A device includes a first biosensor of a biosensor array; a second biosensor of a biosensor array; a readout circuit electrically connected to the biosensor array; a decoder electrically connected to the biosensor array; a voltage generator electrically connected to the biosensor array; and a decision system electrically connected to the voltage generator and the readout circuit.

In some embodiments, an inverting amplifier includes four electrical circuit elements (or “pixels”), with two pixels used as sensing elements and two pixels used as adjustable resistors for adjusting amplification factor to operate all pixels at the same amplification factor and cancelling out variations from processing. The sensing pixels include a silicon nanowire exposed to liquid or gas medium for sensing, a metal electrode partially open for contact with the medium and used for feeding a high-frequency sinusoidal stimulation in impedance measurements and for sensing properties of the medium, implanted source and drain electrodes connected to the nanowire, and electrical metal contacts attached to the electrodes and connecting the pixel to an electrical circuit. The two compensation pixels include an n-type or p-type silicon nanowire, implanted source and drain electrodes connected to the nanowire, and electrical metal contacts attached to the electrodes and connecting the pixel to an electrical circuit.

A method for nucleic acid sequencing includes receiving a plurality of signals indicative of a parameter measured for a plurality of defined spaces, at least some of the defined spaces including one or more sample nucleic acids, the signals being responsive to a plurality of nucleotide flows introducing nucleotides to the defined spaces; determining, for at least some of the defined spaces, whether the defined space includes a sample nucleic acid; processing, for at least some of the defined spaces determined to include a sample nucleic acid, the received signals to improve a quality of the received signals; and predicting a plurality of nucleotide sequences corresponding to respective sample nucleic acids for the defined spaces based on the processed signals and the nucleotide flows.

Integrated circuit (100) comprising a semiconductor substrate (110); an insulating layer (120) over said substrate; an first transistor (140) on said insulating layer, said first transistor comprising an exposed channel region (146) in between a source region (142a, 142b) and a drain region (144); and a voltage waveform generator (150) conductively coupled to the semiconductor substrate for providing the first transistor with a bias voltage during a signal acquisition period, wherein the voltage waveform generator is arranged to generate an alternating bias voltage waveform (300) comprising a periodically increasing amplitude. A sensing apparatus including such an integrated circuit and a sensing method using such an integrated circuit are also disclosed.

This document provides methods, devices, and systems for detecting the presence, absence, or amount of one or more analytes. For example, this document provides methods for using graphene-based sensors to detect one or more analytes (e.g., proteins, nucleic acids, intact cells, intact viruses, intact microorganisms, and/or chemicals).

A method of forming a sensor comprising a single layer or multilayer structure; a fluorinated layer having a fluorinated surface on the single layer or multiple layer structure; and a receptor having a fluorinated group on the fluorinated surface, the method comprising treating the fluorinated surface with a surfactant and either depositing the receptor having a fluorinated group onto the fluorinated surface from a formulation comprising one or more solvents in which the receptor is dissolved or dispersed, or depositing a fluorinated compound comprising a fluorinated group onto the fluorinated surface from a formulation comprising one or more solvents in which the fluorinated compound is dissolved or dispersed, and reacting the fluorinated compound or a derivative thereof with a receptor comprising a reactive group to form the receptor having the fluorinated group.

The present invention provides a bio-sensing device. The bio-sensing device includes an array of unit cells, each unit cell including: a source electrode and a drain electrode spaced apart from each other; a sensing film that serves as a channel between the source electrode and the drain electrode; and gate electrodes spaced apart from the sensing film, wherein the gate electrodes is disposed at a lower level than the source electrode, the drain electrode and the sensing film.

An assembly and a method are disclosed for analyzing nucleic acid sequences by way of so-called sequencing-by-synthesis. According to an embodiment of the invention, a chemical substance group that is released when a nucleotide bonds to a nucleic acid sequence to be sequenced is detected. The reagents are applied by way of a spraying device to a sensor that detects the released substance group. This has the advantage that no lateral flow occurs. The rate of false-negative and false-positive results is significantly reduced. Furthermore, a small amount of the reagent is sufficient to completely wet the sensor. Filling of the supply and discharge lines as for a flow cell is not necessary.

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.

An integrated electronic detector operates to detecting a variation in potential on an input terminal. The detector includes a MOS transistor having a drain forming an output. Variation in drain current is representative of the variation in potential. A bipolar transistor has a base forming the input terminal and a collector electrically connected to the gate of the MOS transistor. The detector has a first configuration in which the bipolar transistor is conducting and the MOS transistor is turned off. The detector has a second configuration in which the bipolar transistor is turned off and the MOS transistor is in a sub-threshold operation. Transition of the detector from the first configuration to the second configuration occurs in response to the variation in potential.