The present invention relates to a sensor for dopamine-selective detection, a preparation method therefor, and use thereof.

Sequencing-by-synthesis (SBS) method is provided that includes providing a detection apparatus that includes an array of magnetically-responsive sensors. Each of the magnetically-responsive sensors is located proximate to a respective designated space to detect a magnetic property therefrom. The detection apparatus also includes a plurality of nucleic acid template strands located within corresponding designated spaces. The method also includes conducting a plurality of SBS events to grow a complementary strand by incorporating nucleotides along each template strand. At least some of the nucleotides are attached to corresponding magnetic particles having respective magnetic properties. Each of the plurality of SBS events includes detecting changes in electrical resistance at the magnetically-responsive sensors caused by the respective magnetic properties of the magnetic particles. The method also includes determining genetic characteristics of the complementary strands based on the detected changes in electrical resistance.

Analyte sensors and methods for fabricating analyte sensors are provided. In an exemplary embodiment, a method for fabricating a planar flexible analyte sensor includes sputtering platinum onto a polyester base layer to form a layer of platinum. The method includes patterning the layer of platinum to form working electrodes and additional electrodes. Further, the method includes forming an insulating dielectric layer over the base layer, wherein the insulating dielectric layer is formed with openings exposing portions of the working electrodes and portions of the additional electrodes. Also, the method includes partially singulating individual sensors from the base layer, wherein each individual sensor is connected to the base layer by a tab. The method further includes depositing an enzyme layer over the exposed portions of the working electrodes and coating the working electrodes with a glucose limiting membrane.

Analyte sensors and methods for fabricating analyte sensors are provided. In an exemplary embodiment, a method for fabricating a planar flexible analyte sensor includes sputtering platinum onto a polyester base layer to form a layer of platinum. The method includes patterning the layer of platinum to form working electrodes and additional electrodes. Further, the method includes forming an insulating dielectric layer over the base layer, wherein the insulating dielectric layer is formed with openings exposing portions of the working electrodes and portions of the additional electrodes. Also, the method includes partially singulating individual sensors from the base layer, wherein each individual sensor is connected to the base layer by a tab. The method further includes depositing an enzyme layer over the exposed portions of the working electrodes and coating the working electrodes with a glucose limiting membrane.

An electrochemical detection electrode includes: a plurality of electrode structures; and a plurality of groups of detection structures on the plurality of electrode structures; wherein: the plurality of groups of detection structures include a first group of detection structures and a second group of detection structures, each of the first group of detection structures on one of the plurality of electrode structures having a first shape in a plane parallel to a surface of one of the plurality of electrode structures is configured to combine with a first detection object, each of the second group of detection structures on one of the plurality of electrode structures having a second shape in a plane parallel to a surface of one of the plurality of electrode structures is configured to combine with a second detection object; and wherein the first shape is different from the second shape.

Fluorophores are used during the synthesis of oligonucleotides to achieve real-time quality control of the synthesis process. Fluorescence may indicate successful addition of individual nucleotides to a growing oligonucleotide strand or removal of a blocking group. The oligonucleotides may be created by enzymatic synthesis using terminal deoxynucleotidyl transferase (TdT). The synthesis is performed on an addressable array so that oligonucleotides with different sequences are created in parallel on different regions of the array. The oligonucleotide sequences are predetermined and the locations of synthesis on the array are controlled. Observed fluorescence is compared to expected locations of fluorescence as determined by the oligonucleotide sequences and the arrangement on the array. Thus, the fidelity of oligonucleotide synthesis is checked as synthesis proceeds. If a variation is found, a mitigating action is taken such as repeating addition of a species of nucleotide or repeating a deblocking step.

The embodiments disclose an apparatus including a test cartridge configured for inserting into a reader, a sample insertion component coupled to the test cartridge a test sample, a heater device coupled to the test cartridge configured to heat to a predetermined temperature the test sample, a sensor array coupled to the test cartridge consisting of at least one electrochemical sensor for sensing analytes in a sample, a reader configured to gather test related data from the sensor array coupled to the test cartridge, an analyzer coupled to the reader configured for determining test results of each sensor in the sensor array and comparing all the test results for confirmation of a valid test and coherent results, a MCU (Microcontroller Unit) to perform main control and processing functions, and orchestrates all the functionality for the Reader, and a BLE Radio RF link between the MCU and an external processing system.

A lateral flow assay device comprises a test strip to receive a quantity of fluid comprising a quantity of exosomes and detect the presence of a target analyte on the surface of the exosomes. The test strip comprises a conjugate pad that contains a set of one or more types of tetraspanin binding reagents conjugated with a label. Each type of tetraspanin binding reagent is configured to bind with a corresponding type of exosome tetraspanin and form an immunocomplex comprising an exosome. The conjugate pad is fluidly connected to a membrane. The membrane comprises a test line comprising an immobilized binding reagent to the target analyte. The immobilized binding reagent to the target analyte is configured to bind to a protein of the target analyte on the surface of an exosome in an immunocomplex comprising the exosome.

Methods and techniques are described for analyzing test fluids to determine presence, absence, or concentration of analytes in the test fluids. The methods may correspond to diagnostic testing, such as quickly (within 5 minutes) identifying whether or not an individual may have a particular disease or condition, such as infection by SARS-CoV-2 or a SARS-CoV-2 variant or vaccine-induced immunity or natural immunity to infection by SARS-CoV-2 or a SARS-CoV-2 variant, or whether an individual would benefit from a vaccine booster. The test results can be used for a variety of applications including facilitating or controlling access at events, venues, or transportation systems, or generating exposure notifications.

The present application relates to detection units and methods for detecting one or more target analytes in a sample using a complex formed by a target and first and second probes, wherein the complex comprises an elongated region, a particle that is coupled to the first probe, and a solid support that is coupled to the second probe. Specific binding of a target analyte can be distinguished from non-specific binding of the particle by measuring the displacement of the particle.