Abstract: The invention provides a treatment device (100) for fractional laser-based skin treatment. The treatment device comprises an emission window (70) comprising an elongated area (75) and a plurality of predefined locations (74) in said elongated area (75), wherein the predefined locations (74) are arranged in an elongated array which extends along a treatment axis (72) of the window (70), and wherein each predefined location (74) in the array is located at a distance from the treatment axis (72), seen in a direction perpendicular to the treatment axis (72), which is smaller than 25% of a maximum distance between two predefined locations (74) in the array, seen in a direction parallel to the treatment axis (72).

Abstract: An increasing number of non-invasive skin treatment devices are being provided for use by consumers instead of by medical professionals. Such home use raises new concerns, such as safety and treatment efficacy. The invention improves on existing devices and treatment methods. The invention provides a device and method, wherein a light source is configured and arranged to provide a first (31) and a second (32) region of non-zero intensity within a transverse cross-section of a laser light beam (21) having a single higher-order laser beam mode, and a third region (33), disposed between the first (31) and second (32) regions, of lower light intensity than the non-zero light intensity. The first (31) and second (32) regions are configured to create, during use, a lesion in skin tissue in the focal spot of the laser light beam, and the third (33) region is configured to avoid creating in the focal spot, during use, a lesion in skin tissue between the lesions created by the first and second regions.

Abstract: The invention provides a non-invasive device (100) for skin rejuvenation using a treatment pressure below ambient pressure, and provides a method and a computer program product. The non-invasive device comprises a suction chamber (110) having a skin contact surface (115) comprising an opening (120) for exposing the skin tissue (200) to the suction chamber for applying a suction force to an outer surface (210) of the skin tissue. The opening in the suction chamber is less than 10 square millimeters. The suction chamber is dimensioned so as to allow it to be manually applied to the outer surface of the skin tissue. The non-invasive device further comprises a controller (140) for controlling a level of treatment pressure (Pt) inside the suction chamber (110) and for controlling an application time interval (?t) of the treatment pressure for damaging an interface (225) between an epidermis layer (220) and a dermis layer (230) of the skin tissue.

Abstract: The application provides a non-invasive measurement device (30) and method for the measurement of skin properties using laser light, the device comprising a probe module (70) and an imaging module (50). The application also provides a non-invasive treatment device (130, 230, 330, 430) and method comprising the measurement device/method. The probe module (70) provides a probe light beam (82) that enters the skin along the probe axis (71). The probe light beam (82) is separate from any treatment radiation beam (22), so that the probe light beam (82) can be optimized for the measurement. A more reliable skin measurement system is provided because it measures a plurality of positions along the probe axis (71), within a probe region (95). The measurement device and method may also comprise a treatment module (110) or treatment step. The skin parameters measured may then be directly used to control the treatment parameters.

Abstract: The invention provides a non-invasive device (100) for treatment of skin tissue using laser light, and it provides a method and a computer program product. The non-invasive device comprises a light emission system (110) for generating a first laser pulse (130) and a subsequent second laser pulse (150) at a predefined time delay (?T) after the first laser pulse. The non-invasive device further comprises an optical system (160) for focusing, in use, the first laser pulse and the second laser pulse at a treatment location (210) inside the skin tissue (200). The first laser pulse comprises a first power density, a first pulse duration and a first pulse energy for initiating a plasma (205) at the treatment location.

Abstract: The present application relates to a microdermabrasion device (1). The device has a suction path (11) along which skin fragments removed by the device are drawn, and a detection unit (3) configured to determine one or more characteristics of skin fragments drawn along the suction path. The detection unit is configured to determine the depth of abrasion performed by the device based on the one or more characteristics of skin fragments drawn along the suction path. The present application also relates to a method of determining the operating depth of abrasion of a microdermabrasion device.

Abstract: A skin treatment device comprising a light source for providing a light beam for optically treating a skin, a wheel with a wheel surface for reflecting the light beam towards the skin, wherein different angular positions of the wheel correspond to respective different directions of reflection for the light beam, driving means for rotating the wheel for changing the angular position of the wheel, an angular position detector for detecting the angular position of the wheel, a storage means for storing a predefined skin-treatment pattern and a relation between the different angular positions of the wheel and the corresponding respective different directions of reflection for the light beam, and a control circuit coupled to the light source, the angular position detector and the storage means and being operative to control the light source in dependence on the angular position detected by the angular position detector in such a way that, for each revolution of the wheel, the light beam only illuminates the wheel

Abstract: A method of treating a skin tissue area, in particular non-invasively treating the skin tissue area (1), is provided. The skin tissue area has a dermis layer area (3), an epidermis layer area (5) providing a skin surface (7) and covering the dermis layer area. The method comprises: a first step of causing one or more dermal lesions (11) localized in the dermis layer area while avoiding epidermal damage, and a second step of causing, separately from causing said plurality of dermal lesions, a plurality of epidermal lesions (15) localized in the epidermis layer area. An apparatus is also provided.

Abstract: A skin treatment apparatus (1) for treating a skin surface, comprising: a hand held base body (10); a rotor head (20), movably connected to the base body (10), and including at least one skin contacting element (22); a motor (30), operably connected to both the base body (10) and the rotor head (20), and configured to rotatably drive the rotor head (20) relative to the base body (10) around a rotation axis (L); at least one motion sensor (40), configured to generate a movement signal reflecting a path of relative movement between the motion sensor and the skin surface; and a control unit (50), operably connected to the at least one motion sensor (40) and the motor (30), and configured to control the motor (30) to rotatably drive the rotor head (20) in dependence of the movement signal of the at least one motion sensor (40).

Abstract: An apparatus for treating a skin tissue area (1) is provided, comprising: an energy source configured to heat the skin tissue area to a temperature in a range of about 55-65° C., a cooler configured to cool the skin tissue area to a temperature below about 40° C. Further, a skin tissue deformer configured to mechanically deform the skin tissue area into a deformed shape and to maintain the skin tissue area in the deformed shape, and a controller configured to operate the apparatus to perform a method of treating a skin tissue area (1). The method comprises the steps of: mechanically deforming the skin tissue area into a deformed shape; heating the skin tissue area to a temperature in a range between about 55° C. and about 65° C.; cooling the skin tissue area to a temperature below about 40° C. while maintaining the skin tissue area in the deformed shape, and the steps of reheating the skin tissue area to a temperature in a range between about 55° C. and about 65° C.

Abstract: A method of treating a skin tissue relief feature (3) in mammalian, in particular human, skin tissue (1) is provided. The method comprises the steps of: determining a perimeter (4) of the relief feature and inducing contraction of skin tissue areas (5) present on opposite sides of the relief feature in positions adjacent to respective portions of the perimeter in a direction of contraction substantially parallel to a skin surface and substantially normal to the respective portions of the perimeter. A system is also provided comprising a radio-frequency source (9) and an applicator with a roller.

Abstract: A method of treating a skin tissue area (3) having a skin surface (5) is provided. The method comprises the steps of: deforming the skin tissue area into a deformed shape comprising a plurality of folds (17) in the skin tissue area; arranging radiofrequency electrodes (13) in contact with the skin surface on opposite sides of the deformed skin tissue area; and, while maintaining the skin tissue area in said deformed shape, providing a spatially continuous radiofrequency energy flow between the radiofrequency electrodes on opposite sides of the deformed skin tissue area through the deformed skin tissue area, thereby heating at least a portion (19) of the deformed skin tissue area; and releasing the skin tissue area from said deformed shape, thereby deforming said heated portion (19) into a wave-shaped zone of heated skin tissue having a depth relative to the skin surface that varies between a minimum and a maximum value in a direction between said opposite sides.

Abstract: A method of skin tissue (1) treatment is provided which comprises the steps of: determining a treatment zone (9) within the skin tissue below the skin surface (3); modifying an electrical conductance property of at least two first skin tissue portions (11) present on opposite sides of the treatment zone with respect to a direction parallel to the skin surface; and providing radio frequency (RF) energy to the treatment zone via said first skin tissue portions. The step of modifying said first skin tissue portions comprises decreasing electrical impedance for the radiofrequency energy, in particular increasing electrical conductance, of said first skin tissue portions relative to a second skin tissue portion present between said first skin tissue portions; and such that said first skin tissue portions extend into the skin tissue substantially from the skin surface to treatment zone. A system for skin tissue (1) treatment is also provided.

Abstract: A method of and an optical arrangement for generating a non-linear optical signal on a material excited by an excitation field, wherein with the excitation field coherent fields of first and second optical pulses of differing frequency are overlapped in the material in temporal and spatial relationship, wherein the first pulses of a first frequency are generated in a first beam of a first optical generator unit, and the second pulses of a second frequency are generated in a second beam of a second optical generator unit synchronously pumped by the first optical generator unit, wherein with the first pulses of the first frequency as a fundamental frequency pulses of a higher harmonic frequency thereof are generated and the second optical generator unit is pumped with the pulses of the higher harmonic frequency.

Abstract: The invention concerns a method of and an optical arrangement (10) for generating a non-linear optical signal (17) on a material (16) excited by an excitation field (2), wherein with the excitation field (2) coherent fields of first and second optical pulses of differing frequency are overlapped in the material (16) in temporal and spatial relationship, wherein the first pulses of a first frequency are generated in a first beam (3) of a first optical generator unit (1), and the second pulses of a second frequency are generated in a second beam (8) of a second optical generator unit (7) synchronously pumped by the first optical generator unit (1), wherein with the first pulses of the first frequency as a fundamental frequency pulses (5) of a higher harmonic frequency thereof are generated and the second optical generator unit (7) is pumped with the pulses of the higher harmonic frequency.