The present application is concerned with a skin treatment device that has a handle section arranged to be held in a human user's hand, a treatment head section having a skin treatment unit and a skin contact frame having a skin contact surface, the skin contact frame at least partially encircling a skin treatment area and a vibration generation unit being coupled with the skin contact frame to vibrate at least a portion of the skin contact frame at an ultrasonic frequency.

In one aspect, devices for light treatment of skin are described herein. A device described herein, in some embodiments, comprises an interior compartment having a proximal end and a distal end, and an optical aperture disposed at the distal end. The device also comprises a laser or BBL source that produces a laser or BBL beam. The laser or BBL beam has a first optical path within the interior compartment, between the proximal end and the distal end. Additionally, the first optical path exits the interior compartment through the optical aperture. The device further comprises an imaging system that receives a return signal from the aperture. The return signal received from the aperture has a second path within the interior compartment. Further, a selectively reflective optical element is disposed in the first and second optical paths. The selectively reflective optical element generally transmits the laser or BBL beam.

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.

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.

Methodology for encouraging hair growth in male humans, and more particularly to methodology which involves application of electromagnetic radiation, mechanical vibrations, along with applications of combined minoxidil, mint oil, (preferably menthol containing essential peppermint oil), ginger oil, lavender oil, castor bean oil, jojoba oil; melaleuca oil, cumin oil, D-alpha tocopherol (vitamin E) infused oil, biotin infused oil and a single selection, or dry mixture and/or liquid “tea” formed from selections from the group consisting of powdered saw palmetto; powdered horsetail; powdered ginger; powdered stinging nettles; powdered horny goat weed; powdered pueraria lobate; powdered Tribulus terrestris; powdered ashwagandha; powdered capsicum; powdered habenero; powdered green tea; powdered sage; powdered gingko biloba; powdered myrrh; powdered alpha-hydroxy; powdered Aloe vera; powdered wheat protein; powdered wheat starch; powdered casein, powdered keratin, powdered folic acid; powdered fenugreek seed and powdered biotin powdered ginseng Root; powdered vetiver grass; powdered caffeine; powdered Co-enzyme Q; powdered folate; powdered gotukola leaf; powdered milk thistle; powdered African pygeum; powdered stinging nettles; powdered gingko biloba; powdered myrrh; powdered alpha-hydroxy; powdered caffeine; powdered niacinamide (NAD) and/or niacin; and powdered Nigella sativa; powdered Eclipta alba; powdered Centella asiatica; powdered Phyllanthus emblica in water and alcohol, or an oil.

A lightweight smart hair-growing instrument with external power supply, which includes an headgear mechanism, light sources, a control mechanism, and a power source; the headgear mechanism is provided with a cavity for containing a user's head; the light sources are disposed in the cavity and faced to a centre of the cavity; the control mechanism are located at an outside of the headgear mechanism and electrically connected with the light sources; the power source is disposed in the control mechanism; the control mechanism and the light sources are connected electrically by a transmission line or driving connected by a wireless protocol signal; the power supply is integrated on the control mechanism independent with the headgear mechanism, which greatly reduces the whole heavy of the hair-growing instrument.

A stable smart laser hair-growing instrument with independent light sources includes a shell, a laser emitting assembly and a control system; the shell is provided with a cavity disposed above a user's head, the laser emitting assembly includes light sources, a first circuit board and multiple second circuit boards, the first circuit board is disposed in the shell at a position aligned at a center of a user head; a gap is arranged between the adjacent second circuit boards; the light sources are evenly distributed on the first circuit board and those of the second circuit boards; the control system includes a circuit control and a multi-group of independent control units electrically connected with the circuit control; all the independent control units are electrically connected to the corresponding driving circuit of the second circuit boards and that of the first circuit board, respectively.

A formula and method to counteract hair loss, where the formula is a mixture. The mixture consists of Flaxseed oil, Coconut oil, Castor oil, Nigella sativa oil, Olive oil, Sesame oil, Sweet Almond oil, Bitter Almond oil, Watercress oil, Jojoba oil, Garlic oil, Onion oil, and Pistacia lentiscus oil. The oils derived from seeds are cold rolled to produce the oil. The mixture is applied to the scalp after brushing and washing of the scalp area to be treated.

Treatment of skin tissue with photoactive materials and light, such as nanoparticles and formulations which are useful for cosmetic, diagnostic and therapeutic applications to mammals such as humans. In particular, embodiments of thermal treatment of the skin surface with metal nanoparticles in surfactant containing solutions are disclosed.

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.