An ultraviolet (UV) light sanitizing system includes an electromagnetic interference (EMI) reducing cover configured to couple to a housing of a UV lamp assembly having a UV light source that is configured to emit UV light through a light outlet of the housing. The EMI reducing cover is further configured to be disposed one or more of within, below, or over the light outlet. The EMI reducing cover includes one or more grids including beams and light openings defined between the beams. The light openings provide open areas through which the UV light emitted from the UV light source passes, and wherein the EMI reducing cover includes at least 90% open space. In at least one embodiment, the beams include at least one surface that is transverse to a direction of the UV light that is to be emitted from the UV light source. In at least one embodiment, wherein the EMI reducing cover includes an interior grid and an exterior grid.

A sterilizing mouthpiece assembly for reducing the airborne transmission of infectious diseases includes a mouthpiece for positioning in a user's mouth. A shelf is integrated into the mouthpiece and a wedge extends upwardly from the shelf. A plurality of first light emitters is each of the first light emitters is integrated into the mouthpiece and each of the first light emitters emitting light in the ultraviolet spectrum to sterilize the inside of the user's mouth. A plurality of second light emitters is each positioned on the wedge and each of the second light emitters emits light in the ultraviolet spectrum to sterilize the inside of the user's mouth.

Systems and methods for performing Direct Sodium Removal (DSR) therapy are provided in which an implantable device includes a pump coupled to an inlet catheter designed for placement in a patient's peritoneal cavity, an outlet catheter designed to be coupled to the patient's bladder, and is operably coupled to an analyte sensor, the pump programmed to transfer and/or cease transfer of fluid from the patient's peritoneal cavity to the patient's bladder for voiding responsive to a level of analyte detected by the analyte sensor. In addition, the system may include a processor that computes an amount of analyte transferred per pumping session.

A light radiation device includes a housing, a substrate provided in the housing, and a light source mounted on the substrate. The light source includes a first light source including at least one first light source to emit first light having a blue wavelength band, a second light source including at least one second light source to emit second light having a ultraviolet wavelength band, and a control unit to control the first light source and the second light source such that the second light source sequentially emits the second light after the first light source emits the first light. A dose of the second light source is less than 1/10 of a dose of the first light source.

Methods and compositions for the prevention or reduction of platelet transfusion associated complications are provided. The subject methods include modifying donor whole blood or platelets prior to transfusion to prevent or reduce alloimmune platelet refractoriness.

The current pandemic due to Covid-19 stresses the importance of effectively treating highly contagious and deadly infections. The described medical device is meant to help the medical community by enabling them to treat patients more effectively. The delivery mechanism focuses on the mucous membrane. It is noninvasive and easy to use by patients directly. The device is hand-held, with incorporated germicidal UVC lights. It has two chambers connected by an internal application tip. The tip connects to a removable container which can be used with the prescribed treatment/therapy, vaccine, or viral testing fluid/reagent, as needed. Due to its versatility, non-invasive nature and germicidal properties, this device supports rapid response to infectious diseases, such as COVID-19. It may also further promote the development and use of different inoculation and drug techniques and delivery systems by enabling easy administration, via the mucous membrane.

The invention is an apparatus having a protective envelope which is designed and constructed to envelope at least one room region, such that the protective envelope is able to separate the at least one room region from an environment immediately surrounding the protective envelope, and use thereof. Methods for operating a production engineering unit under cleanroom conditions and for creating and operating a virus-free and cross-contamination free room region surrounded by a protective envelope for accommodating persons and/or objects subject to quarantine. The invention has a protective envelope with at least two layers separated by a spacer layer, that is flow-permeable.

A system for disinfecting a medical device is disclosed that includes an elongate instrument comprising a plurality of optical fibers extending along a length of the instrument to a disinfection zone, and a light source coupled with the instrument configured to propagate light distally along the optical fibers. The elongate instrument can be configured to redirect the light radially outward from the instrument. An elongate instrument for disinfecting a medical device can include a plurality of optical fibers extending along a length of the instrument from a proximal end to a disinfection zone at a distal end, the optical fibers configured to propagate a light along the instrument. One or more reflective surfaces can be located within the disinfection zone, and the reflective surfaces can be configured to direct the light radially outward from the instrument.

Provided is a novel method that makes it possible to easily sterilize spores and the like in a highly safe manner. A method for producing radicals according to the present invention includes a generation step of generating radicals through photoirradiation of a radical generation source, and the peak wavelength of light used in the photoirradiation is greater than UV wavelengths and 600 nm or less. Also, a method for sterilizing spores according to the present invention includes a treatment step of generating radicals through photoirradiation of a radical generation source and treating spores with the radicals, and the peak wavelength of light used in the photoirradiation is greater than UV wavelengths and 600 nm or less. The peak wavelength is, for example, 405 to 470 nm.

Certain exemplary embodiments can provide an apparatus and method for generating at least one radiation. The exemplary apparatus and/or method can selectively kill and/or affect at least one bacteria. For example, a radiation source first arrangement can be provided which is configured to generate at least one radiation having one or more wavelengths provided in a range of about 190 nanometers (nm) to about 230 nm, and at least one second arrangement can be provided which is configured to prevent the at least one radiation from having any wavelength that is outside of the range.