The new invention foot-care equipment unit is directly related to foot problems and cures from pain, numbness, stiffness, swelling, athlete's foot, blisters, bunios, corns, plantar fasciitis, heel spur, mallet or hammer toe, gout, ingrown toenail, nail hardening, fungal nail infection, plantar wart, stone bruise, morton neuroma, sesamoidits, poor blood circulation, crack heals, blood clots in the foot vain or excessive sweat, and or bad odours are common symptom of foot related issues or causes of poor foot health. The foot-care equipment a hands free solution for practicing random or regularly use of equipment for steaming, fermenting, massaging, cleaning and sanitizing, air blow drying, sterilizing and or scrubbing of foot or the feet's for cure or general health and hygiene as therapy or treatment. The foot-care equipment unit may comprise of semi-automatically functional in cleaning, sanitizing and sterilizing, and or drying of its equipment components for users.

A system for for treatment of wounds consists of a treatment housing, a fluid delivery mechanism for supplying debridement fluids to the wound treatment area, an evacuation mechanism for evacuation of debris from the treatment chamber. A handheld device is connected to the treatment housing, wherein its interior accommodates a laser source, a scanning device, an image recording device and at least one sensors/detectors, a control unit having a microprocessor for controlling operation of the system. The sensors detect concentration of various substances in the wound, and microprocessor analyzes data obtained by the sensors and generates signals to adjust parameters of the laser, the liquid dispensing nozzles and the suction outlet to optimize removal of necrotic tissue so as to ultimately to promote wound healing.

A cosmetic method and apparatus for selecting an IPL light source having a band pass filter equivalent to a specified wavelength laser light source for providing cosmetic treatment of skin tissue and being configured to deliver high energy fluences and achieve a threshold energy sufficient to produce a clinical effect during operation.

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.

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.

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.

An oral treatment device that emits electromagnetic radiation onto surfaces of a user's teeth. The oral treatment device may include an intraoral mouthpiece and a handle extending therefrom, the handle containing the control circuitry required for operation of the device. The mouthpiece may include a lamp support structure, a lamp, a lens plate, and a guard component. The lamp may include an electromagnetic radiation source that includes a flexible sheet and a plurality of illumination elements located thereon. The illumination elements may be light emitting diodes printed with an electrically conductive. Additional electronic components such as a processor and a power source may also be included in the device.

Disclosed are a microbe inactivation processing method that can perform inactivation processing of microbes, while damage to human body cells is prevented or inhibited, with an efficient use of light emitted from a light source and the obtainment of a large effective irradiation area. Also provided are a cell activation processing method that can reliably activate target cells with high efficiency. The microbe inactivation processing method includes: a step of applying light emitted from a light source through an optical filter, with the light source configured to emit light having a wavelength within a wavelength range of 190 nm to 237 nm, in order to perform inactivation processing of a target microbe. When the light emitted from the light source is incident at an incident angle of 0°, the optical filter transmits at least a part of ultraviolet light having a wavelength within a range of not lower than 190 nm and not more than 230 nm, and transmits at least a part of ultraviolet light having a wavelength within a range of more than 230 nm and not more than 237 nm, and the optical filter blocks transmission of ultraviolet light having a wavelength out of a wavelength range of not lower than 190 nm and not more than 237 nm.

A system for treatment of wounds consists of a treatment housing, a fluid delivery mechanism for supplying debridement fluids to the wound treatment area, an evacuation mechanism for evacuation of debris from the treatment chamber. A handheld device is connected to the treatment housing, wherein its interior accommodates a laser source, a scanning device, an image recording device and at least one sensor/detector, a control unit having a microprocessor for controlling operation of the system. The sensor detects concentration of various substances in the wound, and the microprocessor analyzes data obtained by the sensor and generates signals to adjust parameters of the laser, the liquid dispensing nozzles and the suction outlet to optimize removal of necrotic tissue so as to ultimately to promote wound healing.

Disclosed are devices suitable for treatment of subcutaneous tissue by transdermally-inducing ultrasonic vibrations in subcutaneous tissue and/or transdermally delivering energy with electromagnetic radiation such as light to subcutaneous tissue. In some embodiments, the treatment of subcutaneous tissue is effective in reducing the amount of subcutaneous fat therein. In some embodiments, transdermal radiation-delivery of energy and transdermal induction of ultrasonic vibrations in subcutaneous tissue can be performed simultaneously, alternatingly or in an unrelated fashion. In some embodiments, the device simultaneously transdermally-induces both ultrasonic transverse and ultrasonic longitudinal vibrations in subcutaneous tissue.