The present invention relates to a laser therapy device and a light transmitting member comprising: a main body provided with a laser light source; a light irradiation unit for irradiating a laser generated in the laser light source to a treatment site; and a light transmitting unit provided between the main body and the light irradiation unit so as to form a path through which the laser is transmitted, wherein the light transmitting unit comprises a plurality of arm members connected by joint parts, and at least one of the plurality of arm members has therein a vacuum forming unit at a position where the laser is focused. According to the present invention, by configuring a compact structure, it is possible to improve the quality of a laser outputted to a treatment site.

Modulated light therapy devices for treatment of dermatological disorders of the scalp are provided. An exemplary device includes a flexible printed circuit board (FPCB) supporting at least one light emitting device having an emitter height. The FPCB includes multiple interconnected panels and bending regions defined in and between at least some of the interconnected panels as to allow the FPCB to be configured in a concave shape to cover at least a portion of a cranial vertex of the patient. At least one light-transmissive layer proximate to the FPCB is configured to transmit (e.g., incoherent) light emissions generated by at least one light emitting device. At least one standoff is configured to be arranged between the FPCB and the scalp of the patient, wherein the at least one standoff includes a standoff height that exceeds the emitter height.

A sterilization system uses ultraviolet radiation and ozone to eradicate deadly pathogens to sterilize a surface of an object or wound/incision site at an adjustable intensity level. The sterilization system has ultraviolet emitters that emit ultraviolet light in wavelengths that kill pathogens and in wavelengths that produce ozone at the sites, therefore killing/disabling several hard-to-kill pathogens. The sterilization system has an intensity control and proximity detectors to enable ultraviolet emission only when the system is properly located near or against the surface so as to protect from unwanted radiation from the ultraviolet light.

An adjustable illuminator for photodynamically diagnosing or treating a surface includes a plurality of first panels and at least one second panel. The plurality of first panels have wider widths and the at least one second panel has a narrower width. The narrower width is less than the wider widths. The illuminator further includes a plurality of light sources, each mounted to one of the plurality of first panels or the at least one second panel and configured to irradiate the surface with substantially uniform intensity visible light. The plurality of first panels and the at least one second panel are rotatably connected. The at least one second panel is connected on each side to one of the plurality of first panels. The second panel acts as a “lighted hinge” to reduce or eliminate optical dead spaces between adjacent panels when the illuminator is bent into a certain configuration.

The present disclosure discloses an adjuvant nail treatment device, including a lower shell component and an upper shell component; an irradiation control component and a display screen, which are fixedly arranged in the upper shell component, wherein the irradiation control component includes a circuit board fixedly arranged in the upper shell component, and the display screen penetrates through the upper shell component; the irradiation control component includes a photosensitive lamp group, a therapy lamp group, and a photosensor device which are respectively fixedly arranged on the circuit board and respectively penetrate through a support in the upper shell component; a photosensitive component, fixedly arranged on the lower shell component and located below the irradiation control component, wherein the photosensitive component reflects light emitted by the photosensitive lamp group to the photosensor device; and a battery component, fixedly arranged in the lower shell component.

A light therapy device mounting system may include an elongate pole comprising a plurality of holes, a first portion, a second portion, and a coupler configured to couple the first portion and the second portion. In some embodiments, the system includes a slider mount slidably coupled to the elongate pole via at least one hole of the plurality of holes, a top bracket slidably coupled to the first portion of the elongate pole, and a bottom bracket slidably coupled to the second portion of the elongate pole. The top bracket may include a top hook for receiving a top portion of a door, and the bottom bracket may include a bottom hook for receiving a bottom portion of the door.

Modulated light therapy devices for treatment of dermatological disorders of the scalp are provided. An exemplary device includes a flexible printed circuit board (FPCB) supporting at least one light emitting device having an emitter height. The FPCB includes multiple interconnected panels and bending regions defined in and between at least some of the interconnected panels as to allow the FPCB to be configured in a concave shape to cover at least a portion of a cranial vertex of the patient. At least one light-transmissive layer proximate to the FPCB is configured to transmit (e.g., incoherent) light emissions generated by at least one light emitting device. At least one standoff is configured to be arranged between the FPCB and the scalp of the patient, wherein the at least one standoff includes a standoff height that exceeds the emitter height.

An adjustable illuminator for photodynamically diagnosing or treating a surface includes a plurality of first panels and at least one second panel. The plurality of first panels have wider widths and the at least one second panel has a narrower width. The narrower width is less than the wider widths. The illuminator further includes a plurality of light sources, each mounted to one of the plurality of first panels or the at least one second panel and configured to irradiate the surface with substantially uniform intensity visible light. The plurality of first panels and the at least one second panel are rotatably connected. The at least one second panel is connected on each side to one of the plurality of first panels. The second panel acts as a “lighted hinge” to reduce or eliminate optical dead spaces between adjacent panels when the illuminator is bent into a certain configuration.

The present invention relates to a spring arm and a laser treatment apparatus including same and, particularly, to a spring arm for a laser treatment apparatus, which can provide an appropriate support force according to a change in the center of gravity of a link at an initial high rotation angle and at a low rotation angle during use, and a laser treatment apparatus including same. According to the present invention, a user fatigue degree can be reduced and accuracy of the apparatus when in use can be improved.

A treatment support device (1) configured to control therapeutic light irradiated toward a treatment site of a subject (ST) to whom a therapeutic agent containing a fluorescent dye used in photoimmunotherapy has been administered and excite the fluorescent dye by means of the therapeutic light to perform treatment is provided with: a light source (242) for emitting the therapeutic light; a control unit (17) for controlling the irradiation time and the irradiation intensity of the therapeutic light; and a detection unit (182) for detecting the intensity of the fluorescence generated from the fluorescent dye, when the therapeutic light is being emitted. The control unit (17) controls at least one of the irradiation time and the irradiation intensity of the therapeutic light based on the irradiation intensity of the fluorescence.