DNA is extremely versatile and powerful, both as a construct in biological applications and as a ligand in materials design due to the fact that its recognition properties can be programmed through sequence and length. Spherical nucleic acids (SNAs), nanoparticles surrounded by a dense shell of DNA or RNA, are...
Proteins are the nanoscale building blocks of life. Their sophisticated but well-defined architectures result in complex biological functions, including ones involved in metabolism, photosynthesis, transcription, translation, and immunity. To study and improve upon the natural functions of proteins, it is desirable to develop methodology for organizing proteins into targeted architectures....
Nucleic acids such as DNA or RNA of various lengths and structures have a wide scope of functions as therapeutic entities compared to conventional drugs. For instance, native and modified forms of nucleic acids can be used for gene silencing, genome editing, gene replacement, immune system modulation, and theranostics. While...
Gold nanoparticles (AuNPs) display unique characteristics compared to their macro-counterparts that are dependent on shape, size, and attached surface molecules. Methods have been developed to precisely control both size and shape of AuNPs for specific applications. The biocompatibility, plasmonic properties, and ease of functionalization with thiolated molecules, make gold nanoparticles...
Stimuli-responsive colloidal crystals with reconfigurable structures and properties have garnered significant interest in fields focused on the development of on-demand optics, adaptive catalysts, as well as chemical and biological sensors. A variety of different assembly techniques have been developed to engineer colloidal crystals. However, most reported structures are static as...
Metal-organic frameworks (MOFs) are a class of highly modular materials with welldefined three-dimensional architectures, permanent porosity, and diverse chemical functionalities, which show promise for a wide range of applications, including gas storage and separation, drug delivery, chemical sensing, and catalysis. Nanoparticle forms of MOFs have similar properties but are dispersible...
When attached to another species (e.g. a nanoparticle), the sequence specificity of DNA can be repurposed to program interactions between such entities and to direct their formation into ordered structures. The research presented in this thesis aims to push the boundaries of structures that can be made via this approach....
Nano-scale materials possess many unique physical and chemical properties which are not found in bulk materials. The ability to synthesize these materials by design is one of the greatest challenges in materials science. Advances towards meeting this challenge will lead to discoveries in fields such as plasmonics, photonics, catalysis, and...
Systems of colloids coated with high-information polymers are powerful tools for designing crystal lattice with tailorable properties or studying the fundamentals of crystallization. By changing the colloid-colloid interaction strength or colloid shape, different types of lattices can be assembled. In this thesis, I present novel coarse-grained models to describe high-information...
Spherical nucleic acids (SNAs) are a class of structures composed of spherical nanoparticle cores that are densely functionalized with radially oriented, linear DNA. SNAs exhibit properties that are distinct from those of their linear counterparts. These constructs can readily enter cells, evade nuclease degradation, and bind complementary DNA targets with...