Surface passivation
to inhibit nonspecific interactions is a key requirement for in vitro
single-molecule fluorescent studies. Although the standard passivation
methods involve the covalent attachment of poly(ethylene glycol) (PEG)
in two steps preferably over quartz surfaces, this protocol and improvements
thereon require extensive labor and chemicals. Herein, we report an
efficient one-step surface grafting of PEG-silane that yields enhanced
passivation, as evidenced by reduced nonspecific interactions, over
the conventional method at a minimal time and reagent cost and on
glass surfaces. Our method is rooted in a mechanistic understanding
of the silane reaction with the silanol groups on the glass surface.
Single-molecule fluorescence studies with fluorescently tagged proteins
and DNA on PEG-silane-functionalized glass surfaces validate the enhanced
performance of the method. Combined with atomic force microscopy surface
characterization, our study further illustrates that few remaining
pinhole defects, plausibly from defects on the glass, on PEG-silane
glass-coated surfaces account for the minimal background, where typically
no more than one molecule is nonspecifically attached in a given diffraction-limited
spot on the surface.
Four short ligands; cysteine, cysteamine, dithiothrietol and glycine are examined and compared in their ability to stabilize and assemble silver nanoparticles (AgNPs).
The fabrication of plasmonic nanorings remains of substantial interest by virtue of their enhanced electric and magnetic response to light fields which can be subsequently exploited in diverse applications. Scaling down the size of nanorings holds promise in creating artificial magnetism at wavelengths matching the solar spectrum. Nanosized bioscaffolds can be utilized to tackle the challenge of size reduction of metallic rings owing to their miniature features as well as their well-known biomineralization capacity. Herein, we use the tobacco mosaic virus coat protein as a command surface to grow and assemble silver nanoparticles into sub-30 nm rings. The versatility of TMV allows the formation of both solid rings and rings consisting of discrete nanoparticles that are characterized by UV-vis and TEM. The pH-dependent coulombic surface map along with the annular geometry of the protein aggregate allow the generation of rings with or without a central nanoparticle. Our silver rings are believed to be the smallest to date, and they can offer a test material for existing theories on metallic nanorings of this heretofore unreached size scale.
SummaryNanostructured materials with tunable properties are of great interest for a wide range of applications. The self-assembly of simple nanoparticle building blocks could provide an inexpensive means to achieve this goal. Here, we generate extended anisotropic silver nanoparticle assemblies in solution using controlled amounts of one of three inexpensive, widely available, and environmentally benign short ditopic ligands: cysteamine, dithiothreitol and cysteine in aqueous solution. The self-assembly of our extended structures is enforced by hydrogen bonding. Varying the ligand concentration modulates the extent and density of these unprecedented anisotropic structures. Our results show a correlation between the chain nature of the assembly and the generation of spectral anisotropy. Deuterating the ligand further enhances the anisotropic signal by triggering more compact aggregates and reveals the importance of solvent interactions in assembly size and morphology. Spectral and morphological evolutions of the AgNPs assemblies are followed via UV–visible spectroscopy and transmission electron microscopy (TEM). Spectroscopic measurements are compared to calculations of the absorption spectra of randomly assembled silver chains and aggregates based on the discrete dipole approximation. The models support the experimental findings and reveal the importance of aggregate size and shape as well as particle polarizability in the plasmon coupling between nanoparticles.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.