A bioFET cell for measuring a time dependent characteristic of an analyte bearing fluid includes a source, a drain, a semiconductive single wall carbon nanotube network layer extending between the source and drain electrodes and electrically coupled there between, a gate insulatively spaced from and disposed over and extending between the source and drain electrodes, a layer of at least one selected antibody disposed on and linked to the polymer layer to functionalize the semiconductive single wall carbon nanotube network layer to a selected target biomarker corresponding to the at least one selected antibody so that electron transport into the semiconductive single wall carbon nanotube network layer is facilitated, where the source, drain and gate electrodes with the carbon nanotube network layer form a defined channel through which the analyte bearing fluid may flow, and a high impedance source follower amplifier coupled to the source electrode.

The present invention provides a structure for integrating microfluidic devices and electrical biosensors, including: a substrate for carrying an electrical biosensor; a microfluidic channel layer for providing at least a fluid to flow; a cover member for the inflow and outflow of the at least a fluid, and an electrical biosensor, having a biosensing layer and mounted to the cover member in a flip-chip manner; wherein the fluid flows into an inlet, passes the electrical biosensor for sensing and flows out through a fluid outlet.

Structures, apparatuses, and methods are provided for fabricating a semiconductor device structure. An example semiconductor device structure includes a first substrate, a first device layer, a second device layer and a third device layer. The first device layer may be on the first substrate and include a switch. The second device layer may be on the first device layer and include a sensing device. The third device layer may include one or more inter-level connection structures configured to electrically connect the switch to the sensing device. The switch may be configured to be electrically turned on in response to a selection signal. The sensing device may be configured to generate an output signal in response to the switch being turned on.

A nanopore-containing substrate includes a substrate, a membrane on the substrate, and at least one nanoscale electronic element disposed on or embedded in the membrane. The membrane defines at least one nanopore. The nanoscale electronic element is aligned with one of the nanopores such that a shortest distance between an edge of the nanoscale electronic element and the edge of the nanopore is less than 50 nm. The nanopores may be formed by etching through a dielectric layer using a solution while applying a voltage to the nanoscale electronic element relative to the solution. The nanopore-containing substrate can be used to detect or sequence a biopolymer, such as a nucleic acid. The nanopore-containing substrate may be used with a biopolymer detection and/or sequencing system.

Disclosed are ion-sensitive polymers and methods for their use for monitoring biological phenomena associated with ion fluxes, as well as organic electrochemical transistors including such polymers.

In one example, a sensor includes a heterojunction bipolar transistor and component sensing surface coupled to the heterojunction bipolar transistor via an extended base component. In another example, a biosensor for detecting a target analyte includes a heterojunction bipolar transistor and a sensing surface. The heterojunction bipolar transistor includes a semiconductor emitter including an emitter electrode for connecting to an emitter voltage, a semiconductor collector including a collector electrode for connecting to a collector voltage, and a semiconductor base positioned between the semiconductor emitter and the semiconductor collector. The sensing surface is coupled to the semiconductor base of the heterojunction bipolar transistor via an extended base component and includes a conducting film and a reference electrode.

Provided herein are devices, systems, and methods for measuring the presence of an analyte of interest in a sample. Certain embodiments of the present disclosure are related to culture measurement systems that include a culture vial and a sensor, wherein the sensor is a pH sensor, a responsive label, or an indicator compound, such that the sensor is incorporated into the culture vial for measurement of the pH of the sample.

A method and an apparatus for nucleic acid sequencing are provided. The method includes immobilizing capturing oligonucleotides with different sequences in reaction wells, immobilizing single-stranded nucleic acid templates in the reaction wells via annealing between the templates and the capturing oligonucleotides, amplifying the immobilized nucleic acid templates and producing a population of template clones annealed with a plurality of sequencing primers. The method further includes sequentially disposing different types of nucleotide trisphosphates, detecting, by ion-sensitive field-effect transistors, ion concentration change in the reaction wells in response to incorporation of one of the nucleotide trisphosphates at 3′ end of sequencing primers, when the nucleotide trisphosphates is complementary to a corresponding nucleotide in the template clones, and sequencing the template clones by repeating the sequentially disposing and the detecting. A method for producing single-stranded nucleic acid template clones on a reaction well array is also provided.

A chemically differentiated sensor array system includes a plurality of environmentally-gated transistors and an environmental gate, wherein the environmental gate includes a liquid solution and each environmentally-gated transistor includes a drain, a source, and a Carbon-based substrate channel, the drain electrically couples to a first location on the substrate channel, the source electrically couples to a second location on the substrate channel separated by a gap from the first location on the substrate channel, the environmental gate covers and contacts the substrate channel, a first insulating layer covers and separates the drain from the environmental gate, and a second insulating layer covers and separates the source from the environmental gate.

A sensor device (100, 2800) for detecting particles, the sensor device (100, 2800) comprising a substrate (102), a first doped region (104) formed in the substrate (102) by a first dopant of a first type of conductivity, a second doped region (106, 150) formed in the substrate (102) by a second dopant of a second type of conductivity which differs from the first type of conductivity, a depletion region (108) at a junction between the first doped region (104) and the second doped region (106, 150), a sensor active region (110) adapted to influence a property of the depletion region (108) in the presence of the particles, and a detection unit (112) adapted to detect the particles based on an electric measurement performed upon application of a predetermined reference voltage between the first doped region (104) and the second doped region (106, 150), the electric measurement being indicative of the presence of the particles in the sensor active region (110).