A method for sequencing a nucleic acid template includes forming a nanowire assembly including a semiconductor nanowire and a probe covalently bound to the semiconductor nanowire; contacting the nanowire assembly with a template nucleic acid; contacting the nucleic acid duplexes with an extension nucleic acid, the extension nucleic acid joined to the probe; disrupting the nucleic acid duplexes; and measuring an electrical characteristic of a nanowire assembly of the set of nanowire assemblies.

A method for sequencing a nucleic acid template includes forming a nanowire assembly including a semiconductor nanowire and a probe covalently bound to the semiconductor nanowire; contacting the nanowire assembly with a template nucleic acid; contacting the nucleic acid duplexes with an extension nucleic acid, the extension nucleic acid joined to the probe; disrupting the nucleic acid duplexes; and measuring an electrical characteristic of a nanowire assembly of the set of nanowire assemblies.

A method for sequencing a nucleic acid template includes forming a nanowire assembly including a semiconductor nanowire and a probe covalently bound to the semiconductor nanowire; contacting the nanowire assembly with a template nucleic acid; contacting the nucleic acid duplexes with an extension nucleic acid, the extension nucleic acid joined to the probe; disrupting the nucleic acid duplexes; and measuring an electrical characteristic of a nanowire assembly of the set of nanowire assemblies.

Disclosed are field effect transistor-based (FET-based) sensors for the rapid and accurate detection of analytes both in vivo and in vitro. The FET-based sensors can include a substrate, a channel disposed on the substrate, a source electrode and a drain electrode electrically connected to the channel, and a recognition element for an analyte of interest immobilized on the surface of the channel via a linking group. The distance between the recognition element and the channel can be configured such that association of the analyte of interest with the recognition element induces a change in the electrical properties of the channel. In this way, an analyte of interest can be detected by measuring a change in an electrical property of the channel. Also provided are devices, including probes and multi-well plates, incorporating the FET-based sensors.

A method for sequencing a nucleic acid template includes forming a nanowire assembly including a semiconductor nanowire and a probe covalently bound to the semiconductor nanowire; contacting the nanowire assembly with a template nucleic acid; contacting the nucleic acid duplexes with an extension nucleic acid, the extension nucleic acid joined to the probe; disrupting the nucleic acid duplexes; and measuring an electrical characteristic of a nanowire assembly of the set of nanowire assemblies.

A multi-dimensional chromatographic method for the separation of N-glycans. The method comprises providing a glycan preparation that includes at least one negatively charged N-glycan. The glycan preparation is then separated by anion-exchange chromatography and at least one secondary chromatographic technique.

A multi-dimensional chromatographic method for the separation of N-glycans. The method comprises providing a glycan preparation that includes at least one negatively charged N-glycan. The glycan preparation is then separated by anion-exchange chromatography and at least one secondary chromatographic technique.

A multi-dimensional chromatographic method for the separation of N-glycans. The method comprises providing a glycan preparation that includes at least one negatively charged N-glycan. The glycan preparation is then separated by anion-exchange chromatography and at least one secondary chromatographic technique.

A method for sequencing a nucleic acid template includes forming a nanowire assembly including a semiconductor nanowire and a probe covalently bound to the semiconductor nanowire; contacting the nanowire assembly with a template nucleic acid; contacting the nucleic acid duplexes with an extension nucleic acid, the extension nucleic acid joined to the probe; disrupting the nucleic acid duplexes; and measuring an electrical characteristic of a nanowire assembly of the set of nanowire assemblies.

The present invention provides a method for the analysis of a compound with amino group (e.g., an amino acid or peptide) contained in a sample and convenient manner with a high sensitivity. The compound with amino group in a sample containing the compound with amino group is labeled with a specific carbamate compound such as p-trimethylammonium anilyl-N-hydroxysuccinimidyl carbamate iodide to enhance the selectivity and sensitivity. The present invention is preferably used in conjunction with mass spectrometry such as MS/MS method to facilitate quantitative analysis. The present invention further provides labeling reagents for mass spectrometry.