Abstract: The present invention is directed to a method for creating permanent or semi-permanent images on a pre-determined treatment area of the skin wherein electromagnetic radiation (“EMR”) is applied to the treatment area. Based on the EMR energy density selected, no hypertrophic scarring occurs. The skin is nevertheless hypopigmented where the spot is directed. When the treated area is tanned, the selected image appears. When the skin is pale, the selected image does not appear.

Abstract: A handpiece can treat biological tissue using electromagnetic radiation, which can be substantially fluorescent light. The handpiece includes a source of electromagnetic radiation and a waveguide. The waveguide is adjacent the source, receives electromagnetic radiation from the source, and delivers the electromagnetic radiation to the biological tissue. The handpiece also includes a system for moving a fluorescent substance through the waveguide. The fluorescent substance includes a fluid base and a fluorescing agent and is capable of modulating at least one property of the electromagnetic radiation. A method is described for removing the fluorescing agent from the fluorescing substance and replacing it with a second, different fluorescing agent.

Abstract: A method for non-invasive temperature determination in biological tissue treated with treatment radiation wherein a reaction which depends on the treatment temperature is generated and detected. Measurement radiation pulses and pulses of the treatment radiation are applied to the tissue to be treated successively, in particular in an alternating way, from the same radiation source. A device includes a radiation source, an irradiation lens system, detectors for determining a reaction and a system control suitable for controlling treatment radiation and measurement radiation pulses. The system control generates successive, in particular alternating, pulses of treatment radiation and measurement radiation pulses from one radiation source only, in particular a laser which can be modulated.

Abstract: Embodiments of the present disclosure provides systems, devices, and methods for non-invasively modifying, maintaining, or controlling local tissue optical properties. Methods and devices of the disclosure may be used for optically clearing tissue, for example, for diagnostic and/or therapeutic purposes. A method of optically clearing a tissue may comprise contacting the tissue with an optical clearing device having a base, an array of pins fixed to one side of the base, a brim fixed to the base, an inlet port in the base, an exit port in the base, and a handpiece interface tab fixed to the side of the base opposite the array of pins, applying a mechanical force to the tissue, and illuminating said tissue with at least one wavelength of light through the optical clearing device. A method may further comprise controlling the temperature of the tissue illuminated.

Abstract: A dermatological laser apparatus for irradiating human tissue with optical pulses includes a laser source (2) producing an optical output, a pulse shaper (4) coupled to the laser source for converting the optical output into optical pulses having desired shapes, and an optical delivery tool (8) coupled to the pulse shaper for applying the optical pulses sequentially to a multiplicity of sites on the human tissue with consecutively irradiated sites being non-adjacent.

Abstract: The present invention discloses a method for controlling growth of hair on human skin with low doses of electromagnetic radiation, and a device (1) for carrying out the method. In the method, radiation (13) of a suitable spectrum is applied to the skin (12), in one or more pulses of between 1 and 100 ms, and with maximum fluencies on the skin between 1 and 12 J/cm2. By applying such low fluencies and at controlled pulse durations, follicles of the hairs are induced to the catagen phase. This means that the growth of the hairs of those follicles will stop. Although the method is not primarily aimed at immediate hair removal, hairs may be shed subsequently. In any case, further growth may be stopped for prolonged periods of time. The main advantage of the method is that the risk of damage to the skin is minimized.

Abstract: Provided is a decontamination apparatus including a base, and a source that emits UVC light at a suitable intensity to at least partially decontaminate a target object and render the target object pathogen reduced. An adjustable support is coupled to the base and includes an adjustment mechanism that can be manipulated to adjust a position of the source relative to the base. A controller is operatively connected to the source to control emission of the UVC light and establish at least one of a suitable duration of a decontamination process and a suitable intensity of UVC light to render the target object pathogen reduced.

Abstract: A pilomotor effect stimulating device is designed to electrically stimulate the arrector pili muscles of the skin to cause a pilomotor reaction in which goosebumps are formed in the affected area and the hairs are raised away from the skin. The device has a handle and a head at one end of the handle carrying electrodes for skin application. An electronic control unit in the handle is connected to the handles and includes a pulse generator configured to produce a pulsed electrical signal at the electrodes which is designed to stimulate the arrector pili muscles in the vicinity when the electrodes are applied to the skin. The device may be used as a shaving aid to raise the hairs in an area to be shaved, making it easier to cut the hairs closer to the skin when shaving.

Abstract: In one embodiment, a handheld laser treatment apparatus comprises: a handset including a treatment chamber, the treatment chamber having an open treatment aperture; a laser array arranged to project optical energy into the treatment chamber and coupled to a power source; at least one vacuum channel positioned within the treatment chamber and coupled to a vacuum source; a trigger sensor coupled to logic that controls activation of the laser array and the vacuum channel; an attachment sensor arranged to detect which of a plurality of attachments are inserted into the treatment chamber through the treatment aperture. The logic enables activation of the vacuum channel when the attachment sensor detects a first attachment of the plurality of attachments inserted into the treatment aperture. The logic disables activation of the vacuum channel when the attachment sensor detects a second attachment of the plurality of attachments inserted into the treatment aperture.

Abstract: Device for destroying parasites on fish, such as salmon lice on salmon in fish farms, comprising a camera (4) communicating with a controlling unit (51) which in turn communicates with a light source (5) adapted to fire pulses of point shaped light which is harmful for the parasite in question. The controlling unit (51) controls a system for optical recognition within a defined coordinate system and is arranged to detect points and to update in real time coordinates that exhibits contrast differences typical for parasites on a fish surface and to trigger a light pulse from the light source (5) when the coordinates for at detected point coincides with the coordinates for the aiming point of the light source.

Abstract: Data representing animated hair in a computer generated imagery (CGI) scene may be compressed by treating hair data as arrays of parameters. Hair data parameters may include control vertices, hair color, hair radius, and the like. A principal component analysis (PCA) may be performed on the arrays of hair data. PCA may yield new basis vectors, varying in length, with the largest basis vector corresponding to a new dimension with the largest variance in hair data. The hair data may be quantized based on the varying lengths of new basis vectors. The number of bits allocated for quantizing each new dimension corresponding to each new basis vector may be determined based on the relative lengths of new basis vectors, with more bits allocated to dimensions corresponding to longer basis vectors. The quantized hair data may be bit-packed and then compressed using lossless entropy encoding.

Abstract: A device of guiding a multiple area dermatologic care process. The device comprises a carrier which supports a drive of a dermatologic care tool over a skin area while the dermatologic care tool intermittently performs a plurality of dermatologic care sessions each in one of a plurality of skin subareas of the skin area and a brake unit which regulates a movement of the carrier from a first skin subarea to a second skin subarea during the drive of the dermatologic care tool.

Abstract: Embodiments of methods and systems for hair treatment are disclosed. According to various embodiments, light is used to shave, trim, or otherwise modify hair shafts.

Abstract: An improvement in a method for providing localized cooling of tissue when thermally mediated by electromagnetic radiation including directing at least one spurt of a heat transferring substance onto a selected location on the tissue, and preventing ignition of the heat transferring substance by heating from the electromagnetic radiation. Preferably liquid carbon dioxide under pressure is supplied as the heat transferring substance, and adiabatically expanded to provide a solid carbon dioxide spray onto the selected location.

Abstract: A system and method for controllably releasing radiation in percutaneous radiation treatment is provided. In a preferred embodiment, a laser is coupled to an optical fiber that is inserted below the skin or into a vascular lumen to a predetermined point. The fiber is connected to a source of electromagnetic radiation such as a laser, non-coherent radiation source, high power laser diode, LED, and an ultrasonic source. Radiation is then delivered to the treatment site while the fiber is simultaneously drawn out to the entry point. The fiber is manually withdrawn and during this time the radiation is administered in a manner appropriate for the vein being treating in regards to power or energy level. To maintain a constant proper energy density, the speed of withdrawal is measured and sent to a controlling mechanism. The controlling mechanism modifies the power emitted, pulse length or pulse rate to ensure that the vein or tissue receives a consistent dose of energy during manual withdrawal.

Abstract: An electromagnetic energy system adapted to reduce scar formation associated with a skin wound includes a memory, an electromagnetic energy source, an optical energy conduit, a handpiece, and a controller. The memory includes predetermined beam parameter information. The electromagnetic energy source is adapted to generate an electromagnetic energy beam having at least one beam parameter corresponding to the predetermined beam parameter information. The electromagnetic energy beam having the at least one beam parameter is adapted to reduce scar formation associated with a skin wound. The optical energy conduit has a proximal and a distal end, and is coupled to the electromagnetic energy source at the proximal end. The handpiece is coupled to the distal end of the optical energy conduit. The controller is adapted to activate the electromagnetic energy source to deliver to a treatment area near the skin wound.

Abstract: A shaver is disclosed that comprises a handle (12) and a cutting head (13) that are arranged to move relative to each other via a rotational and/or translational axis (16,17). This movement facilitates skin contour following during shaving to achieve a close cut. The handle (12) comprises a laser source that emits a laser beam and the shaver has an optical system that includes optical elements (23,25,26,37,40,42) to direct a part of a laser beam so that it coincides with the rotational axis and/or is parallel to the translational axis. In this way, when the cutting head (13) is moved the optical alignment between the laser source, optical elements (23,25,26,37,40,42) and cutting zone (28) does not change.

Abstract: The invention provides a hair treatment device (40) comprising a detector (10) for detecting a hair (22) near a skin surface (21). The detector (10) comprises a light source (11) for generating a light beam (31) with an initial polarization direction, a polarization modulator (32) for time-dependent modulation of the polarization direction of the light beam (31) between at least a first polarization direction and a second polarization direction, optical elements (14, 16, 17, 18) for focusing the light beam (31) at the hair (22) near the skin surface (21), and a polarization-sensitive light-based detection unit (13) for detecting light interacted with the hair (22) or the skin surface (21) and for discerning when the interacted light has a polarization-direction component different from the initial polarization direction.

Abstract: 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.

Abstract: A dermatologic treatment device having a first light source emitting a first pulse of optical radiation beneficial to a dermatologic treatment, and a second light source emitting a second pulse of optical radiation and being optically coupled to the first light source. The second pulse enhances the brightness of at least part of the optical radiation in the first pulse upon impinging on the first light source. The dermatologic treatment device further includes a timing circuit adapted to energize the first and second light sources to at least partially overlap emission of the first and second pulses.

Abstract: Various endoscopes are integrated with an applicator configured for delivering a therapeutic solution to an internal anatomic target that may be infected by pathogenic microorganisms and a UV light-emitting device transmitting UV light thereto.

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: Switching power supplies made in accordance with the disclosed technology drive flash lamps of dermatologic treatment devices to emit a sequence of relatively small light pulses that are aligned with particular locations within the waveform of the AC line source. Such power supplies not only enable sufficient light energy in aggregate to therapeutically heat target chromophores in a skin region without causing undesired damage to surrounding tissue, but also provide the added benefit that the corresponding electrical energy need not be substantially drawn from any charged capacitor. The disclosed power supply further compensates for performance degradation of the flash lamps during their usable life, by modifying its operation based on predetermined values that are indicative of flash lamp aging/efficiency characteristics. The flash lamps and their associated stored values are preferably incorporated into a replaceable cartridge that facilitates user maintenance of the dermatologic treatment device.

Abstract: A system and method of estimating a distance between the distal end of an optical fiber and treated tissue, to improve treatment efficiency, is provided herein. The estimation is achieved by modulating the numerical aperture of a light beam transmitted through the fiber to receive reflections from the tissue and distinguish them from other reflections in the fiber, and further by calculating the distance by comparing reflection intensities of beams having different numerical aperture values that illuminate the tissue over a very short period, so that tissue and environment conditions do not change much. Distance estimation may be carried out by modulating the treatment beam itself, or by a light beam transmitted between pulses of a pulsed treatment beam.

Abstract: Disclosed is a system and method for treatment of skin disorders. More particularly, the disclosed invention is directed toward the use of multiple light sources for treating skin with or without the use of a topical compositions or photomodulation enhancing agents. Dual light emitting diodes may, for example, be used at relatively low power (less than about 10 J/cm2) to photomodulate skin or living tissue to reduce wrinkles, fine lines, acne, acne bacteria, and other skin disorders.

Abstract: A skin treatment apparatus that includes, a disposable electrode carrier with a plurality of voltage-applying dome-shaped elements protruding from the surface of the electrode carrier. Further, the protruding elements are spaced apart in a pattern. The apparatus operates to apply a voltage to at least some of the protruding elements. The apparatus applies a voltage to the protruding elements with a magnitude that is sufficient to result in an electrical break down of the skin and thereby cause electric current enabling the desired treatment.

Abstract: A device for providing radiation-based dermatological treatments includes a device body configured to be handheld by a user; a VCSEL laser supported in the device body, the VCSEL laser including multiple spaced-apart VCSEL beam sources configured to generate multiple discrete laser beams for generating multiple discrete treatment spots on the skin; an application end configured to be manually moved across the surface of the skin during a treatment session; and electronics configured to control the multiple VCSEL beam sources to emit the multiple discrete laser beams toward the skin to provide a dermatological treatment.

Abstract: The present invention relates to a system for treatment of skin wounds, comprising an energy source for activation of a biochemical healing effect, and at least one dressing intended to be placed on the wound before the step of activation by said energy source, characterized in that said dressing comprises an identification means interacting in a contactless manner with a sensor that triggers the function of the energy source only when the distance between the sensor and said identification means is below a threshold value.

Abstract: Disclosed herein are medical systems involving the novel use of lasers in a way to transfer a desired amount of energy to deeper tissues, such as deep dermis, fat, deep vessels, fascia, tumors and others, without burning the skin, in particular the skin surface. A medical system (10) comprises a laser beam delivery system (21) producing a plurality of laser beams (1a-1d) for simultaneously or alternately irradiating the deep tissue target structure (5) from multiple directions via the skin surface (2), wherein the laser beams (1a-1d) individually are individually adjusted to have an energy level insufficient to ablate and/or burn the skin (2). The target structure (5) comprises a deep tissue target structure (5). The laser beams (1a-1d) have a combined energy level at their point of intersection to achieve a preselected thermal gradient sufficient to treat the deep tissue target structure (5). The medical system (10) further comprises a cooling device for cooling the skin surface (2) during irradiation.

Abstract: The invention relates to medicine and can be used in surgery, including cosmetic surgery, for example, for treating trophic and slowly healing ulcers, bed sores, burns, scars, etc., as well as for biological tissue rejuvenation, including skin, in different locations. The proposed method is for the regeneration of biological tissues with restoration of functional properties, characteristics and structure thereof, in which tissues are subjected to a predetermined degree of mechanically-induced trauma through the creation, in the desired areas, of at least one region of interference between acoustic waves generated by at least two sources and propagating in the tissues to be regenerated, with the possibility of subsequent natural regeneration of the corresponding biological tissues in said areas. Also proposed are various embodiments of the device for the implementation of the above method.

Abstract: A cutting element for a cutting head for a device for cutting hair is disclosed. A laser beam is directed across a cutting zone, in the cutting head, substantially parallel to a user's skin. The laser beam has an effective cutting region in which the laser beam is of a sufficient intensity to cut hair entering said region. The cutting element has a guard adjacent to the cutting zone to contact a user's skin and space the laser beam there from. The guard has a non-planar shape in a direction extending across the cutting zone so that it substantially follows the contours of an edge of the effective cutting region of the laser beam to reduce any variation in the distance between the edge of the effective cutting region and the user's skin across the length of the cutting zone.

Abstract: Embodiments of dermalogical cell treatment are described generally herein. Other embodiments may be described and claimed.

Abstract: A laser device for treating skin is provided which includes a handholdable housing; a laser member arranged within the housing emitting an output beam; a capacitance sensor arranged at the first end of the housing which includes a plate surrounding and defining a window through which the output beam exits, the plate having at least three segments with each flexibly movable in and out of a common plane, each of the segments being connected to an electrode, the electrodes operating to determine dielectric constants of a skin surface; a signal and control storage device communicating with the sensor comparing input signals of measured dielectric constant values to a stored standard dielectric constant value, and wherein emission of the output beam is activated to fire only when all of the at least three segments align in a plane and sense the stored standard dielectric constant value.

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 device for providing laser-based dermatological treatments may include a device body having an application end, a VCSEL laser supported in the device body and including multiple emitter zones, each emitter zone comprising one or more micro-emitters, each micro-emitter configured to emit a micro-beam, wherein at least two of the multiple emitter zones are configured such that the micro-beam emitted by the micro-emitters of the at least two emitter zones form a combined beam through the application end of the device to provide a treatment spot on the skin, and electronics coupled to the at least two emitter zones and configured to control the at least two emitter zones independently.

Abstract: A light based skin treatment device (10, 20) is provided, comprising a light source (18) for providing an incident light beam (21) for treating a skin (30) by laser induced optical breakdown (LIOB) of hair or skin tissue, a transparent exit window (14) for allowing the incident light beam (21) to exit the device (10, 20), and an optical system for focusing the incident light beam (21) into a focal spot (221, 222) in the hair or skin tissue outside the skin treatment device (10, 20).

Abstract: The invention relates to the field of cosmetology. The invention relates to cosmetic or aesthetic skin treatment using an appliance, in particular for dermatological care, which combines applying pulsed electrical currents to the skin for treating the skin by electroporation in a first step, constant currents for electrophoretically treating the skin in a second step, with the simultaneous exposure of the skin under treatment to chromotherapeutic light emissions in which the color changes from one step to the next. The color red is preferred for electroporation; orange is preferred during the electrophoretic treatment. The appliance is programmed for automatic is programmed for automatic operation. The method advantageously comprises a third chromotheraphy step under blue light combined with the application of an electrophoretic current.

Abstract: Methods and apparatus for damaging hair follicles using a series of rapidly-delivered low-fluence pulses of coherent or incoherent light are disclosed herein. In some embodiments, the pulses of coherent or incoherent light have a wavelength or wavelengths primarily in the range between 750 nm and 1500 nm. In some embodiments, applied electromagnetic radiation comprising the rapidly-delivered low-fluence pulses is effective for concomitantly heating both the sub-dermal layer (i.e. the dermis) of the tissue and the hair follicles. In some embodiments, the thermal damaging of the hair follicles is useful for facilitating hair-removal.

Abstract: A device (10) for energy-based skin treatment is provided. The device (10) comprises a light source (18) for providing polarized incident light (21) having an incident polarization, optical elements (11, 12, 13) for focusing the polarized incident light (21) in a focal point (22) within a collagen layer of the skin (30), a polarization-sensitive detection unit (41, 42) for selectively detecting a selected polarization component of light of a generated harmonic (23) of the polarized incident light (21) returning from the skin (30), and a processor, at least being coupled to the polarization-sensitive detection unit (41, 42), for determining a depth of the focal point (22) within the collagen layer based on the detected selected polarization component.

Abstract: A microdermabrasion system offers a combination of other skin therapies in conjunction with microdermabrasion. In an implementation, the system applies light therapy, photodynamic therapy, radio frequency and microwave energy therapy, massage therapy, or combinations of these while exfoliating the skin.

Abstract: A handpiece can treat biological tissue using electromagnetic radiation, which can be substantially fluorescent light. The handpiece includes a source of electromagnetic radiation and a waveguide. The waveguide is adjacent the source, receives electromagnetic radiation from the source, and delivers the electromagnetic radiation to the biological tissue. The handpiece also includes a system for circulating a fluorescent substance through the waveguide. The fluorescent substance is capable of modulating at least one property of the electromagnetic radiation.

Abstract: There is provided an image-based system for cosmetic procedures for skin including an applicator including a light energy emitter, a camera operative to capture and communicate to a computer an image of a segment of skin or blemish obtained of the applicator being in contact with the skin and wherein the computer employs information extracted from the image to determine specific optimal treatment doses of at least one of light energy and RF energy for one or more skin fractions within the segment of skin. The system could also include a remote image capturing and processing device with at least one camera.

Abstract: Methods for imaging or optical sensing of a material are provided. A first fluorescent image or optical signal of a material can be recorded, the material can be perturbed, and then a second fluorescent image or optical signal of the material can be recorded. The two fluorescent images or signals can be subtracted to give a differential image or optical signal.

Abstract: A combination therapy pad that includes a first layer and a second layer operatively coupled to the first layer. A fiber-optic array is disposed between the first layer and the second layer. A third layer is operatively coupled to the first layer. The third layer includes a vacuum tube in fluid communication with a vacuum source and a therapeutic fluid tube in fluid communication with a therapeutic fluid source. The third layer provides at least one of vacuum therapy and therapeutic fluid treatment to a wound area.

Abstract: An improvement in a light therapy device including multiple light-emitting diodes (LEDs) positioned in a handheld portable device is disclosed. Where the housing and the LEDs are configured to have direct contact with the skin or tissue of the user without any intermediary materials, and light the surface and underlying layers of tissue for photodynamic stimulation of the cells. Two iterations of the device utilize light known to have a bactericidal effect in the case or acne or Rosacea. The devices are fabricated from an injection molded plastic housing. The housing contains an arrangement of 36-72 LEDs on a circuit board in an arrangement to provide even lighting over the skin or tissue surface.

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: A laser skin treatment process and system. The system includes features for producing a first laser beam of long pulse duration and a second laser beam of short pulse duration and a skin cooler for cooling the surface of a region of skin. The system is designed to utilize the first laser beam for heating a volume of skin tissue below the cooled surface region to a temperature to produce skin tissue modification but below skin tissue damage threshold. This volume of skin tissue is called a “thermal cavity”. The second laser beam is divided into a plurality of separate laser beams that are directed through separate optical fibers and via separate paths through skin tissue to a single tiny volume of skin tissue within the thermal cavity to produce in that tiny volume mechanical damage. This tiny volume is called an energy droplet. Thus tiny regions of tissue are damaged while minimizing or preventing any significant damage to adjacent tissue.

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.