The technology disclosed herein relates to a transcutaneous irradiation device having a top portion and a bottom portion. The top portion may include one or more transcutaneous irradiation modules configured to be arranged on a head of a user, the top transcutaneous irradiation modules including a top pulsed laser source. The bottom portion may include one or more transcutaneous irradiation modules configured to be arranged on an abdomen of the user, the top transcutaneous irradiation modules including a bottom pulsed laser source. A modulation frequency may be applied to the top and bottom irradiation modules such that the top and bottom pulse laser sources are subjected to a double pulse.

A portable hair removal device (10), comprising a head portion (30), and a housing (20) connected to one end of the head portion (30). An emitter capable of emitting light is provided in the housing (20), and the light emitted by the emitter passes through the head portion (30) and then acts on the skin for hair removal. The head portion (30) is provided with at least a phototherapy lamp (32), and light emitted by the phototherapy lamp (32) acts on the skin through the head (30) and takes care of the skin. The portable hair removal device (10) has rich functions and a good skin care effect.

Systems and methods are described for treatment of neurological conditions in which transcranial illumination using infrared, near-infrared and/or red wavelengths of light are delivered into the brain of a patient using a portable head wearable device. Arrays of light emitters are simultaneously controlled to provide a selected power density and distribution during a therapeutic session to treat a condition of the patient. An external controller such as a touchscreen tablet or laptop computer can be used to select illumination parameters for each patient. The system can be used to provide treatment to children such as those having autism spectrum disorder (ASD).

A noninvasive method of reducing a user's body apparent body fat by applying a device emitting high power light having a wavelength shorter than 1065 nm externally through the skin of the patient. The device is placed on or attached to one or more areas of a patient's body. Sufficient energy, with a targeted value of 6.6 J/cm absorbed, is applied to one or more of those areas to cause a reduction in the measurement in the energized areas. The preferred methodology uses LEDs at about 532 nm and 635 nm. Targeted energy levels are a minimum of 2 W/cm for LED emissions applied every other day for a minimum of 75 seconds per exposed area; until desired amount of size reduction is achieved.

A UV-C emitting phone case is provided that includes a main body defining a receiving cavity and a perimeter configured to receive and hold a mobile phone, surround a perimeter and a back portion of the phone. The phone case includes at least one UV-C light emitting diode (LED) positioned in the main body of the phone case and exposed on a back side of the phone case. It further includes a window for exposing the UV-C LED and optionally having a color metric to indicate if the light is being emitted, a power source built into the phone case and connected to the UV-C LED; an on/off switch coupled to the power source configured to activate and deactivate the UV-C LED; and an optional distance sensor to indicate a distance from a target surface to the UV-C LED.

There is provided a phototherapy apparatus, in which the therapeutic light is delivered through one or more massage components. The massage component provides mechanical massage to the subject biological tissue and modifies the properties of the subject tissue in thickness, density, etc. to facilitate the absorption of the therapeutic light and enhance the effect of the phototherapy procedure. The light source of the phototherapy apparatus is actively cooled by a synthetic jet cooler.

An optical stimulation lead includes a lead body including a distal end, a distal portion, and a proximal portion; and an optical assembly attached to the distal end of the lead body. The optical assembly includes a light emitter; a feedthrough assembly including at least one ceramic block, at least one feedthrough pin extending through the at least one ceramic block and electrically coupled to the light emitter, and a metal housing attached to the at least one ceramic block; a metal tube attached to the feedthrough assembly and disposed around the light emitter; and an emitter cover disposed over the light emitter and coupled to the metal tube.

A stimulation system includes an energy source, an electronics unit with a controller, and an actuator that is coupled with the electronics unit and/or the energy source. The actuator emits electromagnetic waves for stimulation of genetically manipulated tissue. The electronics unit is disposed in a housing. The stimulation system is configured for at least temporary implantation in a human or animal body. The controller controls the stimulation of tissue in the body by way of the electromagnetic waves emitted by the actuator. A selector of the stimulation system selects the area of the said tissue for stimulation. The selector includes a masking device for masking certain areas of the tissue, so that an intensity of the stimulation for the masked areas is reduced or equal to zero.

An embodiment discloses a mask apparatus including a cover mask having a curvature corresponding to a shape of a face of a user and a plurality of light-emitting modules arranged in the cover mask to irradiate light to the face of the user.

A cosmetic device according to an embodiment of the present disclosure comprises: a main body; a head module that is detachable from the main body; a control unit for recognizing the head module mounted to the main body; and a communication unit for transmitting information about the recognized head module to a mobile terminal. The control unit can control the operation of the head module mounted to the main body differently according to the information received from the mobile terminal.