Systems and methods are provided for treating or preventing carbon monoxide poisoning. In particular, systems and methods are provided for a phototherapy treatment or prevention system that delivers light radiation to a patient's body to photodissociate carbon monoxide from hemoglobin.

The present invention provides a composite intelligent biological phototherapy device including a base structure, a plurality of white light fluorescent tubes arranged side by side on the base structure, a plurality of LEDs disposed between the white light fluorescent tubes, a housing having an opening and configured to accommodate the base structure and the white light fluorescent tubes and the LEDs thereon, a light-transmittable plate disposed on the housing corresponding to the opening, and an control module configured to respectively control the white light fluorescent tubes and the LEDs. The base structure includes a plurality of sections, and each of the sections has a first surface facing the light-transmittable plate. The white light fluorescent tubes and the LEDs are provided on the first surfaces, and the sections are bent relative to each other so an angle between the first surfaces of adjacent sections is less than 180 degrees.

The invention relates to a device (1) for dermatological treatment, comprising a laser head (2) suitable for directing a laser beam (3) towards a target zone (4), at least one fan (5) suitable for dissipating the heat emitted by the laser head (2), and at least one monitoring means (6) suitable for detecting a fault in at least one fan (5) and for controlling at least one means (7) for inhibiting the laser beam (3) when a fault is detected.

An apparatus for laser therapy comprises a frame on which a plurality of lasers slide at several wavelengths in motorized and automated manner for applying the laser on and through the skin and mucous membranes of a patient. The frame is also motorized, allowing installation on the patient without moving the patient from bed. The apparatus is programmed to determine treatment autonomously on the basis of parameters determined by the apparatus during pretreatment and to vary treatment parameters in real time for treatment optimization and safety purposes.

Certain exemplary embodiments of the present disclosure can provide an. apparatus and method for generating at least one radiation can be provided. The exemplary apparatus and for 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 can be provided.

Certain exemplary embodiments of the present disclosure can provide an apparatus and method for generating at least one radiation can be provided. 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 can be provided.

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.

A light therapy wearable includes a fabric panel and a side-emitting light tube affixed to or held against the fabric panel. The side-emitting optical light tube includes a side-emitting optical fiber and a jacket surrounding the side-emitting optical fiber. The side-emitting optical fiber includes a core and cladding surrounding the core. The core is made from a synthetic polymeric material. The jacket is made from a transparent or translucent material and has a durometer of at least 65 A and an outer diameter at least seven times a core diameter of the side-emitting optical fiber.

A disposable material, pre-cut to various shapes or able to be cut or shaped at the time of use, to protect non-target tissue, excluding the eyes, during treatment of the skin is disclosed. The disposable material comprises a flexible material comprising at least one first layer comprising a material that mitigates the transmission of electromagnetic radiation from an radiation source; a backing layer that is located on top of the first layer and is configured to diffusively reflect the electromagnetic radiation without direct specular reflection; and an adhesive for removably attaching the disposable material to the skin. There is also disclosed a method of protecting non-target tissue, excluding the eyes, by applying the disclosed material to a desired location.

Certain exemplary embodiments of the present disclosure can provide an apparatus and method for generating at least one radiation can be provided. 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 can be provided.