An on-body injector system includes a drug container assembly including a container, a seal member, and a sealing interface between the seal member and the container. The container includes an opening and the seal member at least partially covers the opening in the container. A fluid pathway assembly is coupled to the drug container assembly and includes a needle that is movable between a storage position, in which a point of the needle is spaced from the seal member, and a delivery position, in which the point of the needle is disposed at least partially through the seal member. A radiation generator is configured to emit rays of radiation to sterilize and/or disinfect the sealing interface. A barrier is disposed adjacent to the sealing interface and has an opening. At least a portion of the drug container assembly is positioned adjacent to the opening in the barrier.

A surface coating configured to locally enhance ultraviolet light density of ultraviolet light incident on the surface coating. The surface coating includes a dielectric layer, a conductive layer on the dielectric layer, a series of nano-openings in the dielectric layer and the conductive layer, a series of nano-antennae in the series of nano-openings, and a dielectric gap between the series of nano-antennas and the conductive layer. The conductive layer and the nano-antennae both include a UV plasmonic material.

If one sterilizes pre-packed, plastic chromatography columns with an appropriate level of gamma irradiation, the resulting sterile chromatography columns maintain sufficient packing media function and maintain column mechanical properties and pressure ratings.

A treatment system for treating or sterilizing products includes a particle accelerator configured to produce a beam of charged particles, a deflector configured to redirect the beam of charged particles, a vacuum chamber that prevents the atmosphere from interfering with the charged particles, and a magnet array for directing the beam of charged particles onto a product, wherein the beam of charged particles is used to sterilize the product.

An aseptic chamber of a package producing machine is provided. The aseptic chamber comprises an entry section for allowing a web of packaging material to enter the aseptic chamber, and at least one electron beam emitter arranged downstream the entry section for treating the web of packaging material it runs through the aseptic chamber. The entry section comprises an entry chamber arranged between an infeed gasket and an inner gasket.

An on-body injector system includes a drug container assembly including a container, a seal member, and a sealing interface between the seal member and the container. The container includes an opening and the seal member at least partially covers the opening in the container. A fluid pathway assembly is coupled to the drug container assembly and includes a needle that is movable between a storage position, in which a point of the needle is spaced from the seal member, and a delivery position, in which the point of the needle is disposed at least partially through the seal member. A radiation generator is configured to emit rays of radiation to sterilize and/or disinfect the sealing interface. A barrier is disposed adjacent to the sealing interface and has an opening. At least a portion of the drug container assembly is positioned adjacent to the opening in the barrier.

A drug delivery sterilization system includes a housing defining at least one receptacle, a container assembly having first and second ends, an elongated portion extending therebetween, and an electron beam or x-ray generator disposed near the housing. The container assembly includes a container having a container contact region at the second end and an inner volume to contain a medicament, a seal member having a seal member contact region to form a sealing interface with the container contact region, and a coupling device adapted to sealingly couple the seal member to the container. The container assembly is at least partially disposed in the receptacle such that the second end of the container is exposed through the housing. The electron beam or x-ray generator generates a sterilizing beam that penetrates the seal member to sterilize the sealing interface.

A system includes a sensor applicator, a sensor control device arranged within the sensor applicator and including an electronics housing and a sensor extending from a bottom of the electronics housing, and a cap coupled to one of the sensor applicator and the sensor control device, wherein the cap is removable prior to deploying the sensor control device from the sensor applicator.

A product allows gaseous manufacturing by-products to be vented from the inside a sealed package tray. An exemplary method for packaging a device includes sealing the device inside a package tray with a gas-permeable sealing material, resulting in a sealed package tray. The sealing material allows volatile substances to vent from inside the sealed package tray to outside the sealed package tray.

A method of making a ready-to-use catheter assembly is provided, which can be immediately used by a patient. The ready-to-use catheter assembly ensures that the catheter does not suffer from a loss of quality during its shelf life and a wetting medium are provided. The method comprises: placing a catheter with an inactivated hydrophilic outer surface at least along its insertable length and a wetting medium in a catheter package; treating the catheter package with the catheter and the wetting medium with electro-magnetic and/or particle radiation while at least initially the hydrophilic outer surface at least along the insertable length of the catheter remains inactivated; and activating the hydrophilic outer surface at least along the insertable length of the catheter with the wetting medium during and/or after the radiation treatment and wherein the wetting medium decreases in viscosity when submitted to electro-magnetic and/or particle radiation.