A blood processing apparatus including a blood supply unit, a centrifuge, a light irradiation unit, a filtering device, and a blood collection unit, which is characterized in that blood is introduced into the centrifuge and centrifuged, the centrifuged blood is passed through a transparent tube provided in the light irradiation unit while being irradiated with light applied, from the outside of the transparent tube, by a light irradiation device configured to include an infrared lamp with a wavelength of 830±5 nm, a red light-emitting diode (LED) lamp with a wavelength of 635±6 nm, a blue LED lamp with a wavelength of 420±5 nm, a green LED lamp with a wavelength of 530±5 nm, a yellow LED lamp with a wavelength of 585±5 nm, and ultraviolet (UV) lamps, and the blood irradiated with the light is filtered using the filtering device and collected in the blood collection unit.

Described herein is a low-form table-top air sanitizer using filterless UVA/UVC technology to prevent viral spread in a localized volume. For example, the low-form table-top air sanitizer can be used where people are indoors, in close proximity, and not wearing masks. Also described herein is a method of using a low-form table-top air sanitizer to purify air in an indoor, close proximity environment where wearing a mask is impractical.

A LED grow light array and method for controlling thereof, aimed at increasing plant canopy light penetration without stationary hot spots, providing antimicrobial light to eliminate microorganism on plants, providing pulsing canopy penetrating and microbial light without a dark period, and reducing energy consumption, the LED grow light array comprising: a LED grow light array, the array comprising at least four light bars, wherein the light bars comprise discrete photosynthetic LED chips of different types based on the wavelength of light they emit, the light they emit being either blue, red, or white light, or a combination thereof, wherein blue light wavelength ranges from 405 nm to 450 nm, red light wavelength ranges from 630 nm to 720 nm, and white light is a combination of wavelengths that ranges from 400 nm to 700 nm, each type of photosynthetic LED chip forming a set of chips; wherein the bars are in a series and spaced evenly over a given plant growing area; wherein the light bars further comprise discrete antimicrobial LED chips of different types based on the wavelength of light they emit, the light being light with antimicrobial properties between the wavelengths of 100 nm and 405 nm, each type forming a set of chips; wherein each light bar comprises a circuit board to mount said discrete photosynthetic and antimicrobial LED chips thereon; at least one LED driver to provide power to the LED chips; at least one microprocessor to control the at least one LED driver; and a lighting program sent to the microprocessor designed to control the at least four light bars and the sets of photosynthetic and antimicrobial LED chips individually.

The invention relates to a recipient (1) for ex-vivo treatment of biological liquids, which includes: a rigid body (2); a reservoir (3) provided inside the body (2), which is formed by a side wall (4), a rigid upper wall (5) and a rigid lower wall (6) and has an internal thickness defined by the separation between the upper wall (5) and the lower wall (6), at least one of the upper wall (5) or the lower wall (6) having a window area (7) configured to allow the passage of electromagnetic radiation from outside of the body (2) to the reservoir (3); two ports (8, 9) for liquids to gain access to the reservoir (3) from outside of the body (2); and closure means (10, 11) for the ports (8, 9), the closure means (10, 11) being configured to provide, jointly, the reservoir (3) with hermetic sealing against gases and liquids.

A solution for controlling mildew in a cultivated area is described. The solution can include a set of ultraviolet sources that are configured to emit ultraviolet and/or blue-ultraviolet radiation to harm mildew present on a plant or ground surface. A set of sensors can be utilized to acquire plant data for at least one plant surface of a plant, which can be processed to determine a presence of mildew on the at least one plant surface. Additional features can be included to further affect the growth environment for the plant. A feedback process can be implemented to improve one or more aspects of the growth environment.

An illuminator comprising more than one set of ultraviolet radiation sources. A first set of ultraviolet radiation sources operate in a wavelength range of approximately 270 nanometers to approximately 290 nanometers. A second set of ultraviolet radiation sources operate in a wavelength range of approximately 380 nanometers to approximately 420 nanometers. The illuminator can also include a set of sensors for acquiring data regarding at least one object to be irradiated by the first and the second set of ultraviolet radiation sources. A control system configured to control and adjust a set of radiation settings for the first and the second set of ultraviolet radiation sources based on the data acquired by the set of sensors.

The present invention is directed to a system and method for photoeradication of microorganisms from a target. The method includes the step of obtaining test data for a plurality of experiments each of which comprises irradiating test microorganisms with a plurality of light pulses having a wavelength that ranges from 380 nm to 500 nm. The light pulses have a plurality of pulse parameters (peak irradiance, pulse duration, and off time between adjacent light pulses) and are provided at a radiant exposure that ranges from 0.5 J/cm.sup.2 to 60 J/cm.sup.2 during each of a plurality of irradiation sessions. The test data comprises a survival rate for the test microorganisms after irradiation with the light pulses. The method also includes the step of analyzing the test data to identify the pulse parameters for the light pulses and the radiant exposure for each of the irradiation sessions that result in a desired survival rate for the test microorganisms. The method further includes the step of irradiating the microorganisms of the target with light pulses having the identified pulse parameters at the identified radiant exposure for each of the irradiation sessions so as to photoeradicate all or a portion of the microorganisms.

A hand sanitizing device described herein allows users to sanitize and/or disinfect their hands by bathing them in ultraviolet light. The hand sanitizing device may comprise a cabinet that comprises one or more cavities for a user's hands. The one or more cavities may comprise a sensor to detect a user's hands, a controller to send signals to a plurality of ultraviolet lights, and a plurality of ultraviolet lights. Based on a determination that the user has placed their hands in the one or more cavities, the plurality of ultraviolet lights may be illuminated to sanitize and/or disinfectant the user's hands. When the user has removed their hands from the one or more cavities, the plurality of ultraviolet lights may be turned off. By using ultraviolet light, the hand sanitizing device may reduce the spread of infectious diseases and waste consumption associated with bathroom usage.

A device includes a material and a silver titanium dioxide coating supported by the material. The material may be a face mask adapted to be worn by a user. The coating may be applied via a Silver Titanium Dioxide solution. The solution may also be atomized for inhaling. Silver Titanium Dioxide acts as a photocatalyst at least due to the Titanium Dioxide to degrade organic molecules and microorganisms. The silver acts as a Bacteria stat, Fungus stat, and a Virus stat with or without light exposure. A titanium dioxide solution may be applied to skin. Exposure of the solution imbibed skin to light may be performed to remove or reduce tattoos.

A handheld portable device for sanitizing a surface or air surrounding a surface. The handheld portable device includes a body that comprises a user input and a far-UVC illumination source disposed at the body. The handheld portable device also includes a power source for providing power to the far-UVC illumination source. Responsive to actuating the user input, such as by a user holding the handheld portable device, the far-UVC illumination source emits far-UVC illumination to sanitize the surface or the air surrounding the surface of pathogens.