Abstract: A device for treatment of dermatological lesions includes a gas discharge lamp for generating a plurality of different electromagnetic radiation treatments. A power supply for driving the gas discharge lamp is selectively controlled to drive the gas discharge lamp to output a first electromagnetic treatment when an area of skin being treated has a pigmented lesion, and to drive the gas discharge lamp to output a second electromagnetic treatment when the area of skin being treated has a vascular lesion, where the second electromagnetic treatment has a spectral distribution that is blue-shifted relative to the spectral distribution of the first electromagnetic treatment.

Abstract: A method for removing tattoos using two laser beams and a multi-photon process is disclosed. A 0.1 to 100 nsec pulse secondary laser beam focused to 108 W/cm2 creates a temporary channel from the skin surface to the tattoo pigment. A 100 fsec pulse main laser beam is then guided through the channel to the pigment and focused to sufficient intensity, i.e., 1012 W/cm2 or more, to initiate a multi-photon process that breaks up the pigment, disrupting its light reflecting properties. The channel allows the main laser beam unobstructed passage to the pigments, resulting in efficient use of the main laser. The pigment fragments escape through the temporary channel or diffuse into the blood stream. A suitably configured Ti/Sapphire laser beam is split into two components, with an uncompressed component used as the secondary laser beam, and a compressed component as the main laser beam.

Abstract: A system and method for providing treatments of electromagnetic radiation to areas of post-partum abdominal skin. The treatments provide for raising the temperature in a portion of post-partum abdominal skin to a treatment temperature, which is sufficient to reduce the laxity or redundancy of the post-partum skin. In one embodiment the treatment can provide treatment exposures to sub-areas, of an area of post-partum abdominal skin which has been identified for treatment, and bring a temperature of the tissue being treated to at 50° C.

Abstract: Exemplary embodiments of a method, device, and apparatus for positioning an apparatus on a location of a tissue. For example, a substantially rigid film over an area of tissue to be treated can be provided. The film can include a positioning arrangement that facilitates a particular spatial engagement with the apparatus. The exemplary method can further include applying a portion of the film to a portion of a surface of the tissue and positioning the apparatus at the location by the engagement of the film to the apparatus using the feature of the film.

Abstract: Hair or partial hair removal system and hair growth deterrent that includes mechanical process for cutting, plucking or shaving hair follicles, along with pre and/or post skin treatment techniques. The skin treatment techniques can include the application of energy to the skin surface before, after and/or during the application of the mechanical process. Such techniques include the application of heat and/or energy from illumination sources and/or RF emitters. Further skin treatment techniques include the application of solutions before, after and/or during the mechanical process and/or the application of heat and/or energy. Overall, the system operates to treat an area of skin to facilitate the removal of all or a portion of hair, retard further growth, and recovery of skin surface.

Abstract: Methods, devices and systems for delivering light therapy to human or non-human animal subjects. Included are shapeable light therapy devices which are formable into different shapes suitable for delivery of therapeutic light to different regions of the subject's body and will retain the desired shape without a need for the use of a strap or other shape-retaining apparatus. Also included are light therapy devices that, in at least some modes of operation, deliver light that is not visible to the human eye and which include indicator(s) to indicate to a user and/or to the subject being treated when non-visible light is actually being emitted.

Abstract: A dermatologic treatment device having a light source emitting optical radiation having a plurality of wavelengths. The optical radiation including light exhibiting at least a first set of wavelengths and a second set of wavelengths, in which the first set of wavelengths is preferred for a dermatologic treatment. The dermatologic treatment device further including a wavelength converter for converting at least some of the second set of wavelengths of the optical radiation to the first set of wavelengths. A contact element is also included for conveying at least some of the converted optical radiation to a skin surface to facilitate the dermatologic treatment.

Abstract: Provided are dermatological medical devices and methods comprising a distal end for positioning at a region proximal a target therapeutic region of tissue, an output port at the distal end, an energy source that generates optical energy, which is output from the output port to the target therapeutic region of tissue, and a microcontroller that processes replenishment data that controls an operation parameter of the device. The device is activated for performing a treatment operation in response to a receipt and processing of the replenishment data.

Abstract: An aesthetic treatment device and method for treating the skin of a patient, the device comprising at least one of a plurality of arc lamps, each arc lamp provided with a reflector for obtaining a substantially collimated beam; a pulse generator for generating a train of pulses of electrical energy for energizing said at least one of a plurality of arc lamps; a control unit for controlling pulse shape, amplitude, width, frequency and timing, for obtaining controllable spectral output and energy of the collimated beam through an application end of the device to a designated area of skin of the patient. The device can further comprise secondary light sources with different spectrum characteristics than the arc lamp as well as various attachments including a position feedback, material dispenser, skin cooler, and docking station for optical fiber.

Abstract: The invention provides a system and method for percutaneous energy delivery in an effective, manner using one or more probes. Additional variations of the system include array of probes configured to minimize the energy required to produce the desired effect.

Abstract: A device for treating oral ulcers or sores comprises a light source for illuminating a sore or ulcer to be treated; a laser diode for directing laser energy at the sore or ulcer; a regulated power supply for powering the light source and the laser diode at selected power levels; a first switch operable to selectively deliver power from the regulated power supply to the light source; a second switch operable to selectively deliver power from the regulated power supply to the laser diode when the switch is operated by a user to treat the located ulcer or sore; a control device configured to operate the laser diode for a selected time period each time the switch is operated and to then subsequently turn the laser diode off until the switch is operated again; and a portable, handheld housing for housing the laser diode, regulated power supply, switch, and control device.

Abstract: A medical apparatus comprising a first laser source operable to generate light at a first wavelength and supply a first laser light beam, a second laser source operable to generate laser light at a second wavelength and supply a second laser light beam, the first laser light beam being continuous or pulsed having a first, relatively long pulse duration, the second laser light beam being pulsed with a second, relatively short pulse duration, the apparatus being operable to supply the first laser light beam and subsequently the second laser light beam.

Abstract: Hair or partial hair removal system and hair growth deterrent that includes mechanical process for cutting, plucking or shaving hair follicles, along with pre and/or post skin treatment techniques. The skin treatment techniques can include the application of energy to the skin surface before, after and/or during the application of the mechanical process. Such techniques include the application of heat and/or energy from illumination sources and/or RF emitters. Further skin treatment techniques include the application of solutions before, after and/or during the mechanical process and/or the application of heat and/or energy. Overall, the system operates to treat an area of skin to facilitate the removal of all or a portion of hair, retard further growth, and recovery of skin surface.

Abstract: The present invention relates to a medical laser treatment device and a method for operating same, which aim to treat a curved area on the skin of a patient. The medical laser treatment device, according to the present invention, comprises: a main body portion having a laser oscillation portion for oscillating the laser; a hand piece, which is connected to the main body, for irradiating the laser onto the skin of the patient; and a laser tip, which is positioned between the skin of the patient and the hand piece and comes into contact with the skin of the patient so as to guide the laser, wherein the laser tip applies pressure to one side of a blood vessel on the inside of an irradiation area.

Abstract: A system and method for using a light source to treat tissue with NIR light. The operation provides for generating higher temperatures in deeper layers of tissue relative to higher layers of tissue. The increased temperature in dermal layers can operate to induce collagen shrinkage, or remodeling. One of the light sources for providing a broad spectrum of NIR light is a filament light. The light from the filament lamp can be selectively filtered, and after filtering this light is applied to the skin, where the selective filtering can enhance the ability to elevate the temperature of deeper layers of tissue, relative to layers of tissue which are closer to the surface of the skin.

Abstract: Systems and methods that enable delivery of radiofrequency energy and cryotherapy applications to adipose tissue for reduction and contouring of body fat are described herein. Aspects of the disclosure are directed to methods for reducing surface irregularities in a surface of a subject's skin resulting from an uneven distribution of adipose tissue in the subcutaneous layer. The method can include delivering capacitively coupled or conductively coupled radiofrequency energy to a target region of the subject at a frequency which selectively heats fibrous septae in a subcutaneous layer of the target region to a maximum temperature less than a fibrous septae denaturation temperature. Furthermore, the method can include removing heat such that lipid-rich lobules in the subcutaneous layer are affected while non-lipid-rich cells and lipid-rich regions adjacent to the fibrous septae are not substantially affected.

Abstract: Enhanced delivery of compositions for treatment of skin tissue with photoactive plasmonic nanoparticles and light, with embodiments relating to delivery devices using, for example, ultrasound. Treatments are useful for cosmetic, diagnostic and therapeutic applications.

Abstract: The present invention relates to a composition for topical application on skin for photoepilation comprising nanocomplexes which comprise a nanoparticle supporting an LSP resonance which is coated with at least a chemical compound, wherein said chemical compound is selected from the group consisting of polyionic polymers, heterobifunctional compound of the surface assembled monolayer type, antibodies and their mixtures. The present invention also relates to a photoepilation method which comprises the steps of (i) applying to the skin surface the composition for topical application of the present invention, and (ii) applying a radiation to said surface of the skin.

Abstract: A light source apparatus including light spectrum-converting materials that emit light primarily over large portions of the 360 nm-480 nm and the 590-860 nm spectral range is provided. This apparatus provides a cooled, high-luminance, high-efficiency light source that can provide a broader spectrum of light within these spectral ranges than has been cost-practical by using many different dominant peak emission LEDs. Up to 15% of the output radiant power may be in the spectral range 350-480 nm in one embodiment of this device, unless a specific separate source and lamp operating mode is provided for the violet and UV. Control methods for light exposure dose based on monitoring and controlling reflected or backscattered light from the illuminated surface and new heat management methods are also provided.

Abstract: A skin treatment apparatus includes a handle body, a driving unit received in a receiving cavity of the handle body, a treatment head unit, and an inlet arrangement. The treatment head unit includes a supporting member provided at the front end portion of the handle body, a treatment cap detachably attached on the supporting member, a treatment shaft rotatably connected to the driving unit and extended from the driving unit into a treatment cavity, and an abrasion head integrally formed at a free end of the treatment shaft in such a manner that when the treatment shaft is driven to rotate, the abrasion head is also driven to rotate with respect to the handle body. The inlet arrangement is formed at the supporting member of the treatment head unit for providing a predetermined amount of skin treatment fluid in the treatment cavity.

Abstract: A hair treatment (40) device is provided comprising a light-based detector (10) for detecting a hair (22) near a skin surface (21) the detector (10) comprising a light source (11), optical elements (14, 16, 17, 18) and a polarization-sensitive light sensor (12, 13). The light source (11) is provided for generating a light beam (31) with an incident polarization. The optical elements (14, 16, 17, 18) are provided for focusing the light beam (31) at the hair (22) near the skin surface (21). The polarization-sensitive light sensor (12, 13) is provided for detecting light interacted with the hair (22) or the skin surface (21) and having a predefined linear polarization. The light source (11) and/or the optical elements (14, 16, 17, 18) are arranged to cause the light beam (31) to simultaneously have multiple spatially separated foci (51, 52, 53) at or near the hair (22) or the skin surface (21).

Abstract: Skin cooling apparatus is provided for use with a medical treatment device such as a hypodermic syringe or a skin ablation laser or other electromagnetic source. The skin cooling apparatus provides selective, localized cooling of the target area that is acted upon by the medical treatment device. Included is a support body engaging at least a portion of the medical treatment device, for supporting and orienting the medical treatment device to the target area. A solid state cooling device such as a thermoelectric or Peltier device is carried by the support body and includes a cooling surface facing the target area of a patient's skin surface. The support body may be flexible so as to allow the medical treatment device to be inclined relative to the skin surface. The support body may also include aiming structure for directing the medical treatment device to a particular point within the target area.

Abstract: A device configured to cut hair using laser light includes a handle portion and a shaving portion. The handle portion includes a battery and a laser light source. The laser light source is coupled to and configured to receive power from the battery. The laser light source is also configured to generate laser light having a wavelength selected to target a predetermined chromophore to effectively cut a hair shaft. The shaving portion includes a support and a single fiber optic supported by the support. The fiber optic has a proximal end, a distal end, an outer wall, and a cutting region positioned towards the distal end and extending along a portion of the side wall. The fiber optic is positioned to receive the laser light from the laser light source at the proximal end, conduct the laser light from the proximal end toward the distal end, and emit the light out of the cutting region and toward hair when the cutting region is brought in contact with the hair.

Abstract: In some embodiments, the instant invention provides for a system that includes at least the following components: (i) an Alexandrite laser pumping subsystem; where the Alexandrite laser pumping subsystem is configured to: 1) produce wavelengths between 700 and 820 nm, and 2) produce a pump pulse having: i) a duration between 1 to 10 milliseconds, and ii) an energy measuring up to 100 Joules; where the Alexandrite laser pumping subsystem includes: 1) an optical fiber, and 2) a Lens system, (ii) a Thulium doped Yttrium Aluminum Garnet (Tm:YAG) laser subsystem; where the Tm:YAG laser subsystem includes: 1) a Tm:YAG gain medium, 2) a rod heat sink, and 3) at least one cooling device, (iii) a wavelength selecting device, where the wavelength selecting device is configured to deliver a wavelength between 1.75 microns to 2.1 microns; and where the system is configured to produce a high energy conversion efficiency.

Abstract: The present invention relates to methods for use in the selective disruption of lipid-rich cells by controlled cooling. The present invention further relates to a device for use in carrying out the methods for selective disruption of lipid-rich cells by controlled cooling.

Abstract: A hair removal device utilizes a system for sensing the presence and color of skin. The system includes a skin color sensor assembly and a capacitive sensor assembly disposed in a housing. The skin color sensor assembly includes a light pipe communicating with a color sensor aperture of the housing and having one or more notches defining receiving and emitting light propagation regions, a color sensor and one or more light emitting diodes, and a holder having at least one standoff mated to the notches thereby directing light emitted by the light emitting diodes through the light pipe for reflection of an external surface and receipt by the sensor for detection of surface color. The capacitive sensor assembly includes a plurality of copper elements in proximity to a device aperture and contacting an interior surface of the housing and for detection of an object in contact with the copper elements.

Abstract: A medical device includes a housing that is moved along a surface of a target tissue in a longitudinal direction. One or more supply lines conduct air and water to the housing. A pulse emitter emits electromagnetic pulses toward the surface at a repetition rate for the pulses to produce ablation holes in the tissue. The pulse emitter includes optical components and is configured to direct the air against the optical components to keep the optical components clean. One or more nozzles emit the water and the air in an air/water spray to moisturize and cool the target tissue prior to laser application.

Abstract: The present invention is directed to systems, apparatus, methods and procedures for the noninvasive treatment of tissue using microwave energy. In one embodiment of the invention a medical device and associated apparatus and procedures are used to treat dermatological conditions using microwave energy.

Abstract: The invention provides a skin treatment device comprising a laser source (40) and focusing optics (50), such that a focal spot (18) is positioned in a dermis layer (24) of the skin to be treated. The laser beam (42) is powered and focused (16) such that a LIOB (laser induced optical breakdown) phenomenon is obtained, which affects the skin in order to stimulate re-growth of tissue. This in turn reduces wrinkles (30). The device may comprise wrinkle-determining means (52, 54, 56, 58). The focusing optics (50) may have a numerical aperture of at least 0.4. The invention also provides a corresponding method to treat skin, in particular to reduce wrinkles (30), by providing a focused laser beam (16) that causes LIOB in the dermis layer (24) of the skin. The advantage is that damage to overlaying epidermis layers may be avoided by the use of the very local LIOB phenomenon.

Abstract: For lightening or eradicating pigments in human skin, a first conditioning laser optical energy having first optical parameters selected to obtain an ablative effect on the epidermal layer of human skin is provided. A target area of the human skin is conditioned by directing the first conditioning laser optical energy onto the target area and forming in an epidermal layer of the target area discrete pressure and gas release ducts across the target area. A second treatment laser optical energy is provided that has second optical parameters selected to obtain a lightening or eradicating effect on the pigments located within the human skin and to substantially avoid damaging the epidermal layer of the human skin. The second treatment laser optical energy is directed onto the target area subsequent to conditioning, and the pigments within the human skin are lightenmed or eradicated by the second treatment laser optical energy.

Abstract: A device and method of hair removal treatment is disclosed, The device includes a combination of two light sources one an IPL and second an incandescent lamp type, halogen or others. The two light sources are applied simultaneously or sequentially to the treated area. The present invention relates to a method for hair removal treatment where multiple light sources are combined together and include at least one pulsed arc lamp, and are operated simultaneously or sequentially to treat a selected skin area. The incandescent light energy will raise the overall skin temperature while the arc lamp will selectively ablate the hair follicle with minimum collateral damage.

Abstract: The present invention relates generally to methods of preventing or treating toxicities of the skin, hair, and/or nails, which are associated with administration of one or more multikinase inhibitors, with light-emitting diode photomodulation treatment, either alone or in combination with other agents.

Abstract: A laser depilatory device is provided where the tips of skin hairs can be trimmed evenly after cauterization and the skin hair can he removed efficiently with lower power consumption, while preventing the direct adverse influent of het on the human skim The laser device includes: a housing including a contacting surface to which a skin surface is contacted and a recessed portion formed on the contacting surface; a laser light generating section disposed in the housing for generating laser light; and a first hole portion formed on an inner wall surface of the recessed portion for emitting the laser light through a space inside the recessed portion towards the inner wall.

Abstract: An LED induced tattoo removal system and method of use that utilizes an ultra bright LED having a principal peak with a peak at 640 nm-700 nm for tattoo removal without causing collateral skin damage and without causing pain to a subject is disclosed. The tattoo removal method includes an LED, which generates light in a specific range of wavelengths proven to be effective for this purpose. The method also includes optionally applying a vasodilator after the LED exposure and further includes optionally utilizing an electrical or chemical heat source after the LED exposure. The tattoo removal method comprises irradiation of the tattooed region using ultra bright LED light for a timed interval and the optional application of a vasodilator formulation, which increases blood circulation to the tattooed skin region and also increases the concentration macrophage cells in the treated skin region to metabolize the tattoo ink and its by-products.

Abstract: The invention relates to a system and method for removing hair. The hair removal system comprises a hair detection device and a hair removal device (20; S3) operatively coupled to the hair detection device, wherein the hair detection device comprises an imaging device comprising a first image sensor (12; S1) which is constructed and arranged to detect an image of a part of a skin (30) to be treated, and a control unit (18) adapted to discern, in the image, a hair (32) on the part of the skin (30), and operatively coupled to the hair removal device (20; S3) so as to control its operation, characterized by preventing means coupled to the control unit (18) and being adapted to disable the hair detection device or the hair removal device during a preventing period after the control unit has discerned the respective hair for the first time.

Abstract: Methods, apparatus, and systems for transcutaneously treating tissue located beneath a skin surface with electromagnetic energy delivered from a treatment electrode. A portion of the treatment electrode is contacted with the skin surface. While maintaining the contact between the portion of the treatment electrode and the skin surface, the electromagnetic energy is delivered from the treatment electrode in a plurality of power pulses through the skin surface to the tissue over a treatment time with a time gap between each consecutive pair of the pulses to lower a level of pain perceived by a patient.

Abstract: The present invention relates generally to methods of preventing or treating toxicities of the skin, hair, and/or nails, which are associated with administration of one or more vascular endothelial growth factor receptor inhibitors, with light-emitting diode photomodulation treatment, either alone or in combination with other agents.

Abstract: Method of producing a therapeutic laser device (TLD). The TLD includes stretchable, flexible membranes which comprise a high pressure air cavity. High air pressure is produced by fans which are speed controllable by computer. Standoff posts provide, an attachment function, and a separation function between the TLD and the patient. Semiconductor laser diodes and lens sets in a two dimensional array produce the therapeutic laser light. Cooling air tubes direct air controlled by temperature sensors from the high pressure cavity onto laser diodes. Capacitive proximity sensors in conjunction with infrared radiation sensors confirm close contact with a patient and allow lasing. Power is supplied either by battery or by connection to mains power. A touch screen computerized device with wireless communication displays information to the user and controls the therapy session. The TLD and the power supply both have stretchable straps enabling the TLD to be fixed to the patient.

Abstract: An apparatus for treating a subcutaneous fat region is provided. The apparatus includes a housing that has a skin contacting portion defining a chamber. The apparatus also includes a first spaced region in the housing through which a coolant passes and a second spaced region in the housing that is at least partially evacuated of air. The apparatus further includes a source of electromagnetic radiation, a source of vacuum in fluid communication with the chamber, and a source for the coolant.

Abstract: A sensor for detecting the presence of skin is disclosed, one configuration of which uses multiple light emitting diodes, each of a unique wavelength band, and a broad-band photodetector to measure the remission of light at multiple wavelengths from a material being analyzed. Characteristics of the spectral remission of the material are used to discriminate human skin from materials that are not human skin. Further, an aesthetic medical device utilizing such a sensor in which the device is inhibited from operation if skin has not been detected. The incorporation of a skin sensor improves the safety of devices that emit radiation that otherwise would pose a hazard if not directed onto skin.

Abstract: Phototherapy systems comprising a therapeutic lamp platform for radiant lamps such as LEDs disposed in an assembly comprising a first wall to which the lamps are affixed thereto and a second wall, closer to the patient, spaced from the first wall wherein the lamps are recessed relative thereto. The second wall comprises a reflective surface facing towards a patient and a plurality of light apertures substantially aligned with the LEDs on the first wall for communicating lamp radiation from the lamps to a user. The lamps and associated circuitry are disposed between the first and second wall so that the reflective surface is relatively smooth and seamless towards the patient. The walls have a malleable rigidity for flexible adjustability relative to the user. The device is mounted to the user with a frame comprising an eyeglass frame or goggles including lenses for shielding the user's eyes from lamp radiation.

Abstract: An improved procedure for performing liposuction is obtained by utilizing a needle that includes a laser source conductor with one end of the needle being configured for insertion into a target adipose skin volume and the other end being coupled to a laser source. The needle may include one or more channels for extracting the treated adipose area. A vacuum source can be used in the extraction of the treated adipose. Further, the first end of the needle may include a cap or end-piece that reduces the build up of carbon deposits. A temperature sensor may be used as input to adjust the laser power and prevent over exposure.

Abstract: The device includes a housing, a flash lamp arranged inside the housing, the housing having an opening through which electromagnetic energy originating from the flash lamp can be transmitted towards a skin surface. The housing includes a cavity adjacent to the flash lamp; at least one aeration orifice; and at least one mobile component in the housing, which can be displaced between a first so-called aeration position, in which the cavity communicates with the aeration orifice and a second so-called closed position, for which the cavity is closed in order to limit the light escaping from the opening.

Abstract: A cordless, hand-held dermatologic hair-regrowth-inhibiting apparatus may include: a self-contained housing configured for gripping by a person's hand for cordless manipulation in a hair-regrowth-inhibiting procedure; a light source comprising one or more diode laser bars within the housing; a direct drive electrical circuit within the housing comprising one or more batteries for energizing the light source to produce output light pulses, wherein the electrical circuit does not include any storage capacitors that energize the light source by capacitor discharge; and a light path within the housing including an aperture through which the output light pulses are propagated out of the housing having properties sufficient for at least temporary hair-regrowth inhibition.

Abstract: A dermatologic hair-regrowth-inhibiting apparatus is disclosed which is cordless and sufficiently compact as to be hand-held. A self-contained housing is configured for gripping by a person's hand for cordless manipulation in a hair-regrowth-inhibiting procedure. A light source and electrical circuit are contained within the housing. The circuit includes one or more batteries for energizing the light source to produce output light pulses. A light path within the housing includes an aperture through which eye-safe light pulses are propagated out of the housing having properties sufficient for at least temporary hair-regrowth inhibition. A diffuser is disposed along the light path to reduce the integrated radiance to an eye-safe level.

Abstract: The invention provides a hair treatment device (40) comprising a light-based detector (10) for detecting a hair (22) near a skin surface (21) and a method for detecting a hair (22) near a skin surface (21). The detector (10) comprises a light source (11), optical elements (14, 16, 17, 18) and a polarization-sensitive light sensor (12, 13). The light source (11) generates a light beam (31) and the optical elements (14, 16, 17, 18) focus the light beam (31) at a hair (22) near the skin surface (21). The polarization-sensitive light sensor (12, 13) is provided for detecting light interacted with the hair (22) or the skin surface (21) and having a predefined linear polarization. The light source (11) and/or the optical elements (14, 16, 17, 8) are arranged to cause the light beam (31), when reaching the skin surface (21), to have a polarization direction which is time-invariant and spatially variant in cross-sections of the 10 light beam.

Abstract: A skin cooling method for a dermatologic treatment procedure, by which a skin target region is exposed for a specified duration to irradiation with electromagnetic energy emitted from an electromagnetic energy exit opening of a skin treatment applicator and the target region is cooled at least during part of the duration of the exposure to electromagnetic energy irradiation, wherein a cooling procedure is performed including an air cooling step comprising ejection of a directional flow of cooling air towards the skin treatment region, said directional cooling air flow having a temperature T in the interval 0° C.<T?15° C. In an apparatus according to the invention this method may be combined with one or more contact cooling steps.

Abstract: Light-source treatment devices such as dermatological or cosmetic devices include a skin contacting surface layer that is antimicrobial. The antimicrobial skin contacting surface layer enhances the cleanliness of the device and helps reduce infection and contamination risks associated with use of the devices, particularly where the treatment of multiple individuals occurs. The antimicrobial layer may be titanium dioxide.

Abstract: A skin proximity sensor and method are disclosed in a dermatologic treatment device that includes a bezel or similar surface, and a treatment source capable of being activated to supply a dermatologic treatment through the bezel or surface, such as a window or similar port. A plurality of contacts leading to remotely located capacitors, in some embodiments, or a plurality of capacitive sensors in other embodiments, is positioned in or under the bezel and around the window, and control circuitry coupled to the plurality of capacitors senses the change in capacitance due to skin and inhibits activation of the dermatologic treatment device unless the proximity of skin is sensed. The presence of skin is detected, for example, by measuring changes in charge and discharge times, indicating a variation in capacitance.

Abstract: A laser system has a laser source for generating a laser beam, a control unit, and a hand piece for manually guiding the laser beam onto a target area. A wavelength (?) of the laser beam is in a range from above 1.9 ?m to 11.0 ?m inclusive. The laser system is adapted for a thermal, non ablative treatment of mucosa tissue by the laser beam such, that the laser source generates the laser beam in single pulses with a pulse duration (tp) in a range from 1.0 ?s, inclusive, to 1.0 sec, inclusive, and that a fluence of each of the single pulses on the target area of the mucosa tissue is in a range from 0.2 J/cm2, inclusive, to 2.5 J/cm2, inclusive, and preferably in a range from 1.40 J/cm2, inclusive, to 1.95 J/cm2, inclusive.