Systems, devices, and methods for treating a skin of a patient with therapeutic laser light via imaging a first skin area of the patient to obtain at least a first image, processing the at least a first image of the first skin area with at least one processor to identify within the first skin area at least one or more target skin areas and a non-target skin area, generating a treatment map of the first skin area based on the identified one or more target skin areas and the non-target skin area, and treating at least a portion of the one or more target skin areas with therapeutic laser light based on the generated treatment map.

A hair removal and re-growth suppression apparatus (10) constituted of: a control circuitry (70); a removal and suppression head (20); an extender assembly (23) coupled to the head (20) and extending away from a wall of the head (20) towards an end thereof, the extender assembly defining an opening (17) at an end thereof removed from the wall of the head (20); an irradiating element (40) secured to the head (20) responsive to the control circuitry (70); a reflector (90) disposed on the head (20) between the irradiating element (40) and the head (20); and a cutting element (110) secured to the head (20) and arranged to cut hair when the opening (17) is juxtaposed with a skin portion (140) having a hair (150) extending outward there from, wherein the reflector (90) is arranged to substantially reflect the output electromagnetic radiation toward the opening (17). Optionally, the irradiating element (40) is regularly translated between a first and a second position to heat and cut the hair without damaging the skin.

A computerized method for controlling the operation of a laser therapy device is disclosed. A laser therapy device comprising laser diodes has a microprocessor for storing and executing instructions pertaining to the operation of the laser diodes within certain parameters. The computerized method detects the movement of the laser therapy device and alters the output of the laser diodes when a movement signal exceeds predetermined threshold parameters. The computerized method detects difference in temperature in certain areas, and patterns in temperature differences, for assistance in diagnosing ailments. The computerized method also detects differences in skin color to determine treatment areas. The computerized method also measures the distance of the laser therapy device to a treatment area. The microprocessor executes instructions then which can alter the output of the laser diodes or generate an alarm signal based on measurements received.

An unattended approach can increase the reproducibility and safety of the treatment as the chance of over/under treating of a certain area is significantly decreased. On the other hand, unattended treatment of uneven or rugged areas can be challenging in terms of maintaining proper distance or contact with the treated tissue, mostly on areas which tend to differ from patient to patient (e.g. facial area). Delivering energy via a system of active elements embedded in a flexible pad adhesively attached to the skin offers a possible solution. The unattended approach may include delivering of multiple energies to enhance a visual appearance.

The present invention relates to a therapy system for the treatment of the skin and subdermis with light. The system comprises a NIR light source which produces light with a wavelength adapted to an absorption maximum for exciting molecular oxygen in aqueous solution; an image recognition unit for detecting papillary end arterioles and their x-y-z coordinates, wherein a respective depth underneath the skin surface is determined as the z-coordinate by an autofocus function; an optical system for the optical coupling of the light of the NIR light source and the pattern recognition unit to the skin, with a focussing unit to controllably position the light with at least one focus point in the skin; and a control unit to control the NIR light source, the image recognition unit, and the optical system.

The present disclosure is concerned with a skin treatment device having at least a first LED, at least a first controllable current source, in particular a first controllable constant current source, for driving the first LED, a control unit for controlled switching of at least the first controllable current source between a first state in which current is provided to the first LED and a second state in which no current is provided to the first LED, and at least a first current sensor that is connected or connectable with the first LED so that the first current sensor and the first LED form a current path at least in the second state of the first controllable current source.

Disclosed is a high power VCSEL laser treatment device with a skin cooling function, comprising VCSEL array (4) packaged on a laser heat sink (2), an optical transmission device (8) arranged in front of light-exiting faces of the VCSEL array (4) and a high-heat-conductivity optical window sheet (6) adhered to the light-exiting port end of the optical transmission device (8). An integrally molded cooling conduction metal piece (1) is arranged on the outer sides of the laser heat sink (2), the optical transmission device (8) and the high-heat-conductivity optical window sheet (6). In addition, one or more semiconductor chilling plates (7) are arranged between the cooling conduction metal piece (1) and the laser heat sink (2). In the above-mentioned high power VCSEL semiconductor laser treatment device, the semiconductor chilling plates (7) and the VCSEL array (4) share the heat sink, so that the inner structure is simplified.

A method for photothermolysis that includes applying galvanic current energy to skin at an area of a hair follicle and applying pulsed optical energy to the skin at the area of the hair follicle at an energy level and duration so as to cause thermal destruction of a hair papilla.

According to an aspect of this disclosure, there is provided an apparatus (42) configured for use with a personal care device (2). The apparatus (42) is configured to provide visual guidance to a user on movement of the personal care device (2) across a body of a subject, wherein the personal care device (2) is configured to perform a personal care operation on a plurality of successive treatment areas of the body by successively moving the personal care device into a plurality of successive treatment positions on the body each corresponding with a respective one of said successive treatment areas. The apparatus (42) comprises a projection unit (22) configured to project a light pattern on to a surface of the body, and a processing unit (46). The processing unit (46) is configured to control the projection unit (22) to project the light pattern on to the surface of the body in a projection position indicative of a next treatment position on the body to which the personal care device (2) is to be moved by the user from a current treatment position on the body.

A photo-bio-stimulation device uses near infrared (NIR) laser illumination of the scalp to promote hair growth with a lightweight user wearable device. All the remaining components are mounted on the concave underside of an outer cap shell. Many VCSEL laser device chips are surface mount soldered underneath of a single large flexible printed circuit. These discrete devices direct a diffused, near uniform flood of 678-nanometer monochromatic laser light deep into the hair roots and follicles across the scalps of its users. Petal shapes along a central spine are cut deep into the side edges of the flexible printed circuit to allow it to be conformed and fixed into a hemispherical dome and attached with dozens of plastic snaps inside the outer shell. This connects inside to a rechargeable battery and power controller. A protective clear covering matching the concave underside is attached along the brims.