The present invention generally relates to nanotechnology and sub-microelectronic circuitry, as well as associated methods and devices, for example, nanoscale wire devices and methods for use in determining nucleic acids or other analytes suspected to be present in a sample. For example, a nanoscale wire device can be used in some cases to detect single base mismatches within a nucleic acid. In one aspect, dynamical information such as a binding constant, an association rate, and/or a dissociation rate, can be determined between a nucleic acid or other analyte, and a binding partner immobilized relative to a nanoscale wire. In some cases, the nanoscale wire includes a first portion comprising a metal-semiconductor compound, and a second portion that does not include a metal-semiconductor compound. The binding partner, in some embodiments, is immobilized relative to at least the second portion of the nanoscale wire.

Techniques for enhanced fluorescence include a Tamm substrate for a target optical frequency comprising a metal nanoscale layer deposited on a Bragg grating. The Bragg grating includes multiple dielectric layers including multiple high index of refraction layers alternating with multiple low index of refraction layers. The dielectric layers are parallel to the metal nanoscale layer; and, the thickness of each dielectric layer is about a fourth of a wavelength of the target optical frequency in the layer. The metal nanoscale layer is configured to host a fluorophore such that an S polarized emission from the fluorophore at the target optical frequency propagates out of the substrate perpendicular to the plurality of dielectric layers.

A waveguide sensor capable of direct, real-time detection and monitoring of analytes in the vicinity of the waveguide surface without requiring the tagging or labeling of the analyte, is described. Analytic and numerical calculations have predicted that by locally detecting either changes in the evanescent field or changes in the light coupled out of the waveguide as a result of the presence of the analyte, high detection sensitivity will be able to be achieved.

A label-free method for the spatio-temporal mapping of protein secretions from individual cells in real time by using a chip for localized surface plasmon resonance (LSPR) imaging. The chip is a glass coverslip compatible for use in a standard microscope having at least one array of functionalized plasmonic nanostructures patterned onto it. After placing a cell on the chip, the secretions from the cell are spatially and temporally mapped using LSPR imaging. Transmitted light imaging and/or fluorescence imaging may be done simultaneously with the LSPR imaging.

Titania nanotube arrays are useful for phosphopeptide enrichment and separation. These highly ordered titania nanotube arrays are a low cost and highly effective alternative to the use of liquid chromatography mass spectrometry (LC-MS) methods using meoporous titania beads or particles. The highly ordered Ti0.sub.2 nanotubes are grown on surfaces coated with Ti metal, or preferably on Ti wires, by methods that preferably include anodic oxidation.

Titania nanotube arrays are useful for phosphopeptide enrichment and separation. These highly ordered titania nanotube arrays are a low cost and highly effective alternative to the use of liquid chromatography mass spectrometry (LC-MS) methods using meoporous titania beads or particles. The highly ordered Ti0.sub.2 nanotubes are grown on surfaces coated with Ti metal, or preferably on Ti wires, by methods that preferably include anodic oxidation.

The present invention relates to a method for detection of binding or interaction events between a binding agent and its corresponding analyte (such as an antibody and an antigen) in which a signal is detected which is substantially more amplified and thus easier to detect than in prior art systems. The method comprises simultaneous but separate addition of a first enhancement reagent having affinity for said analyte and a second enhancement reagent having affinity for the first enhancement reagent wherein the first enhancement reagent binds to the analyte and the second enhancement reagent binds to the first enhancement reagent, and, wherein the first and second enhancement reagents have more than one binding site so that they are able to bind to each other to thereby amplify a detectable signal from the binding event.

The invention provides methods of immobilizing an active agent to a substrate surface, including the steps of, providing a substrate, contacting the substrate with a solution of a compound including a trihydroxyphenyl group, thereby forming a trihydroxyphenyl-treated substrate, and contacting the trihydroxyphenyl-treated substrate with an active agent, thereby immobilizing the active agent on the substrate. Further provided are methods of immobilizing an active agent on a substrate, including the steps of providing a substrate, combining a solution of a compound including a trihydroxyphenyl group with a solution of an active agent, thereby forming a solution of an active agent-trihydroxyphenyl conjugate, and contacting the substrate with the solution of the active agent-trihydroxyphenyl conjugate, thereby immobilizing the active agent on the substrate. The invention further provides substrates and medical device or device components with active agents immobilized on the surface thereof.

One or more aqueous, near infrared emitting, high yield, highly photoluminescent, stable quantum dots conjugated to one or more biomarkers specific moieties. The conjugated quantum dots have an enhanced detection sensitivity and selectivity and may be formed using a novel and efficient method for conjugating one or more biomarker specific moieties to the quantum dots. The invention is further directed to a method for using the conjugated quantum dots for cancer detection in the margin of excised tissue.

For a chemical or biological sensor, which is reusable while maintaining a clean state thereof, and a method for using the same, the present invention provides a reusable chemical or biological sensor and a method for using the same, the reusable chemical or biological sensor comprising: a sensor transducer; a ferromagnetic pattern formed on at least one surface of the sensor transducer; magnetic nanoparticles which can be collected or released in a single layer on the sensor transducer, in directions of first and second magnetic fields applied to the sensor transducer; and a receptor which is fixed on the magnetic nanoparticles and can bind to a target substance to be detected.