The present embodiments relate generally to applicators of on-skin sensor assemblies for measuring an analyte in a host, as well as their method of use and manufacture. In some aspects, an applicator for applying an on-skin sensor assembly to a skin of a host is provided. The applicator includes an applicator housing, a needle carrier assembly comprising an insertion element configured to insert a sensor of the on-skin sensor assembly into the skin of the host, a holder releasably coupled to the needle carrier assembly and configured to guide the on-skin sensor assembly while coupled to the needle carrier assembly, and a drive assembly configured to drive the insertion element from a proximal starting position to a distal insertion position, and from the distal insertion position to a proximal retraction position.

An applicator for an analyte monitoring device may include an actuatable housing having a body defining a cavity therein and having a distal opening and a side opening. A cuff and a shuttle are received within the cavity and are separately translatable relative to the housing body. A base may removable engage the housing body at the distal opening. The housing body, the cuff, the shuttle, and/or the base may be engaged with one another with one or more releasable coupling features. The base may be removed from an engagement with the housing body, causing the cuff and the shuttle to be aligned and positioned in a configuration in which the analyte monitoring device, held by the shuttle, is ready for insertion into the skin.

A system and method for monitoring body chemistry of a user, the system comprising: a housing supporting: a microsensor comprising a first and second working electrode, a reference electrode, and a counter electrode, and configured to access interstitial fluid of the user, and an electronics subsystem comprising a signal conditioning module that receives a signal stream, from the microsensor, wherein the electronics subsystem is configured to detect an impedance signal derived from two of the first working electrode, the second working electrode, the reference electrode, and the counter electrode; and a processing subsystem comprising: a first module configured to generate an analysis indicative of an analyte parameter of the user and derived from the signal stream and the impedance signal, and a second module configured to transmit information derived from the analysis to the user, thereby facilitating monitoring of body chemistry of the user.

Articles and systems configured for treating GI motility disorders are generally provided. In some embodiments, an article comprising one or more electrodes (with both sensing and stimulating capabilities) may be configured to stimulate one or more tissues in the GI tract, electrically and/or chemically, to modulate peristalsis and/or allow neuromodulation. In some embodiments, a system comprises a controller that allows for close-loop operation of the article, e.g., such that the article may stimulate (e.g., via a feedback loop) the one or more organs in the GI tract upon receiving sensed parameters in the GI tract. In some embodiments, an implantation tool comprising a sensor may allow for submucosal or intramuscular implantation of an article. The implantation tool and the article may be useful for, for example, as a general platform for delivery of treating GI motility disorders and/or neuromodulation of the GI tract.

An insertion device is proposed for implanting a flexible implantable strip in the cortex of a living being in a reliable and accurate manner. The insertion device comprises a wire maintained within a lumen of a penetration member so that a free tip portion configured to engage an anchoring hole of the implantable strip protrudes from a distal end of the penetration member Thanks to reduced dimensions of the tip portion of the wire compared to that of the implantable strip, removing the wire from the lumen results in the implantable strip being released from the penetration member while still adhering to the cortex. The wire may be withdrawn by pulling at an end portion opposite to the tip portion. The penetration member can be chosen among a needle and a tube

Systems for applying a transcutaneous monitor to a person can include a telescoping assembly, a sensor, and a base with adhesive to couple the sensor to skin. The sensor can be located within the telescoping assembly while the base protrudes from a distal end of the system. The system can be configured to couple the sensor to the base by compressing the telescoping assembly.

An apparatus for insertion of a medical device in the skin of a subject is provided, as well as methods of inserting medical devices. Embodiments include removing a substantially cylindrical cap from an inserter to expose a substantially cylindrical sleeve, removing a cover from a substantially cylindrical container holding sensor components, and fitting the sensor components into the inserter.

One aspect of the present disclosure can include an intrafascicular neural electrode. The intrafascicular neural electrode can include a microwire body having a proximal end, a distal anchoring end, and a middle portion extending between the proximal end and the distal anchoring end. The distal anchoring end can substantially match the mechanical and biological properties of the target nerve. The microwire body can have a middle anchoring portion extending between the proximal end and the distal end, wherein at least a portion of the distal end and/or the middle anchoring portion substantially match(es) the mechanical and biological properties of the target nerve. The electrode can be made of graphene. The microwire body, except for the distal anchoring end, can be coated with an insulation material, preferably with a biocompatible agent adsorbed onto the insulation material.

An apparatus includes a body and an actuator is coupled to the body. A needle is mounted to the actuator. The needle comprises a slot along a length to a tip. A sensor is coupled to a plurality of wires. A base is configured to be moveable by the actuator and includes a cutout, a circuit board having a microprocessor, and a plurality of contacts. Each contact is coupled to a wire of the plurality of wires. A power source is connected to the circuit board and to the base. A bracket is coupled to the bottom surface of the body and configured to receive the base. A patch is coupled to the bracket and has an adhesive. A needle is configured to be moveable by the actuator. The plurality of wires extend from the circuit board of the base, through the needle and out of the slot.

A contact assembly for electrically interconnecting at least two modules is disclosed. The contact assembly has a first module having a first contact pad and a second module having a second contact pad. The first and second contact pads are arranged nonparallel to one another. One of the first and second contact pads exerts pressure on an electrically conductive elastomer to thereby deform it, and the deformation results in the other one of the first and second contact pads being contacted by the electrically conductive elastomer. An electrochemical sensor may be part of the first module and an electronics assembly may be part of the second module. An insertion needle may also be provided to insert the sensor transcutaneously. Associated methods are disclosed.