A valuable media sanitizing/cleansing cassette is provided for sanitizing/cleansing surfaces of valuable media dispensed to a consumer during a dispense transaction at a transaction terminal. Dispensed media is urged from one or more media cassettes within the terminal along a transport path. The transport path is altered to pass the media through the sanitizing/cleansing cassette where the top and bottom surfaces of the media are illuminated with Ultraviolet (UV) radiation to eradicate any bacteria or virus that may be adhered to the top or the bottom surfaces of the media. Once the media passes through the sanitizing/cleansing cassette, the now sanitized/cleansed media is urged along a remainder of the transport path and dispensed from a media interface of the terminal to the consumer. In an embodiment, media deposited at the terminal is also sanitized/cleansed by passing through the sanitizing/cleansing cassette before being stored in the appropriate media cassettes.

A device comprising a housing having a handle end and a treatment end. The treatment end is configured to provide an antimicrobial treatment and a heat treatment. The treatment end comprises an applicator having an applicator surface for providing at least the heat treatment. The device includes a heat generation unit configured to heat the applicator surface in use, a source of antimicrobial agent, and a control unit operatively connected to at least the heat generation unit for controlling the heat generation unit. The device can be a hand-held device and used to apply topical treatment to a treatment area of a subject.

An osseointegrated fixture of a percutaneous osseointegrated prosthesis (POPs) anchors directly into a bone of a residual limb within an amputation stump. By anchoring directly into the bone, the POPs provides improved mobility, comfort, and function for an amputee, but an interface between an opening in the skin and the osseointegrated fixture, which allows the anchoring directly into the bone, is prone to infection by microbes. An anti-microbial device can be attached to and/or embedded within an extracorporeal portion of the osseointegrated fixture to irradiate at least a portion on the interface with at least one wavelength of light selected for its antimicrobial effects.

A medical device including a lubricating coating film (surface lubricating layer) that exerts excellent lubricity and durability is provided. The medical device includes, on a base layer, a surface lubricating layer formed from a block copolymer having a hydrophilic portion and a hydrophobic portion that has a reactive functional group. The ratio of the hydrophobic portion of the block copolymer in an outermost surface of the surface lubricating layer is 20 to 45 mol %, and the viscosity of a 1 wt % chloroform solution of the block copolymer at a temperature of 30° C. is 8 to 30 mPa.Math.s.

A medical device including a lubricating coating film (surface lubricating layer) that exerts excellent lubricity and durability is provided. The medical device includes, on a base layer, a surface lubricating layer formed from a block copolymer having a hydrophilic portion and a hydrophobic portion that has a reactive functional group. The ratio of the hydrophobic portion of the block copolymer in an outermost surface of the surface lubricating layer is 20 to 45 mol %, and the viscosity of a 1 wt % chloroform solution of the block copolymer at a temperature of 30° C. is 8 to 30 mPa.Math.s.

A system and method that include using biophotonic and/or phononic systems for deactivating viruses, bacteria, and other pathogens that may be present on people, their clothing, or other surfaces. Biophotonic refers to the use of photons in specific wavelengths of the FAR Ultraviolet C radiation and/or FAR Infrared C radiation to affect the interior structure and chemistry of bacteria and viruses to degrade them and render them harmless. The infrared radiation may also provide a phononic effect that degrades the physical conditions of the cell or virus sufficiently to disrupt the cellular machinery, deactivating the virus. Furthermore, a higher temperature Inside the UVIR system makes negligible the rate of propagation of the Virus. The system of the present invention is operable to use electromagnetic radiation to disinfect the exterior surfaces of living mammal animals without harming the animal's tissue, but still effective to degrade microbe and sanitize the exterior surfaces.

A sterilization system is configured to emit energy, such as UV radiation, for sterilizing a surface, such as a door handle, faucet handle, elevator button, or other target surfaces known in the art. The sterilization system is configured to operate automatically in response to detection of a user's hand interfacing with the handle. After a user releases a handle, the sterilization system is actuated to sanitize the handle for subsequent users.

A light delivery system and method are provided to promote a photochemical reaction for disinfecting a surface. The system includes a light source and a light diffusing element operatively coupled to the light source and further embedded within a surface to be disinfected. The light diffusing element outputs light to the surface to promote a photochemical reaction to disinfect the surface. A low scatter light transmission medium may further be coupled between the light source and the light diffusing element to transmit light from the light source remotely to the light diffusing element.

The present invention relates to a device for applying a cosmetic composition (P), comprising: —a capsule (1) that delimits a housing (10), —an application member (6) positioned in the housing (10) and impregnated with a cosmetic composition (P), —an electric exciter (29) comprising at least two electrodes (4, 5) in contact with the application member (6) and making it possible to circulate an electric current between these two electrodes (4, 5).

The invention concerns a disinfection device includes a disinfection chamber having an interior volume and a radiation source coupled to the interior volume. The radiation source is arranged to emit disinfecting radiation into the interior volume when in operation. A disinfection program in the disinfection chamber is arranged to control the radiation source to emit the disinfecting radiation according to parameters determined based on at least one of a three dimensional model of the disinfection chamber and a three dimensional model of a target article to be disinfected. The three dimensional model of the disinfection chamber is formed using data collected by operating at least one radiation source in a data collection disinfection chamber, or by providing a disinfection chamber model having a virtual interior volume. The three dimensional model of the target article to be disinfected is formed by providing a target article model having a virtual surface.