Light-regulated molecular diffusion in a liquid crystal network.

Photo-responsive liquid crystal polymer networks offer promising means to generate useful functional devices, but many of them focus on their mechanical response so as to generate surface features or shape change. Here, we investigate the photomechanical effect of the polymer network for molecular transport purposes. Dual wavelength illumination of an azobenzene-functionalized cholesteric liquid crystal polymer film produces excess free volume within the film, which results in an accelerated molecular diffusion through the film.

Enhanced vapour sensing using silicon nanowire devices coated with Pt nanoparticle functionalized porous organic frameworks.

Recently various porous organic frameworks (POFs, crystalline or amorphous materials) have been discovered, and used for a wide range of applications, including molecular separations and catalysis. Silicon nanowires (SiNWs) have been extensively studied for diverse applications, including as transistors, solar cells, lithium ion batteries and sensors. Here we demonstrate the functionalization of SiNW surfaces with POFs and explore its effect on the electrical sensing properties of SiNW-based devices.

Metal-Organic Polyhedra-Coated Si Nanowires for the Sensitive Detection of Trace Explosives.

Surface-modified silicon nanowire-based field-effect transistors (SiNW-FETs) have proven to be a promising platform for molecular recognition in miniature sensors. In this work, we present a novel nanoFET device for the sensitive and selective detection of explosives based on affinity layers of metal-organic polyhedra (MOPs). The judicious selection of the geometric and electronic characteristics of the assembly units (organic ligands and unsaturated metal site) embedded within the MOP cage allowed for the formation of multiple charge-transfer (CT) interactions to facilitate the selective explosive inclusion.

Ionophore-containing siloprene membranes: direct comparison between conventional ion-selective electrodes and silicon nanowire-based field-effect transistors.

Siloprene-based, ion-selective membranes (ISMs) were drop-casted onto a field-effect transistor device that consisted of a single-chip array of top-down prepared silicon nanowires (SiNWs). Within one array, two sets of SiNWs were covered with ISMs, each containing two different ionophores, allowing the simultaneous sensing of K and Na ions using a flow cell. It is shown that both ions can be effectively detected in the same solution over a wide concentration range from 10(-4) to 10(-1) M without interference.

Silicon nanowire-based devices for gas-phase sensing.

Since their introduction in 2001, SiNW-based sensor devices have attracted considerable interest as a general platform for ultra-sensitive, electrical detection of biological and chemical species. Most studies focus on detecting, sensing and monitoring analytes in aqueous solution, but the number of studies on sensing gases and vapors using SiNW-based devices is increasing. This review gives an overview of selected research papers related to the application of electrical SiNW-based devices in the gas phase that have been reported over the past 10 years.

Real-time detection of transcription factors using target-converted helicase-dependent amplification assay with zero-background signal.

Highly sensitive detection of transcription factors is essential to the evaluation of cellular development and the disease state. However, so far most detection methods are usually laborious and time-consuming with a poor sensitivity. Here, we demonstrate a simple and ultrasensitive approach for transcription factor detection based on the target-converted helicase-dependent amplification assay.

Rapid and label-free monitoring of exonuclease III-assisted target recycling amplification.

Target recycling-oriented amplification has been widely applied for sensitive detection of DNA, RNA, and proteins due to its successful overcoming the inherent limitation of target-to-signal ratio of 1:1 in the traditional hybridization assay. Exonuclease III (Exo III) is usually used as the cleavage enzyme in the target recycling-oriented amplification because of its easy availability, high catalytic activity, and wide applicability. Even though Exo III is assumed to be double-stranded DNA (dsDNA) specific exonuclease in most literature, its cleavage of single-strand DNA (ssDNA) does occur, resulting in the target-independent degradation of probes.

Sensitive and label-free DNA methylation detection by ligation-mediated hyperbranched rolling circle amplification.

Sensitive and specific detection of DNA methylation in CpG sites of genomic DNA is imperative for rapid epigenetic evaluation and early cancer diagnosis. Here, we employ for the first time the thermostable ligation for methylated DNA discrimination and hyperbranched rolling circle amplification (HRCA) for signal enhancement, without the need for restriction enzymes, PCR amplification, or fluorescence-labeled probes. After bisulfite treatment of methylated DNA, the methylation-specific linear padlock probe can be circularized only in the presence of methylated DNA and serves subsequently as a template for HRCA, whose products are easily detected using SYBR Green I and a standard fluorometer.