Abstract: A wearable sensor patch including a generally cylindrical base having a bore, and a skin contact surface having an adhesive thereon; a piston-like part positioned within the bore; at least one microprobe positioned on the piston-like part; a retention spring; wherein the piston-like part is movable within the bore of the base between (1) a first position in which the at least one microprobe is positioned within the bore, and (2) a second position in which the at least one microprobe protrudes past the skin contact surface, and wherein the retention spring and the piston-like part are configured to cooperate such that the retention spring retains the piston-like part in either the first position or the second position

Abstract: 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.

Abstract: A sensing system includes a microprobe, the microprobe including: a layered structure including: a sensing unit comprising a sensor including a working electrode, wherein the sensing unit has a first perimeter when viewed along a layering direction, includes a first material having a first toughness, and including a first side and a second side; a deformable layer configured to deform under stress and positioned on the first side of the sensing unit; a ductile layer positioned on the deformable layer opposite the sensing unit and having a second perimeter when viewed along the layering direction, the first perimeter being within the second perimeter, the ductile layer including a second material having a second toughness greater than the first toughness; a sensor-interface layer positioned on the second side of the sensing unit; and an encapsulant partially encapsulating the layered structure and mechanically isolating the layered structure from a surrounding environment.

Abstract: 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.

Abstract: 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.