Apparatuses, systems, and methods are disclosed for chemically differentiated sensor arrays and methods of manufacturing and using the same. In one or more examples. An integrated circuit chip includes a chemically differentiated array of graphene field effect transistors with one or more wells configured to receive a volume of biological sample liquid comprising a plurality of different types of biological substances to be distinguished using electrical measurements of output signals of the graphene field effect transistors. At least one electrode is configured to apply a changing gate bias voltage (V.sub.Gs) that increases and decreases within a predetermined range to the sample liquid and at least one electrode is configured to monitor measurement vectors including slopes of drain current measurements relative to the voltage measurements and differences in slope of the measurement vectors distinguish different biological substances in the sample liquid. Systems and methods utilize the integrated circuit chip.

Disclosed herein are methods and devices for a cell-free assay platform that enables measurement of membrane protein function by measuring the events that are induced by ligand binding or other stimuli.

Apparatuses, systems, and methods are disclosed for excitation and measurement of biochemical interactions. Excitation circuitry is configured to apply one or more excitation conditions to a biologically gated transistor that includes a channel, so that one or more output signals from the biologically gated transistor are affected by the excitation condition(s) and by a biochemical interaction of moieties within a sample fluid in contact with the channel surface. Measurement circuitry is configured to obtain information corresponding to the biochemical interaction occurring at one or more measurement distances greater than an electrostatic screening distance from the surface of the channel, by performing a plurality of time-dependent measurements of affected output signals, using a measurement bandwidth that corresponds to the measurement distances. An analysis module is configured to characterize one or more parameters of the biochemical interaction based on the time-dependent measurements.

The present invention provides a method and a system based on a multi-gate field effect transistor for sensing molecules in a gas or liquid sample. The said FET transistor comprises dual gate lateral electrodes (and optionally a back gate electrode) located on the two sides of an active region, and a sensing surface on top of the said active region. Appling voltages to the lateral gate electrodes, creates a conductive channel in the active region, wherein the width and the lateral position of the said channel can be controlled. Enhanced sensing sensitivity is achieved by measuring the channels conductivity at a plurality of positions in the lateral direction. The use of an array of the said FTE for electronic nose is also disclosed.

A graphene transistor includes a graphene layer including at least one sheet of graphene, a drain electrode and a source electrode each electrically connected to the graphene layer, a charge donor on at least one main surface of the graphene layer, the charge donor including an impurity charge, and a counter ion having a charge with a sign different from a sign of the impurity charge.

Devices, methods for fabricating said devices, and methods for detecting an analyte within a bio-target are described herein. The device includes a top assembly and a bottom assembly. The Top assembly includes an electrode disposed on a top layer. The bottom assembly includes a bio-chip disposed on a bottom layer and a polymer body disposed between the bio-chip and the top assembly. The polymer body includes a channel. The electrode of the top assembly is positioned within the channel. The channel is configured to accommodate the bio-target containing the analyte.

Electrical detection methods are used to identify and further characterize single-molecule target analytes such as proteins and nucleic acids. A composition including a probe region and a tail region is contacted with a target analyte. The probe region specifically binds to the target analyte. The tail region is coupled to the probe region, and includes a nucleic acid template for polynucleotide synthesis. When conditions are such that polynucleotide synthesis occurs along the tail region, one hydrogen ion is released for every nucleotide that is incorporated into the tail region. A transistor such as an ISFET detects and measures changes in ion concentration, and these measurements can be used to identify the tail region and thus characterize the corresponding target analyte.

A device and a method for performing an assay is provided. The assay device, which may be used for determining the concentration of an analyte in a sample, includes a plurality of microchambers and a Field-effect transistor (FET) arranged at the bottom of each of the plurality of microchambers. Capture probe molecules for the analyte can be arranged within the plurality of microchambers such that each microchamber contains at most one capture probe molecule. The FET can be arranged in said microchamber to give a readable output signal based on binding of the analyte, or competitor to the analyte, with the capture probe molecule.

A processive enzyme molecular sensor for use in a DNA data storage system is disclosed that can extract digital information suitably encoded into a synthetic DNA molecule. In various aspects, such sensors are provided in a high-density chip-based format that can provide the high throughput, low-cost and fast data extraction capability required for large scale DNA data storage systems. The sensor for reading the digital data stored in DNA molecules processes individual encoded DNA molecules directly, eliminating the need for complicated sample preparation such as making copies of DNA or clonal populations of such molecules.

In one embodiment, a chemical sensor is described. The chemical sensor includes a chemically-sensitive field effect transistor including a floating gate conductor having an upper surface, a first opening extending through a first material and through a portion of a second material located on the first material and a second opening extending from the bottom of the first opening to the top of a liner layer located on the upper surface of the floating gate conductor.