A high-density quantitative nuclease protection microarray platform for high throughput analysis of gene expression.

The quantitative nuclease protection assay (qNPA) is a very simple and highly sensitive method for measuring mRNA transcripts, can be used on a variety of sample types, and is amenable to high-throughput sample processing. We have combined the power of the qNPA assay with the density of a DNA microarray to create a qNPA Microarray platform. This platform is compatible with common laboratory equipment: it uses fluorescence-based detection, can be analyzed with common microarray scanners, and is in an SBS footprint with 96-well layout for high-throughput applications. Here, we demonstrate the characteristics of a qNPA Microarray slide that contains up to 1700 gene elements per well. We show that the new platform can reliably detect transcripts at levels as low as 10fM with median CVs below 12%. On a standardized set of samples, the qNPA Microarray detected the same trends in gene expression as the original qNPA technology, real time qPCR, and Affymetrix GeneChip DNA Microarrays. Given its ease of use, compatibility with multiple sample types, high-throughput capabilities, and its integration with standard laboratory equipment, the qNPA Microarray is a powerful new platform for gene expression research.

Bias-induced forces in conducting atomic force microscopy and contact charging of organic monolayers.

Contact electrification, a surface property of bulk dielectric materials, has now been observed at the molecular scale using conducting atomic force microscopy (AFM). Conducting AFM measures the electrical properties of an organic film sandwiched between a conducting probe and a conducting substrate. This paper describes physical changes in the film caused by the application of a bias. Contact of the probe leads to direct mechanical stress and the applied electric field results in both Maxwell stresses and electrostriction. Additional forces arise from charge injection (contact charging). Electrostriction and contact charging act oppositely from the normal long-range Coulomb attraction and dominate when a charged tip touches an insulating film, causing the tip to deflect away from the film at high bias. A bias-induced repulsion observed in spin-coated PMMA films may be accounted for by either mechanism. In self-assembled monolayers, however, tunnel current signals show that the repulsion is dominated by contact charging.

Reproducible measurement of single-molecule conductivity.

A reliable method has been developed for making through-bond electrical contacts to molecules. Current-voltage curves are quantized as integer multiples of one fundamental curve, an observation used to identify single-molecule contacts. The resistance of a single octanedithiol molecule was 900 +/- 50 megohms, based on measurements on more than 1000 single molecules. In contrast, nonbonded contacts to octanethiol monolayers were at least four orders of magnitude more resistive, less reproducible, and had a different voltage dependence, demonstrating that the measurement of intrinsic molecular properties requires chemically bonded contacts.