Implementations relate generally to devices for measuring an analyte in a host. Implementations may provide reduced sizes for wearable devices including a transcutaneous analyte sensor for analyte measurement.

A stent device including a stent coated with a photosensitizer, the stent including a pair of electrodes; and a circuit fixed to the stent, the circuit including a light emitting diode, a power receiving means for wirelessly receiving power from the outside, and converting the power to electric power; a second communicating means for receiving a control command from the outside; and a second control means for applying, based on the control command, the electric power to the electrodes causing an electric current to flow through the stent between the electrodes, the flow causing heating of the stent, and for controlling a temperature of the stent to provide hyperthermia therapy to a tumor, the second control means further for applying, based on the control command, the electric power to the light emitting diode to emit a predetermined wavelength of light to the photosensitizer to provide photodynamic therapy to the tumor.

A system for a physiological characteristic sensor deployed with a sensor inserter includes an adhesive skin patch coupled to the physiological characteristic sensor. The adhesive patch is to couple the physiological characteristic sensor to an anatomy. The system also includes a gravity resistance system coupled to the adhesive patch and to be coupled to the sensor inserter. The gravity resistance system maintains the adhesive patch substantially perpendicular to a longitudinal axis of the sensor inserter prior to deployment of the physiological characteristic sensor and is removable from the adhesive patch by the sensor inserter upon deployment of the physiological characteristic sensor.

Systems configured to perform determining a measurement time period, generating a plurality of clock signals, receiving a plurality of analog signals during the determined measurement time period, the measurement time period establishing a maximum signal resolution associated with the clock and a sigma-delta modulator as a function of analog to digital conversion time to obtain a higher signal resolution, modulating the received plurality of analog signals to generate a frequency data stream over the measurement time period based on the received plurality of analog signals by synchronizing each of the received plurality of analog signals to a corresponding one of the generated plurality of clock signals, and filtering one or more signal artifacts from the frequency data stream over the measurement time period.

Systems configured to perform determining a measurement time period, generating a plurality of clock signals, receiving a plurality of analog signals during the determined measurement time period, the measurement time period establishing a maximum signal resolution associated with the clock and a sigma-delta modulator as a function of analog to digital conversion time to obtain a higher signal resolution, modulating the received plurality of analog signals to generate a frequency data stream over the measurement time period based on the received plurality of analog signals by synchronizing each of the received plurality of analog signals to a corresponding one of the generated plurality of clock signals, and filtering one or more signal artifacts from the frequency data stream over the measurement time period.

Disclosed are devices, systems and methods for in vivo monitoring of localized environment conditions within a patient user by measuring analytes, including glucose, oxygen, and/or other analytes. In some aspects, a sensor device includes a wafer-based substrate, at least one electrochemical sensor two-electrode contingent including a working electrode and a reference electrode on the substrate and configured to detect a target analyte in a body fluid when the sensor device is deployed within a subject's body, where the working electrode is functionalized by a chemical layer configured to facilitate a reaction involving the target analyte that produces an electrical signal; and an electronics unit in communication with the electrochemical sensor electrode contingent to transmit the electrical signal to an external processor.

Disclosed are devices, systems and methods for in vivo monitoring of localized environment conditions within a patient user by measuring analytes, including glucose, oxygen, and/or other analytes. In some aspects, a sensor device includes a wafer-based substrate, at least one electrochemical sensor two-electrode contingent including a working electrode and a reference electrode on the substrate and configured to detect a target analyte in a body fluid when the sensor device is deployed within a subject's body, where the working electrode is functionalized by a chemical layer configured to facilitate a reaction involving the target analyte that produces an electrical signal; and an electronics unit in communication with the electrochemical sensor electrode contingent to transmit the electrical signal to an external processor.

A probe for real-time sensing of a target biomarker the includes a needle, a luminescent probe within the opening of the needle, a coating comprising a biomarker luminescent material in contact with biological tissue, and an ion-consuming coating within the needle and adjacent to the coating. The disclosed probe is useful for real-time sensing of blood during medical procedures. Additionally, a biomarker detection system is disclosed that includes a biomarker luminescent material at the tip of or inside of the tip of a needle and an optical coupler.

A proto-microelectrode, a proto-microelectrode bundle and array, a method of manufacture of the proto-microelectrode, and a method of using the proto-microelectrode, the proto-microelectrode being capable of forming a microelectrode upon implantation into soft tissue, and includes an oblong electrode body; an optional first coat of electrically non-conducting material on the electrode body; a second coat of water insoluble flexible polymer material enclosing, at a distance, the electrode body and the first coat, the second coat including one or more through openings; a first layer of ice disposed between the electrode body and the second coat.

Provided are transdermal microneedle-based devices for sensing the presence and concentration of analytes such as electrolytes, biomarkers, drugs, and proteins in interstitial fluid. Also provided are methods and systems to transmit the data obtained by wired or wireless connection to a receiver and to relay the data to the user or a clinician.