A device for enhancement of visual appearance including a first applicator to be coupled to a first area of a body region, with a first magnetic field generating device and a first radiofrequency electrode, a second applicator to be coupled to a second area of the body region, with a second magnetic field generating device. The device further includes a first energy storage device, a second energy storage device, and a first switching device to discharge energy from the first energy storage device to the first magnetic field generating to generate a first time-varying magnetic field to cause muscle contraction, and a second switching to discharge energy from the second energy storage device to the second magnetic field generating device to generate a second time-varying magnetic field. The first radiofrequency electrode may provide first radiofrequency waves causing heating of tissue within the first area of the body region.

An example treatment device includes a main body having a first end, a second end, an intermediate portion, a light source, a capacitor, a motor, and a controller. The treatment device may be configured to provide a user with one or more of intense pulsed light treatment, hair removal, and/or vibrational stimulation.

Apparatus and methods for tissue excision. In certain aspects, the apparatus and methods include an annular converging laser beam. The annular converging laser beam can be directed to a surface of a tissue and displace a portion of the tissue in a single or multiple laser pulses. In particular aspects, the dosimetry of the laser beam (e.g. the beam shape, pulse energy and pulse duration) can be controlled to eject the portion of the tissue in a manner to reduce damage to the displaced tissue and the surrounding tissue.

Provided herein is a multifunctional aesthetic system including a housing, an electromagnetic array situated in the housing and having a plurality of electromagnetic radiation (EMR) sources, each EMR source configured to generate an EMR beam having a wavelength different than that of an EMR beam generated by another of the EMR sources, a controller in electronic communication with the array to operate two or more of the EMR sources to direct the EMR beam to a treatment area, and a sensor in electronic communication with the controller for providing feedback to the controller based on defined parameters to allow the controller to adjust at least one operating condition of the multifunctional system in response to the feedback.

The optical module disclosed herein has a first lens, a second lens and an array lens arranged sequentially along the main optical axis. The first lens shapes a beam along the first direction of the main optical axis. The second lens shapes the beam along the second direction of the main optical axis. The array of array lenses is arranged along the second direction. A laser beam enters the second lens after passing through the first lens. The second lens diffuses the laser beam along the second direction. After the laser beam is converted from a Gaussian distribution to a flat-top distribution in the second direction, the laser beam is emitted through the array lens. The first direction and the second direction are perpendicular to each other.

According to an aspect, there is provided a system (40) configured to perform a personal care operation on skin of a subject. The system (40) comprises a processing unit (46) and a personal care device (2). The personal care device (2) comprises a housing (4) having an aperture (10) that is arranged in the housing (4) such that the aperture (10) is adjacent to the skin when the personal care device (2) is in contact with the skin and is to be used to perform the personal care operation on the skin. The personal care device (2) also comprises an imaging unit (44) disposed in the housing (4) and arranged to obtain images of the skin adjacent to the aperture (10) using light passing through the aperture (10) into the personal care device (2), wherein, in a skin contact detection mode of the system (40), a focal plane (66) of the imaging unit (44) is aligned with the aperture (10). The processing unit (46) is configured to receive, in the skin contact detection mode, one or more images obtained by the imaging unit (44) in the skin contact detection mode, and to process the one or more images to determine whether the personal care device (2) is in contact with the skin.

The invention relates to a skin treatment device comprising a handle with an energy supply, an application head with at least one heat source comprising at least one semiconductor light source, and at least one heat sink comprising cooling fins. The heat sink is located remote from the heat source within the handle. Further, the heat source is thermally connected to the heat sink by means of a heat transfer system (6, 6′, 6″) which comprises a hermetically sealed tubular body containing a working medium, wherein the pressure within the tubular body is chosen such that the working medium is a saturated liquid at room temperature and may be vaporized by the heat source.

A device for cooling the skin tissue of a patient during a procedure using energy includes a mat-like structure, the mat-like structure having a bottom wall, a top wall and upstanding walls connecting the top wall and the bottom wall, the walls defining an enclosed volume; it also includes one or more electrodes positioned to protrude from the bottom wall and extend through the volume for connection to a source of energy; further, the volume defines a space for holding a cooling substance for cooling the one or more electrodes and the skin tissue during an energy-based procedure.

Systems and methods are provided for locating anatomical features in the skin based on analysis of reflected light, and treating the located anatomical features using high-energy light. A labeling agent can be administered to optically differentiate the anatomical feature.

A skin treatment device for home use is provided herein. The device has enhanced safety features and improved operation efficiency. RF energy is delivered under strict control to a relatively small and well localized volume of the skin, avoiding excessive heating of the skin surface. Surface heating is monitored both by direct temperature measurement and by movement monitoring of the device to ensure proper use and prevent skin overheating and the pain associated therewith.