An irradiation system is provided which comprises a cabinet housing one or more X-ray tubes providing an irradiation source for a biomass contained within a cylindrical container arranged on a rotating device. The X-ray tubes generate directional X-ray beams and are provided in ultra-close proximity to the container, and the X-ray tubes can be configured to traverse the container. The rotational movement and traversal during the irradiation process ensure a more even irradiation of the entire biomass in the container.

Method for increasing efficiency of a pathogen inactivation via enhancing UVC light absorption at such pathogen by multiple diffuse scattering of the light at a wall defining a substantially closed volume, thereby increasing a number of angles at which the pathogen is being irradiate as compared with a direct irradiation of the pathogen with a beam of such light.

An electronic sanitizing device includes a germicidal light source and one or both of a red light source or a near infrared light source. The germicidal light source is configured to output germicidal light with a peak wavelength of 250 to 270 nanometers. The red light source is configured to output red light with a peak wavelength of 620 to 700 nanometers. The near infrared light source is configured to output near infrared light with a peak wavelength of 800 to 1200 nanometers.

A decontamination assembly, for pharmaceutical applications includes at least one chamber to be decontaminated (4) having a decontamination liquid storage tank (36) by which several atomizers (A, B, C. D) disposed in the chamber to be decontaminated (4) for producing a decontaminant aerosol can be supplied with decontamination liquid using valves (27) which can be controlled by electronic control, the atomizers (A, B, C, D) being in fluid communication with a ring conduit (32) having an inlet (33) and a separate outlet (34) by the valves (27), decontamination liquid from the decontamination liquid storage tank (36) being conveyable into the inlet of the ring conduit by a pump (35) and decontamination liquid flowing out of the outlet of the ring conduit back into the decontamination liquid storage tank (36), and a pressure adjustment mechanism (37) for keeping the pressure in the ring conduit (32) at a predefined liquid pressure range assigned to the ring conduit (32). A measuring mechanism (40) for determining a total volume of decontamination liquid dispensed to the atomizers (A, B, C, D) during a decontamination cycle includes a weighing mechanism (41) for determining a decontamination liquid volume in the decontamination liquid storage tank (36).

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 sanitization device may include an ozone operating system configured to generate ozone, a sanitization compartment, a distribution line fluidly coupling the ozone operating system to the sanitization compartment, and an adaptor disposed within the sanitization compartment. The adaptor may be configured to couple to a mask and may be further configured to be fluidly coupled to the distribution line such that ozone passes through the adaptor and into the sanitization compartment.

The invention concerns a storage device for cleaning and charging portable X-ray detectors, and an X-ray system comprising such storage device. The storage device comprises a receiving unit for receiving at least one portable X-ray detector, a cleaning unit for cleaning the portable X-ray detector when being received by the receiving unit, and a charging unit for charging the portable X-ray detector, wherein the cleaning unit is configured for mechanically and/or chemically cleaning the portable X-ray detector. Further, the invention concerns a method of cleaning and charging a portable X-ray detector in a storage device.

A dental pod that includes a receiver in a form of a cavity for receiving a distal end of a dental handheld device and one or more nozzles on a side of the receiver for cleaning and disinfecting the distal end of the dental handheld device. It also includes a cartridge compartment for receiving one or more cartridges support cleaning, setup, maintenance and other operations of and on the dental handheld device.

A container sanitizing system is provided. The system includes one or more containers, e.g., food containers, and a system to sanitize the containers. The container sanitizing system includes a sanitizing station adapted to receive the food containers and to irradiate the items with ultraviolet light at a sufficient intensity to sanitize and disinfect the items. The food containers are collapsible and may be folded into box-like food containers for the general storage of food, and subsequently, unfolded into a generally flat structure for sanitization within the sanitizing station. The system also includes a handheld sanitizing unit that is portable and/or mobile.

A fluid treatment system includes a reactor chamber fluidly coupled with a fluid inlet and a fluid outlet. The reactor chamber is defined by one or more chamber walls. The system includes a UV LED, and a light pipe. The light pipe extends into the reactor chamber through at least one of the chamber walls. The light pipe has a proximal end disposed outside of the reactor chamber. The proximal end is coupled with the UV LED to transmit UV light into the reactor chamber through the light pipe. To that end, the light pipe also has a distal end, opposite the proximal end, that is disposed within an interior volume of the reactor chamber. The light pipe includes a central section disposed between the proximal end and the distal end. The central section is configured to transmit the UV light from UV LED to the distal end.