Abstract: Disclosed is a wearable device with improvements to microneedles in a microneedle array including an off-center tip, a deflection guide indention, amorphous cavities which help the microneedles to bend during insertion into the skin. As the microneedles bend back after insertion, a number of sills extending from the microneedles help to hold the microneedles in place. Less damage is done to the microneedles and the surrounding tissue, thus reducing inflammation.

Abstract: Methods, systems, and devices are disclosed for collecting and transferring naturally-produced sweat containing an analyte to a biosensor and/or biofuel cell to estimate a concentration of the analyte corresponding to the analyte's concentration in blood and/or for producing electricity. In some aspects, a device includes a substrate, a plurality of electrodes disposed on the substrate and operable to detect an analyte in naturally-produced sweat of an individual, and a sweat permeation layer including a hydrogel, wherein the sweat permeation layer is in contact with the plurality of electrodes and configured to transfer the sweat containing the analyte through the sweat permeation layer to reach the plurality of electrodes for detection and/or energy harvesting.

Abstract: Disclosed here are devices, systems, and methods for continuous monitoring of biomarkers using a wearable, non-intrusive microneedle sensor patch platform. In some aspects, a wearable, non-intrusive microneedle sensor device includes a microneedle sensor unit couplable to an electronics unit, where the microneedle sensor unit comprises a substrate, an array of spiked microneedle structures configured as electrochemical sensor electrodes, an array of base structures that encase a lower portion of spiked microneedle structures, and electrical interconnections that electrically couple the electrodes to the electronics unit for processing of detectable signals associated with one or multiple biomarkers in a biofluid.

Abstract: Disclosed here are devices, systems, and methods for continuous monitoring of biomarkers using a wearable, non-intrusive microneedle sensor patch platform. In some aspects, a wearable, non-intrusive microneedle sensor device includes a microneedle sensor unit couplable to an electronics unit, where the microneedle sensor unit comprises a substrate, an array of spiked microneedle structures configured as electrochemical sensor electrodes, an array of base structures that encase a lower portion of spiked microneedle structures, and electrical interconnections that electrically couple the electrodes to the electronics unit for processing of detectable signals associated with one or multiple biomarkers in a biofluid.

Abstract: Disclosed here are devices, systems, and methods for continuous monitoring of biomarkers using a wearable, non-intrusive microneedle sensor patch platform. In some aspects, a wearable, non-intrusive microneedle sensor device includes a microneedle sensor unit couplable to an electronics unit, where the microneedle sensor unit comprises a substrate, an array of spiked microneedle structures configured as electrochemical sensor electrodes, an array of base structures that encase a lower portion of spiked microneedle structures, and electrical interconnections that electrically couple the electrodes to the electronics unit for processing of detectable signals associated with one or multiple biomarkers in a biofluid.

Abstract: Disclosed are systems, devices and methods for continuous and simultaneous monitoring of multiple analytes within interstitial fluid by an integrated system for a microneedle array sensor platform. In some aspects, the device includes a microneedle array sensor unit, an electronics unit and a housing structure. The electronics unit is in electrical communication with an array of electrode probe structures via an array of surface-mount, spring loaded pins, and the electronics unit includes a power source, a data processing unit, and a wireless transmitter. The housing structure is configured to encase, at least partially, the microneedle array sensor unit and the electronics unit, where the array of microneedles is exposed from a side of the housing structure. The device can be configured as a patch worn on skin of a patient user.

Abstract: Disclosed here are devices, systems, and methods for continuous monitoring of biomarkers using a wearable, non-intrusive microneedle sensor patch platform. In some aspects, a wearable, non-intrusive microneedle sensor device includes a microneedle sensor unit couplable to an electronics unit, where the microneedle sensor unit comprises a substrate, an array of spiked microneedle structures configured as electrochemical sensor electrodes, an array of base structures that encase a lower portion of spiked microneedle structures, and electrical interconnections that electrically couple the electrodes to the electronics unit for processing of detectable signals associated with one or multiple biomarkers in a biofluid.

Abstract: Methods, apparatus, systems, and methods are described that relate to microneedle-assisted aptamer-based electrochemical sensing for label-free, continuous real-time monitoring of biomarkers in a biofluid. One example device for electrochemical monitoring of one or more analytes in a biofluid includes a substrate and at least two microneedles coupled to the substrate. Each microneedle in the at least two microneedles includes a protruded needle structure and an electrode probe structure. The electrode probe structure of a first microneedle in the at least two microneedles includes an aptamer sequence which is specific for a first analyte and the electrode probe structure of the first microneedle is operable as a working electrode for detection of the first analyte using a first electrochemical detection technique.

Abstract: 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 ?-hydroxybutyrate as a biomarker of ketone bodies.

Abstract: Disclosed are devices, systems and methods for monitoring one or more biomarkers using an electrochemical immunosensor sensor with an integrated enzymatic and immunosensing electrochemical detection capability. In some aspects, an electrochemical sensor device for monitoring glucose and insulin includes a substrate; and a plurality of electrodes disposed on the substrate, the plurality of electrodes including a first electrode to sense glucose, a second electrode to sense insulin, and a counter electrode to the first and second electrodes, in which the first electrode includes a glucose oxidase enzyme linked to a surface of the first electrode, and the second electrode includes an insulin capture antibody linked to a second electrode through a self-assembly monolayer, and in which, when the device is electrically coupled to an electronics unit, the device is operable to detect insulin and glucose from a fluid.