The present invention relates to methods for creating conductive nanojunctions using metalized or conductive polymer joined to a DNA nanowire in a nanodevice for chemosensing and biosensing.

A digital microfluidics (DMF) device including an FET-biosensor (FETB) and method of field-effect sensing is closed. In some embodiments, the DMF device may include one or more FETBs integrated into the top substrate, the bottom substrate, or both the top and bottom substrates of the DMF device. In some embodiments, the DMF device may include one or more “drop-in” style FETBs in the top substrate, the bottom substrate, or both the top and bottom substrates of the DMF device. In some embodiments, the DMF device, FETB, and method of field-effect sensing provide active-matrix control integrated into an active-matrix DMF device. Further, a microfluidics system for and method of using the DMF device including at least one FETB is provided.

A method of operating a pore field-effect transistor (FET) sensor for detecting particles, wherein the pore FET sensor comprises a FET wherein a gate is controlled by a pore filled by a fluid, comprises: controlling a first voltage (V.sub.cis) to set the FET in a subthreshold region; controlling a second voltage (V.sub.trans) to set a voltage difference between the first and second voltages (V.sub.trans) such that an effective difference in gate voltage experienced between a minimum and a maximum effective gate voltage during movement of a particle in the fluid is at least kT/q; and detecting a drain-source current in the FET, wherein the particle passing through the pore modulates the drain-source current for detecting presence of the particle.

The invention is directed to apparatus and methods for delivering multiple reagents to, and monitoring, a plurality of analytical reactions carried out on a large-scale array of electronic sensors under minimal noise conditions. In one aspect, the invention provides method of improving signal-to-noise ratios of output signals from the electronic sensors sensing analytes or reaction byproducts by subtracting an average of output signals measured from neighboring sensors where analyte or reaction byproducts are absent. In other aspects, the invention provides an array of electronic sensors integrated with a microwell array for confining analytes and/or particles for analytical reactions and a method for identifying microwells containing analytes and/or particles by passing a sensor-active reagent over the array and correlating sensor response times to the presence or absence of analytes or particles. Such detection of analyte- or particle-containing microwells may be used as a step in additional noise reduction methods.

Various cell analysis systems of the present teachings can measure the electrical and metabolic activity of single, living cells with subcellular addressability and simultaneous data acquisition for between about 10 cells to about 500,000 cells in a single analysis. Various sensor array devices of the present teachings can have sensor arrays with between 20 million to 660 million ChemFET sensors built into a massively paralleled array and can provide for simultaneous measurement of cells with data acquisition rates in the kilohertz (kHz) range. As various ChemFET sensor arrays of the present teachings can detect chemical analytes as well detect changes in cell membrane potential, various cell analysis systems of the present teachings also provide for the controlled chemical and electrical interrogation of cells.

A transistor-type sensor capable of detecting a compound having an amino group has a simple structure and also is expected to be effective in antioxidation action and prevention of dementia, etc. The transistor-type sensor includes a detection electrode for capturing a compound having an amino group for detection, and a transistor having a gate electrode connected with the detection electrode. The detection electrode has a cucurbituril structure-containing compound immobilized on the surface thereof.

A multiple functioning superconductive device was invented based on Toroidal Josephson Junction (FFTJJ) array with 3D-cage structure self-assembled organo-metallic superlattice membrane. The device not only mimics the structure and function of an activated Matrix Metalloproteinase-2 (MMP-2) protein, but also mimics the cylinder structure of the Heat Shock Protein (HSP60) protein, that works at room temperature under a normal atmosphere, and without external electromagnetic power applied. The device enabled direct rapid real-time monitoring atto-molarity concentration ATP in biological specimens and was able to define the anti-inflammatory and pro-inflammatory status revealed a transitional range of ATP concentration under antibody-free, tracer-free and label-free conditions.

A biosensor that includes a semiconductor active region; a sensing region configured to contact a fluid; and multiple electrodes that comprise decoupling electrodes and additional electrodes. The decoupling electrodes may be configured, wherein operating in a first mode, to prevent a formation of a top conductive channel within the semiconductor active region; and wherein the additional electrodes are configured, wherein operating in the first mode, to independently control (i) one or more properties of one or more other conductive channels formed within the semiconductor active region, and (ii) a Debye length at an interface between the sensing region and the fluid.

Photocurable compositions that combine redox-active semiconducting organic polymers with photocurable organic molecules are provided. Upon exposure to radiation, the photocurable compositions form ion-permeable, electrically conductive crosslinked organic films that can be used as conducting channels in n-channel or p-channel organic electrochemical transistors, including vertical organic electrochemical transistors (vOECTs). The vOECTs can be incorporated in complementary electronic circuits.

A sensor includes a working electrode in contact with an analyte solution; an amplifier including: a source terminal; a drain terminal; a back gate terminal; and nanowires, each nanowire electrically connecting the source terminal to the drain terminal; and an insulator having a first side and a second side. The working electrode is positioned to the first side of the insulator. The source terminal, the drain terminal, and the nanowires are positioned to the second side of the insulator. The insulator prevents direct electrical contact between the working electrode, the analyte solution and either the source terminal, the drain terminal, or the nanowires. The working electrode is configured such that, when a chemical species is present in the analyte solution, a variation in an electrical field at a location of the nanowires is induced, inducing a corresponding variation in an electrical current between the source terminal and the drain terminal.