An implantable photobiomodulation lead includes a lead body having a proximal end portion and a distal end portion; at least one light emitter disposed along, or coupled to, the distal end portion of the lead body and configured to emit light out of the photobiomodulation lead; and at least one electrode disposed on or over the at least one light emitter and in a path of the light emitted by at least one of the at least one light emitter.

A device for measuring surfaces to be treated by photobiomodulation. comprising: optical elements for tracking axes of a surface to be treated, data communication elements for communicating data to a data processing unit, the data communication elements being connected to the optical elements, a body for the containment of the optical elements and of the data communication elements, the body being ergonomic.

Proposed is a laser irradiation device for medical treatment for irradiating a laser treatment target with a laser beam. The device includes a handpiece configured to irradiate the laser treatment target with a laser beam in a preset guide shape, and a controller configured to set, on the basis of data on the laser treatment target, a guide shape for emitting a laser beam and generate a control message to control an operation of the handpiece on the basis of the guide shape.

An LED patch for a skin care apparatus is provided. An LED patch for a skin care apparatus according to an exemplary example of the present invention comprises: a substrate part; a circuit pattern part formed in at least two layers on the substrate part; a light source part including one or more LEDs mounted on one surface of the substrate part; and a cover part configured to cover at least one surface of the substrate part.

A system for treating an eye includes a light source configured to provide photoactivating light that photoactivates a cross-linking agent applied to a cornea. The system includes one or more optical elements configured to receive the photoactivating light and produce a beam that defines a spot of the photoactivating light. The system includes a scanning system configured to receive the beam of the photoactivating light and to scan the spot of the photoactivating light along a first axis and a second axis to form a scan pattern on the cornea to generate cross-linking activity.

The present application is directed to devices, assemblies, systems and methods for targeting one or more sites with electromagnetic radiation. The devices, assemblies and systems are operationally configured to transform and convey electromagnetic radiation to one or more targeted sites. The devices, assemblies and systems may also convey one or more fluids or fluid solutions to the one or more targeted sites.

The present disclosure belongs to the technical field of laser energy monitoring, and particularly, a laser energy monitor for myopia treatment device and a monitoring method are provided. The monitor comprises a laser light source, a housing, a beam shaping lens, a beam homogenizing lens, a photosensitive sensor, and a controller; wherein the housing is provided with a cavity for receiving the laser light source, beam shaping lens, beam homogenizing lens, and photosensitive sensor, the housing is also provided with a light aperture, the light aperture is communicated to the cavity, and the laser light source is positioned opposite to the light aperture; and the photosensitive sensor is electrically connected to the controller. The monitor can adjust the inner layout of the conventional housing.

A phototherapy device includes a laser light source 8 for emitting laser light toward a target portion, a body part 5, an intake port 12 provided at a side surface of the body part 5, a discharge port 13 provided at the side surface of the body part 5 at an opposite side from the intake port 12, and an air supply device 14 for supplying air to be ejected from the intake port 12 to the inside of the body part 5, the intake port 12 configured so that an ejection direction F0 of the air is toward the near side from a center of an emission area A of the laser light at the target portion T.

A near-infrared (NIR) light therapy device having at least one NIR light source and a waveguide having i) a NIR light input surface and ii) a NIR light emitting surface. The waveguide includes a lens feature forming the NIR light input surface. The lens feature is configured to at least substantially collimate treatment NIR light from the at least one NIR light source and convey substantially collimated light in a first direction through the waveguide. The waveguide also includes a plurality of extractive surfaces on a surface of the waveguide that is configured to reflect the substantially collimated light through the light emitting surface to a subject. The plurality of extractive surfaces is also configured to create a substantially uniform NIR light output across the light emitting surface.

The disclosure relates to a cancer treatment system including a nozzle which generates the mist of a solution which consists of basic hydrogen peroxide and an imaging optics that relays an aerial image near the exit of the nozzle. The imaging optics can relay a spatial image at the outlet of the nozzle. Consequently, the 1.27-micrometer wavelength radiation is focused at where the affected part of a cancer patient is positioned.