimal cases, computational models can...
The rational and deliberate assembly of functional materials from nanoscale building blocks requires a fundamental understanding of interactions between individual components as well as their collective behavior. This thesis investigates the hierarchical organization of nanoparticles using DNA into well-defined three-dimensional materials on the micrometer and millimeter length scales. This assembly...
Metabolic engineering of microorganisms to produce useful compounds from renewable substrates is a promising means for sustainable, on-demand production of chemicals. However, efforts to design and engineer microbial cell factories are constrained by costly and slow “build” times in which each genetic variation requires re-engineering a new strain for each...
Graphene and graphene oxide (GO), a highly oxidized form of graphene, are materials with incredibly interesting chemical and mechanical properties. These materials have high surface areas and electrical properties that can be tuned by reducing the amount of oxygenates on the surface. They have already demonstrated their importance in the...
Individuals commonly engage in collaborative behavior to more easily produce works of high societal impact. The effect of many individual characteristics such as age or gender on the effectiveness of a team is still unclear. Gender is especially pertinent because many professional settings are still far from gender parity, despite...
T-cell activation is an essential step of the immune response, yet the cellular and molecular events underlying this complex process are not fully understood. Significantly, a comparative genome-scale transcriptional analysis of two T-cell subsets and the natural-mixed CD3+ population remains unexplored. Using microarrays, we investigated the temporal global transcriptional profile...
Separation of DNA molecules by electrophoresis through entangled polymer solutions continues to be an important tool for genetic analysis, especially Sanger-based DNA sequencing. Separations of DNA on microfluidic devices are much more efficient than in capillary electrophoresis (CE) systems, such that the implementation of DNA sequencing onto microchips promises to...
Structural dynamics in three polymer blend systems, differing largely with respect to morphology, have been investigated. The first system, composed of two immiscible homopolymers, exhibits a microstructure of micron-sized droplets dispersed in a matrix phase. We have examined small-angle x-ray scattering (SAXS) as a new approach for conducting in situ...
The genetic code, a set of rules by which mRNA codons are translated into the twenty standard amino acids used in protein synthesis, was once thought to be immutable. As we expanded our understanding of molecular biology more variations in this genetic code have been found across the animal kingdom....
Polyurethane (PU) is an important commodity polymer with a broad range of applications. Increasing regulations on isocyanates have prompted investigations into alternative routes to PU. Cyclic carbonate aminolysis leading to polyhydroxyurethane (PHU) is a promising alternative. This dissertation describes the first fundamental investigation of the synthesis and properties of segmented,...