Methods and systems are provided which project germicidal light from a lamp toward an individual donned in outerwear to disinfect the outerwear. In specific embodiments, germicidal light is projected toward an individual situated greater than approximately 1 foot from the light source. Some systems include sensor/s for detecting presence of an individual within a target area a set distance from the disinfection apparatus comprising the light source and program instructions for commencing operation of the disinfection apparatus based on information from the sensor/s. In addition or alternatively, some systems include reflective panel/s exhibiting greater than approximately 85% reflectance. In such cases, the systems may include program instructions for determining operating parameters of the disinfection apparatus and/or positions of the reflective panel/s based on information regarding an individual who is in the presence of the disinfection apparatus or who is scheduled to be in the presence of the disinfection apparatus.

A light source for emitting emitted light having an SPD comprising: (a) a plurality of light emitters including at least one violet solid-state emitter; (b) at least one phosphor; wherein said light emitters and said at least one phosphor being configured such that: at least 25% of the power within the SPD is in the range 390-420 nm, and the emitted light has a chromaticity which is within a Duv distance of less than 5 points from the Planckian locus.

A sterilization apparatus includes a main body, and a plurality of sterilization modules. The main body defines a sterilization space for sterilization of a sterilization target. The sterilization modules are disposed on a plurality of inner surfaces of the main body surrounding the sterilization space, respectively, and deliver germicidal light to the sterilization space. In addition, the sterilization module includes a support member and a plurality of light sources. A space between adjacent light sources disposed in some regions of the support member is different from a space between adjacent light sources disposed in the other regions of the support member.

Methods and apparatus for the inactivation of infectious agents in, on or around a catheter residing in a patient's body cavity. The method comprises transmitting non-ultraviolet sterilizing electromagnetic radiation (EMR) substantially axially along an optical element in the catheter body. Through delivery of the sterilizing EMR to particular areas of highest infection, the present disclosure is able to inactivate the major sources of infection in catheters.

Disclosed herein is a multiple light emitter device which inactivates microorganisms. The device includes at least two light emitters and at least one light-converting material arranged to convert at least a portion of light from the light emitters. Any unconverted light emitted from the light emitters and converted light emitted from the at least one light-converting material mixes to form a combined light, the combined light being white. In one aspect, the light emitters include at least one blue light emitter and at least one violet light emitter. In another aspect, the light emitters include one blue light emitter and one emitter within the range of approximately yellow to infrared light.

Reusable catheter products (10) are provided for storing, transporting, and sterilizing reusable urinary catheters. The products include a case (12) comprising a proximal section (30), a middle section (40), and a distal section (32). The case includes a cavity (16) configured to receive a catheter (14); the cavity includes a hydration fluid (18). The catheter comprises a distal end, a proximal end and a tubular section therebetween and includes a hydrophilic coating. When the catheter is inserted into the case, the hydration fluid sterilizes and lubricates the catheter.

A germicidal door handle or other surface touched by a user may include one or more light sources configured to emit light at a wavelength effective to act as a germicidal. In some instances, the door handle/surface may interact with a controller configured to selectively activate the one or more light sources. The controller may be configured to perform the following steps: (1) activating the one or more light sources, (2) deactivating the one or more light sources upon an occurrence of a first predetermined condition, and (3) reactivating the one or more light sources upon an occurrence of a second predetermined condition.

A Selected-area Ultraviolet Disinfection (SUD) system which enables increased frequency of ultraviolet light treatment of spaces by improving the convenience, cost, safety, and/or efficacy. The core utility of the SUD system is to frequently and safely disinfect spaces where occupants are conducting their normal activities, enabled by a system constructed with a disinfecting light source that can direct and irradiate only selected areas (and corresponding volumes) that sensing and control components have determined are safe to disinfect, i.e. are not currently occupied.

Provided are methods of reducing and killing bacteria and fungi, and photodynamic treatment methods and sterilization methods using the methods of reducing and killing bacteria and fungi. The method of reducing and killing bacteria and fungi includes bringing a composition including a Ligularia fischeri extract or a fraction thereof as an active ingredient into contact with cells or tissues of a subject and irradiating cells or tissues of a subject in contact with the composition with an absorbable wavelength of excitation light.

Liquid, air, or surface treatment/sterilization/disinfection using pulsed light to eliminate, reduce, degrade, render inert, or nullify physical, chemical, biological, microbiological, or non-microbiological contaminants is disclosed herein. The system also includes at least one power supply powering the light source of the reactor, an ionized wire wrapped outside the light source of the reactor, at least one digital multiplexer connected to the at least one power supply, and a controller to control the at least one digital multiplexer to power the light source to strobe the pulsed light at a predetermined fluence, a predetermined pulsed width, and a predetermined frequency or spectrum to eliminate, reduce, degrade, render inert, or nullify the physical, chemical, biological, microbiological, or non-microbiological contaminants in a liquid flow, air, or surface at a molecular level.