An apparatus for insertion of a medical device in the skin of a subject is provided, as well as methods of inserting medical devices.

An apparatus for insertion of a medical device in the skin of a subject is provided, as well as methods of inserting medical devices.

An apparatus for insertion of a medical device in the skin of a subject is provided, as well as methods of inserting medical devices.

An apparatus for insertion of a medical device in the skin of a subject is provided, as well as methods of inserting medical devices.

A microsensor and method of manufacture for a microsensor, comprising an array of filaments, wherein each filament of the array of filaments comprises a substrate and a conductive layer coupled to the substrate and configured to facilitate analyte detection. Each filament of the array of filaments can further comprise an insulating layer configured to isolate regions defined by the conductive layer for analyte detection, a sensing layer coupled to the conductive layer, configured to enable transduction of an ionic concentration to an electronic voltage, and a selective coating coupled to the sensing layer, configured to facilitate detection of specific target analytes/ions. The microsensor facilitates detection of at least one analyte present in a body fluid of a user interfacing with the microsensor.

This inspection chip is provided with: a base plate having an inflow hole, a micro flow passage connected to the inflow hole, and a reaction chamber connected to the micro flow passage; a porous micro needle provided at a position overlapping the inflow hole and composed of a biodegradable material; a sensor disposed in the reaction chamber, and a capillary tube pump part which has a fine diameter flow passage, and is provided on the base plate and connected to the reaction chamber.

An apparatus for insertion of a medical device in the skin of a subject is provided, as well as methods of inserting medical devices.

A microsensor and method of manufacture for a microsensor, comprising an array of filaments, wherein each filament of the array of filaments comprises a substrate and a conductive layer coupled to the substrate and configured to facilitate analyte detection. Each filament of the array of filaments can further comprise an insulating layer configured to isolate regions defined by the conductive layer for analyte detection, a sensing layer coupled to the conductive layer, configured to enable transduction, and a selective coating coupled to the sensing layer, configured to facilitate detection of specific target analytes/ions. The microsensor facilitates detection of at least one analyte present in a body fluid of a user interfacing with the microsensor.

Methods for intra-mold sterilization of a plastic-embedded metal component of a product, such as a medical lancet having a metal needle embedded within a plastic lancet body. For example, a lancet needle is retained within a mold, plastic is injected to encapsulate the needle, and a specified minimum temperature is maintained for a specified minimum cycle time. In example forms, the specified minimum mold temperature is at least about 370 degrees Fahrenheit and the specified minimum cycle time is at least about 10 seconds.

Methods for mass production of new microfluidic devices are described. The microfluidic devices may include an array of micro-needles with open channels in fluid communication with multiple reservoirs located within a substrate that supports the micro-needles. The micro-needles are configured so as to sufficiently penetrate the skin in order to collect or sample bodily fluids and transfer the fluids to the reservoirs. The micro-needles may also deliver medicaments into or below the skin.