This medical imaging device (1) such as in particular a TEE probe, able to be disinfected at least at intermediate level DNI/HLD in a UV radiation disinfection system, is characterized in that it comprises at least one part (3) made of a UV-transparent material to reduce the shadow areas on the device.

The present disclosure relates to methods and system for disinfecting surfaces within a volumetric space by forming peracids in a reaction layer in situ directly on the surfaces to be disinfected. Particularly, a peroxide compound and an organic acid are sequentially dispersed into the volumetric space, preventing peracids from being formed until the two reactants contact each other on the surface to be disinfected. In some embodiments, any of the dispersed aqueous compositions can optionally be electrostatically charged. Additionally, a system for sequentially dispersing the peracid reactant compounds by electrostatic spraying is provided.

Aspects of the present disclosure include a medical insufflation device for use on a patient body. The device includes a chamber, an ozone generator, an instrument, and a controller. The chamber is configured to receive a medical gas at least including oxygen. The ozone generator is in communication with the medical gas and configured to generate an ozonated medical gas by converting at least a portion of the oxygen in the medical gas into ozone. The instrument is configured to be introduced into the patient body. Further, the instrument is also configured to receive the ozonated medical gas from the chamber and convey the ozonated medical gas into the patient body. The controller is configured to control the device such that the ozonated medical gas conveyed to the patient body by the instrument is at a targeted amount of ozone.

A disinfection apparatus includes an installation member. The installation member includes a sealing member configured to seal a hole located in a ceiling, a nozzle configured to be placed in a ceiling space through the hole and spray a chemical solution to disinfect the ceiling space, a mount member configured to place the nozzle above the sealing member, and a fixing member configured to maintain a state in which the sealing member seals the hole.

A sterilization tray is disclosed herein. A medical instrument, such as an endoscope, may be placed into the sterilization tray, and the sterilization tray with the medical instrument disposed therein may be placed into a vacuum chamber of a sterilization system. The sterilization tray may also be used to transport the medical instrument to and from a point of care. Sterilization is performed with the instrument in the base component and the lid component disposed atop the base component. Transportation is performed with the instrument in the lid component and the base component disposed atop the lid component.

A container treatment system (1, 13) that has at least two working areas (AP). Each of the working areas (AP) respectively comprises at least one exchangeable working tool (2) and/or one adaptable format part. Furthermore, the container treatment system (1, 13) comprises at least one automatic exchange machine (10) which is movable, in particular drivable, to the at least two working areas (AP), which automatic exchange machine (10) can be connected selectively to any of the respective working areas (AP), in particular using centering means (22, 32), and which automatic exchange machine (10) comprises tools for exchanging the working tools (2) and/or for adapting the format parts of the respective working area (AP). The invention further relates to an automatic exchange machine (10) for exchanging working tools (2) and/or for adapting the format parts of at least two different working areas (AP) of a container treatment system (1, 13).

The present invention relates to a high-intensity ultraviolet light emitting diodes (6) (UV-LED) device (1) for preventing biofouling formation in a system for subsea operation of a target fluid. Further, the present invention discloses such device for coupling or integration into a subsea treatment system and to a process using such device.

A sterilization tray is disclosed herein. A medical instrument, such as an endoscope, may be placed into the sterilization tray, and the sterilization tray with the medical instrument disposed therein may be placed into a vacuum chamber of a sterilization system. The sterilization tray may also be used to transport the medical instrument to and from a point of care. Sterilization is performed with the instrument in the base component and the lid component disposed atop the base component. Transportation is performed with the instrument in the lid component and the base component disposed atop the lid component.

The present disclosure relates to methods and system for disinfecting surfaces within a volumetric space by forming peracids in a reaction layer in situ directly on the surfaces to be disinfected. Particularly, a peroxide compound and an organic acid are sequentially dispersed into the volumetric space, preventing peracids from being formed until the two reactants contact each other on the surface to be disinfected. In some embodiments, any of the dispersed aqueous compositions can optionally be electrostatically charged. Additionally, a system for sequentially dispersing the peracid reactant compounds by electrostatic spraying is provided.

A safety cabinet can include an enclosure defining an interior compartment accessible through an opening. The safety cabinet includes an interior lighting system. The interior lighting system can include at least one of an illuminating light to enable viewing to cabinet contents and an ultraviolet light configured to disinfect the interior compartment of the safety cabinet. To provide electrical power to the interior lighting system, the safety cabinet includes an electrical connection disposed through the enclosure. The electrical connection can include at least one of a bulkhead connector and an intumescent socket.