Various analyte sensing apparatuses and associated housings are provided. Some apparatuses comprise one or more caps. Some apparatuses comprise a two-part adhesive patch. Some apparatuses comprise one or more sensor bends configured to locate and/or hold a sensor in place during mounting. Some apparatuses utilize one or more dams and/or wells to retain epoxy for securing a sensor. Some apparatuses utilize a pocket and one or more adjacent areas and various transitions for preventing epoxy from wicking to undesired areas of the apparatus. Some apparatuses include heat-sealable thermoplastic elastomers for welding a cap to the apparatus. Related methods of fabricating such apparatuses and/or housings are also provided.

A sensor insertion assembly includes: a sensor insertion device comprising a needle member configured to be inserted in a living body together with a biological information sensor and to be pulled out of the living body after leaving a distal end side of the sensor in the living body; and a base plate detachably attached to a first end side of the sensor insertion device, the base plate comprising a clamp portion configured to move so as to clamp a proximal end side of the sensor extending to an outside of the living body after pulling out the needle member and along with an operation of detaching the sensor insertion device from the base plate.

Applicators for applying an on-skin assembly to skin of a host and methods of their use and/or manufacture are provided. An applicator includes an insertion assembly configured to insert at least a portion of the on-skin assembly into the skin of the host, a housing configured to house the insertion assembly, the housing comprising an aperture through which the on-skin assembly can pass, an actuation member configured to, upon activation, cause the insertion assembly to insert at least the portion of the on-skin assembly into the skin of the host, and a sealing element configured to provide a sterile barrier and a vapor barrier between an internal environment of the housing and an external environment of the housing.

A simple, disposable sensing device for sensing an analyte is housed in a single case. The sensing device can transmit sensor data to monitoring device(s). The sensing device includes: a case having a lower major wall adapted to be mounted against a patient's skin, and an upper opposing major wall; a sensor extending from the case and having a distal end sensitive to the analyte to produce an electrical signal, and a proximal end within the case having electrical contacts; a printed circuit board assembly within the case supported by one of the major walls to receive the electrical signal via the electrical contacts; and an elastomeric pad disposed in the case and biased by the other major wall to urge the proximal end of the sensor into contact with the printed circuit board assembly and maintain an electrical connection between the electrical contacts and the printed circuit board assembly.

A simple sensing device includes a case with one or more indicators to indicate levels of an analyte such as glucose. The sensing device for self-monitoring an analyte includes a single, flexible case adapted to adhere to a skin of a patient. It also includes a printed circuit board assembly inside the case. It further includes a first sensor extending from the flexible case and electrically coupled to the printed circuit board, and one or more indicators in the flexible case, where the indicator(s) are adapted to indicate whether a level of an analyte is within a normal range.

A neuromonitoring needle electrode placement gun which includes a housing, at least a first needle electrode and housing assembly, an elongated channel dimensioned and configured for accommodating axial movement of the at least a first needle electrode and housing assembly within the channel and for directing movement of the at least a first needle electrode and housing assembly and a pusher dimensioned and configured for engaging the at least a first needle electrode and housing assembly and for axially displacing the at least a first needle electrode and housing assembly.

An analyte measurement kit includes a sensor assembly having a transcutaneous sensor and a controller. The controller includes a battery that powers the sensor assembly and includes a magnetic sensor that generates an electrical activation signal in dependence of a magnetic field. The controller switches from a pre-operative state into an operative state upon generation of the activation signal. The sensor assembly releasably couples to an inserter. The inserter executes an insertion routine that advances the sensor assembly from a retracted position in which the transcutaneous sensor stands back behind a skin contact surface of the inserter into an advanced position in which the transcutaneous sensor projects beyond the skin contact surface, and subsequently decouples the inserter from the sensor assembly. The inserter includes an activation magnet. Executing the insertion routine changes the magnetic coupling between the activation magnet and the sensor assembly and thereby generates the activation signal.

The present invention relates generally to systems and methods for measuring an analyte in a host. More particularly, the present invention relates to systems and methods for transcutaneous measurement of glucose in a host.

An electrochemical sensing system includes a working electrode and a reference electrode, which can at least partially be disposed in a housing. At least a portion of the working electrode includes rhodium metal. An electrical circuit is disposed in the housing and configured to be electronically coupled to the electrodes. The electrical circuit is operative to: (a) bias the working electrode at a voltage of less than about 0.4 V, and (b) measure a current corresponding to the concentration of the target analyte. A communications module is electrically coupled to the electrical circuit and configured to display a concentration of the target analyte, and/or communicate data between the electrical circuit and an external device. The electrodes are movable between a first configuration in which the electrodes are substantially disposed inside the housing, and a second configuration in which at least a portion of the electrodes is disposed outside the housing.

Systems and methods for transcutaneously implanting medical devices, such as in vivo analyte sensors, are provided. The systems and methods involve the use of introducers or inserters made of shape memory alloy (SMA) materials which are transitionable from one operative state or configuration to another operative state or configuration, wherein the transition from state to state enables the transcutaneous implantation and/or transcutaneous explantation of the medical device.