Exploring Biopharmaceutical Analysis with Compact Capillary Liquid Chromatography Instrumentation.

A recent trend in the design of liquid chromatography (LC) instrumentation is the move towards miniaturized and portable systems. These smaller platforms provide wider flexibility in operation, with the opportunity for conducting analysis directly at the point of sample collection rather than transporting the sample to a centralized laboratory facility. For the manufacturing of pharmaceutical and biopharmaceutical products, these platforms can be implemented for process monitoring and product characterization directly in manufacturing environments.

Column selection considerations in compact capillary liquid chromatography.

Recent years have seen significant advances in compact, portable capillary LC instrumentation. This study explores the performances of several commercially available columns within the pressure and flow limits of both the columns and one of these compact LC instruments. The commercially available compact capillary LC system with UV-absorbance detector used in this study is typically operated using columns in the 0.

DNA-templated lithography and nanofabrication for the fabrication of nanoscale electronic circuitry.

The field of structural DNA nanotechnology has undergone significant expansion in recent years as exciting new techniques and understanding have been developed, allowing for the design and assembly of complex and intricate two- and three-dimensional nanostructures. Many of these designed DNA motifs have found use in precise positioning of nanomaterials and thereby can aid in studies, reactions, and assembly of other nanostructures. This review discusses the history and progression of DNA-based nanofabrication with an emphasis on the use of DNA nanostructures for electronics applications.

Site-specific metallization of multiple metals on a single DNA origami template.

This work examines the selective deposition of two different metals on a single DNA origami template that was designed and assembled to direct the deposition. As a result, we were able to direct copper and gold to predesignated locations on the template, as verified by both compositional and morphological data, to form a heterogeneous Cu-Au junction. Seeding and deposition were performed in sequential steps.

Electrically conductive gold- and copper-metallized DNA origami nanostructures.

This work demonstrates the use of a circuit-like DNA origami structure as a template to fabricate conductive gold and copper nanostructures on Si surfaces. We improved over previous results by using multiple Pd seeding steps to increase seed uniformity and density. Our process has also been characterized through atomic force microscopy, particle size distribution analysis, and scanning electron microscopy.