Systems and methods for minimizing or eliminating transient non-glucose related signal noise due to non-glucose rate limiting phenomenon such as ischemia, pH changes, temperatures changes, and the like. The system monitors a data stream from a glucose sensor and detects signal artifacts that have higher amplitude than electronic or diffusion-related system noise. The system replaces some or the entire data stream continually or intermittently including signal estimation methods that particularly address transient signal artifacts. The system is also capable of detecting the severity of the signal artifacts and selectively applying one or more signal estimation algorithm factors responsive to the severity of the signal artifacts, which includes selectively applying distinct sets of parameters to a signal estimation algorithm or selectively applying distinct signal estimation algorithms.

An analyte sensor system may include a first communication circuit configured to transmit a wireless signal in a first communication mode and a second communication mode, and a processor, wherein the processor determines whether a first condition is satisfied, the first condition relating to the sensor signal or to communication by the first communication circuit, and shifts the system to a second communication mode responsive to the first condition being satisfied.

An electrochemical sensor including a working electrode having an arrangement of pillars defining channels between the pillars. The channels increase confinement of a byproduct produced in an electrochemical reaction used during sensing of an analyte, so as to increase interaction of the byproduct with the working electrode. A number of working embodiments of the invention are shown to be useful in amperometric glucose sensors worn by diabetic individuals.

An electrochemical sensor including a working electrode having an arrangement of pillars defining channels between the pillars. The channels increase confinement of a byproduct produced in an electrochemical reaction used during sensing of an analyte, so as to increase interaction of the byproduct with the working electrode. A number of working embodiments of the invention are shown to be useful in amperometric glucose sensors worn by diabetic individuals.

Disclosed is a system and method for performing measurements on a biological subject, and in one particular example, to performing measurements of analytes in a biological subject by breaching a functional barrier of the subject using microstructures, wherein the one or more microstructures include an aptamer for binding one or more analytes.

Conformable and wearable sensors with integrated on-chip gate for the detection of biomolecules, chemicals, and other substrates and applications thereof are provided. Biosensor chips can be built with In2O3 nanoribbon field-effect transistors. Biosensor chips can conform to features of a human body, enabling ability for individuals to wear a biosensor.

Conformable and wearable sensors with integrated on-chip gate for the detection of biomolecules, chemicals, and other substrates and applications thereof are provided. Biosensor chips can be built with In2O3 nanoribbon field-effect transistors. Biosensor chips can conform to features of a human body, enabling ability for individuals to wear a biosensor.

Disclosed embodiments include methods and systems including a receiver unit of a glucose monitoring system. The receiver is configured for communicating with a remote transmitter unit coupled with a glucose sensor. The glucose sensor generates data signals associated with a glucose level. The receiver unit includes a processor, a display, and a memory for storing instructions which, when executed by the processor: access a transmitter key associated with the remote transmitter unit; transmit a command to the remote transmitter unit after verifying the transmitter key; receive communication packets from the remote transmitter unit including a first data segment with data signals indicative of the glucose level and a second data segment with information corresponding to a remaining life of the remote transmitter unit; estimate a remaining life of the remote transmitter unit; process the data signals; and output the estimated remaining life and the processed data signals for display.

Disclosed are a biosensor structure for sample measurement and a sample measuring method using same. In a biosensor electrode structure for sample measurement according to an embodiment of the present invention, a working electrode, which is an electrode for measuring a sample, and a reference electrode are arranged to be spaced apart from each other in the longitudinal direction of a sample insertion channel, a working protrusion, which is a protrusion of the working electrode, and two reference protrusions, which are protrusions of the reference electrode, are alternately arranged at a part corresponding to the sample insertion channel, the ratio of the area of the working protrusion to the areas of the reference protrusions is equal to or greater than 1, at least one recognition electrode for recognizing the sample is disposed adjacent to the working electrode or the reference electrode and parallel to the working electrode and the reference electrode while being spaced apart from the working electrode and the reference electrode, and the at least one recognition electrode has at least one recognition protrusion which is a protrusion disposed at the part corresponding to the sample insertion channel.

Disclosed is a wearable microneedle sensor platform for minimally-invasive, real-time monitoring of key biomarkers. In some aspects, a device includes a wearable epidermal sensor comprising an array of hollowed needles, each hollowed needle having a protruded needle structure including multiple layers forming a hollow interior, at least one hollowed needle including a working electrode to interact with one or more chemical or biological substances that come in contact with the protruded needle structure, at least one hollowed needle including a counter electrode to measure an electrical potential difference with the working electrode; and a wireless transmitter in communication with the sensor to generate output signals based on the electrical potential difference with the working electrode. The output signal represents β-hydroxybutyrate as a biomarker of ketone bodies.