A decontamination system, method, and sterilant kit for a device, such as a lumen device, is depicted. The decontamination system, in some embodiments, includes a device container, a wicking pad, and a sterilant fluid delivery device. The device container, such as a terminal package or a decontamination chamber, defines a device receiving area. The wicking pad is in fluid communication with the device receiving area. The sterilant fluid delivery device is in fluid communication with the wicking pad. The sterilant fluid delivery device is configured to wet the wicking pad with sterilant fluid. The wicking pad is configured to evaporate sterilant fluid into the device receiving area.

A technique is provided whereby hydrogen peroxide introduced into a working chamber containing a resin component is reduced to a low concentration in a shorter time than before. The present invention resides in a method of maintaining a sterile environment of a working chamber that contains a resin component, and includes a step (a) of introducing hydrogen peroxide into the working chamber, a step (b) of introducing air into the working chamber through a filter after completion of the step (a), a step (c) of generating ozone by irradiating the air with ultraviolet having a peak wavelength of from 160 nm to less than 200 nm upstream of the filter or inside the working chamber and introducing the ozone into the working chamber, and a step (d) of decomposing the ozone introduced into the working chamber into oxygen radicals.

The present disclosure relates to a glove arrangement (20) for mounting to a barrier wall (15) of a barrier system (10) comprising a sleeve arrangement (21). The first and second sleeves (40, 41) comprise first and second internal surfaces (90, 91). The intermediate sleeve (40) comprises an intermediate internal surface (92), an outer perimeter (61) attached to the first sleeve (40) and an inner perimeter (62) attached to the second sleeve (41), the outer perimeter (61) having a greater diameter than the inner perimeter (62). In an extended configuration the first sleeve (40) extends from the second and intermediate sleeves (40) for use during manipulation of the glove (22) by an operator. In a retracted configuration the second sleeve (41) is retracted at least partially inside the first sleeve (40) about the intermediate sleeve (40) such that the first and second internal surfaces (90, 91) at least partially face each other. The intermediate sleeve (40) separates the intermediate internal surface (92) from itself and from the first and second internal surfaces (90, 91) to form a cavity (48) between the first, second and intermediate internal surfaces (90, 91, 92).

Method for producing and discharging ultrapure hydrogen peroxide gas GPHU into the ambient air, said gas being substantially free of hygroscopic substances and substantially free of metals, primarily for use in bio-oxidative treatments via the blood stream by inhalation, for use in humans and animals. Said method comprises ultrapure hydrogen peroxide gas, alkaline nanostructured nanomaterial metal catalyst, special polymer nanocomposite material NPE and UV light. The ultrapure hydrogen peroxide gas is discharged into the ambient air naturally by the surface of the NPE. Equipment for producing and discharging ultrapure hydrogen peroxide gas into the ambient air is also disclosed.

The invention relates to an apparatus for vapour decontamination of an enclosed space. The apparatus comprises: (a) a reservoir comprising a supply of a liquid decontaminant; and (b) a vaporiser unit in fluid communication with the reservoir. The vaporiser unit comprises: a body that defines a lumen that passes along the length of the body, the lumen comprising a first end and a second end, wherein the first end receives liquid decontaminant from the reservoir; and a heating element that is configured to deliver sufficient thermal energy to effect rapid boiling of the liquid decontaminant within the lumen so that it exits the lumen via an exit port at the second end of the lumen as a vapour. The exit port is configured to deliver the vapour into a flow of a non-heated carrier gas, thereby facilitating distribution of the decontaminant vapour within the enclosed space. The invention also relates to a method for decontaminating surfaces within an enclosed space.

Methods of the present invention comprise photoinactivation of catalase in combination with low-concentration peroxide solutions and/or ROS generating agents to provide antibacterial effects.

Method and apparatus for generating, providing diffusion limited transport and evacuating gaseous phase material in a sub-atmospheric environment employing a molecular mobility enhancer (MME) component under reduced pressure to rapidly vaporize a liquid and/or solid, to transport generated vapor including a transport moiety into a diffusion processing zone and through diffusion restricted objects and to effectively evacuate non-consumed vapor from apparatus. Compositions, including solids, for delivery of MME-transport moiety vapor in a sub-atmospheric environment. Including those with improved storage and stability. Additionally, methods and apparatus for drying surfaces of articles in a sub-atmospheric environment. Compositions for generating a vapor in a sub-atmospheric environment for use in drying such articles. Methods and compositions herein useful for cleaning, sanitizing and sterilizing substrates, implements and devices including medical and electronic devices.

A modular surgical instrument system that comprises modular components and a control circuit electrically couplable to the modular components. The modular components comprise a shaft and a handle assembly. The handle assembly comprises a disposable outer housing. The disposable outer housing is movable between an open configuration and a closed configuration. The handle assembly further comprises a control inner core receivable inside the disposable outer housing in the open configuration. The disposable outer housing is configured to isolate the control inner core in the closed configuration. The modular components further comprise a loading unit releasably couplable to the shaft and a staple cartridge releasably couplable to an end effector. The loading unit comprises the end effector. The control circuit is configured to generate an interrogation signal, detect a response signal, determine a modular configuration of the modular surgical instrument system, and assess authenticity of the modular configuration.

The invention relates to a method and an apparatus for the plasma treatment of containers. The essential aspect according to the method according to the invention is that, after the plasma treatment at the plasma station and before the container is filled, at least the container interior of the container is at least partially ventilated with a sterilization medium, i.e. is loaded with a sterilization medium.

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.