Disclosed herein are systems and methods of use thereof for coupling affinity reagents (e.g., in solution affinity reagents such as proteins, peptides, and nucleic acids and libraries of affinity reagents) with particles having coronas for rapid detection of proteins in a sample.

Disclosed herein are systems and methods of use thereof for coupling affinity reagents (e.g., in solution affinity reagents such as proteins, peptides, and nucleic acids and libraries of affinity reagents) with particles having coronas for rapid detection of proteins in a sample.

Provided are a kit and a method for detecting target nucleic acids using magnetic nanoparticles. The kit for detecting target nucleic acids includes a reactor having an opening on one side and provided with a sample containing target nucleic acids, at least one magnetic nanoparticle part provided in the reactor, a conductive substrate provided to cover the opening of the reactor, and a magnetic field applying part for applying a magnetic field to the reactor, in which the magnetic nanoparticle part includes a magnetic nanoparticle including a core portion made of iron oxide and a shell portion made of gold and provided to surround the core portion, and a primer attached to the shell portion of the magnetic nanoparticle.

This disclosure relates to biosensors, and in particular, biosensors based on nucleic acid cleaving enzymes such as ribonucleotide-cleaving DNAzymes for the detection of analytes, and methods of use.

This disclosure relates to biosensors, and in particular, biosensors based on nucleic acid cleaving enzymes such as ribonucleotide-cleaving DNAzymes for the detection of analytes, and methods of use.

This disclosure relates to biosensors, and in particular, biosensors based on nucleic acid cleaving enzymes such as ribonucleotide-cleaving DNAzymes for the detection of analytes, and methods of use.

Methods, systems, and devices for sampling/isolating material from cells. An exemplary system may comprise a chip including an electrode array of sampling electrodes arranged along a surface of the chip. A cell-receiving area may be located adjacent the surface of the chip. The system also may comprise a tag array of tags supported by the chip and aligned with the electrode array. Each tag of the tag array may include an identifier that is unique to the tag within the tag array. Each tag may be configured to bind nucleic acids, or a capturing agent distinct from the tag may be aligned with each sampling electrode of the electrode array to capture a protein or other analyte of interest. The system further may comprise a control circuit configured to apply an individually controllable voltage to each sampling electrode of the electrode array and measure an electrical property of the sampling electrode.

Methods, systems, and devices for sampling/isolating material from cells. An exemplary system may comprise a chip including an electrode array of sampling electrodes arranged along a surface of the chip. A cell-receiving area may be located adjacent the surface of the chip. The system also may comprise a tag array of tags supported by the chip and aligned with the electrode array. Each tag of the tag array may include an identifier that is unique to the tag within the tag array. Each tag may be configured to bind nucleic acids, or a capturing agent distinct from the tag may be aligned with each sampling electrode of the electrode array to capture a protein or other analyte of interest. The system further may comprise a control circuit configured to apply an individually controllable voltage to each sampling electrode of the electrode array and measure an electrical property of the sampling electrode.

This transistor sensor includes a substrate, a channel layer provided over one surface of the substrate, and a solid electrolyte layer provided between the substrate and the channel layer or over a surface of the channel layer on an opposite side to the substrate side, in which the channel layer includes an inorganic semiconductor, the solid electrolyte layer includes an inorganic solid electrolyte, and at least a portion of either one or both of the channel layer and the solid electrolyte layer includes an exposed portion exposed to outside.

This transistor sensor includes a substrate, a channel layer provided over one surface of the substrate, and a solid electrolyte layer provided between the substrate and the channel layer or over a surface of the channel layer on an opposite side to the substrate side, in which the channel layer includes an inorganic semiconductor, the solid electrolyte layer includes an inorganic solid electrolyte, and at least a portion of either one or both of the channel layer and the solid electrolyte layer includes an exposed portion exposed to outside.