Abstract: An ultrasound therapy system and method is provided that provides directional, focused ultrasound to localized regions of tissue within body joints, such as spinal joints. An ultrasound emitter or transducer is delivered to a location within the body associated with the joint and heats the target region of tissue associated with the joint from the location. Such locations for ultrasound transducer placement may include for example in or around the intervertebral discs, or the bony structures such as vertebral bodies or posterior vertebral elements such as facet joints. Various modes of operation provide for selective, controlled heating at different temperature ranges to provide different intended results in the target tissue, which ranges are significantly affected by pre-stressed tissues such as in-vivo intervertebral discs. In particular, treatments above 70 degrees C., and in particular 75 degrees C.

Abstract: A treatment device is disclosed for treatment of a living body lumen. The treatment device can include an optical fiber having an emitting part that emits laser light from a side circumferential surface. Two or more grooves are provided in the emitting part at places different in a longitudinal direction of the emitting part. The two or more grooves have two or more kinds of shapes and intensities of the laser light emitted from the grooves adjacent to each other are different. A maximum region of intensity of the laser light emitted from the emitting part is located on one end side relative to a center position in the longitudinal direction of the emitting part. The intensity of the laser light emitted from the emitting part on the other end side of the emitting part relative to a position of the maximum region decreases toward the other end side.

Abstract: The invention provides a method and apparatus for stimulating cellulite reduction using a femtosecond diode laser irradiation system. The system comprises a femtosecond diode laser capable of generating laser light that has a wavelength of 1000 nm-10,000 nm, a power level of 300 mw-5 W, and a pulse duration of less than 1 picosecond. A light-emitting device is coupled to the diode laser by means of flexible waveguide and is held over the skin. The device may be a handheld wand or an area pad comprising a plurality of light-emitting lenses on a surface of the pad. Laser setting controls are set to achieve a depth of photon absorption into the skin to reach subcutaneous adipose tissue.

Abstract: 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.

Abstract: The invention relates to systems and methods for accessing tissue layers of the anterior chamber angle of an eye, targeting one or multiple treatment zones within the anterior angle area of the eye and delivering focused photodisruptive laser pulses with pulse durations <50 picoseconds creating channels into various anatomical structures within the anterior angle of the eye.

Abstract: The present disclosure concerns a lighting device (100) and a method of masking an edge transition (15e). An edge structure (15) provides the light with a first edge transition (L1) along a circumference (15e) of the edge structure (15). A patterned layer (11) is provided between the edge structure (15) and the front side (31) of the device. The patterned layer (11) comprises a gradient edge pattern (11g) configured to provide the transmitted light with a second edge transition (L2). The gradient edge pattern (11g) is configured with respect to the circumference (15e) of the edge structure (15) to smoothen the first edge transition (L1). A diffuser (10) is disposed between the front side (31) and the patterned layer (11) for scattering the light of the second edge transition (L2) to smoothen the second edge transition (L2) of the gradient edge pattern (11g).

Abstract: The present invention relates to a photo-activated modulation of smooth muscle (PAMS) technology-based skin adhesive-type low level light irradiator system using a mobile communication device. The present invention can monitor and control the charging state of a battery embedded in a skin adhesive-type low level light irradiator, which is adhered to a specific skin area of a human body using medical double-sided tape and emits and radiates visible light for a given time period, thereby inducing a bioactive substance, such as nitric oxide, to be secreted from an internal organ or tissue of the human body which is connected to the light irradiated skin area by a peripheral nerve, in real time and wirelessly using a mobile communication device.

Abstract: The present invention relates generally to surgical lasers and more specifically to a laser beam control and delivery system that accurately and efficiently directs a laser beam into an optical fiber. The laser beam control and delivery system also provides additional functions, including a connection for a fiber tip temperature control system and a tissue temperature sensing system. The present invention also relates to a surgical laser system that has a high efficiency thermoelectric cooling system.

Abstract: There is provided a therapeutic apparatus for photodynamic therapy that includes a hollow tube inserted into a living body; an unfolding part that is coupled to one end of the tube and is unfolded; a light irradiation part that is disposed in the unfolding part to irradiate light; and an operating part that is coupled to the other end of the tube to unfold the unfolding part, wherein the light irradiation part irradiates light when the unfolding part is unfolded. The therapeutic apparatus for photodynamic therapy according to the present disclosure allows irradiation of light by unfolding tissues of the curved portion in the living body, using an unfolding part capable of being unfolded depending on the user's selection and the light irradiation part coupled to the unfolding part, there is an effect of allowing the use of the photodynamic therapy even in a portion that cannot be conventionally treated using the photodynamic therapy.

Abstract: A method of managing a system of minimally invasive surgery. The management method includes providing a practitioner with a minimally invasive surgery system including a controller. One or more use parameters is stored to memory associated with the controller. In addition, an electrosurgical probe having its own memory is provided to mate with the remaining elements of the system. Complementary use parameters are stored in the memory of the probe. The management method also includes communicating and comparing the use parameters of the controller with the complementary use parameters of the probe and managing the use of the electrosurgical probe according to the use parameters.

Abstract: A method of imaging an object includes obtaining an image data set from a raster scan. The image data set has a plurality of data points, each data point having an associated location and intensity; generating a reduced data set by selectively removing one or more data points from the image data set based upon an assigned probability of retaining the one or more data points in the data set, the assigned probability being a function of the intensity of a data point; generating a triangulation graph as a planar subdivision having faces that are triangles, the vertices of which are the data points and the edges of which are adjacent vertices; and segmenting the triangulated data set by finding a path with lowest cost between that vertex and every other vertex, wherein the cost is a function of the respective intensity of the vertices.

Abstract: A system and method for inserting an intraocular lens in a patient's eye includes a light source for generating a light beam, a scanner for deflecting the light beam to form an enclosed treatment pattern that includes a registration feature, and a delivery system for delivering the enclosed treatment pattern to target tissue in the patient's eye to form an enclosed incision therein having the registration feature. An intraocular lens is placed within the enclosed incision, wherein the intraocular lens has a registration feature that engages with the registration feature of the enclosed incision. Alternately, the scanner can make a separate registration incision for a post that is connected to the intraocular lens via a strut member.

Abstract: A contact lens, according to the present invention, comprises: a housing having a light-incident part on which a therapeutic beam oscillated from a beam generation part is incident, and a light-emitting part for guiding the therapeutic beam incident from the light-incident part to an eyeball; a first sensing part arranged between the light-incident part and the light-emitting part so as to sense the reaction occurring in a healing site of the eyeball on which the therapeutic beam is irradiated; and a second sensing part arranged in a region of the light-emitting part spaced from the first sensing part so as to sense whether contact has been made with the eyeball.

Abstract: A fiber optic probe that eliminates extreme tip temperatures by radiating laser energy in a radial, 360° pattern from the surface of an exposed fiber optic tip is disclosed. In an embodiment, a fiber optic core is configured to operatively engage with a source of laser energy at a proximal end of the fiber optic tip, and, at a distal end of the fiber optic tip, includes a plurality of refracting surfaces configured to disperse laser energy in a radial pattern. In one embodiment, the refracting surfaces may be arranged as a plurality of annular prisms defined around the fiber core. In another embodiment, the refracting surfaces may be arranged as a plurality of concave lenses defined in the fiber optic tip. The temperature distribution of the disclosed probes is controlled and uniform, and may be tailored to radiate laser energy in any desired pattern which may be suitable to achieve an intended objective.

Abstract: A method and device for skin treatment include using a laser diode bar stack to generate a mix of at least two laser wavelengths for application to a skin area to be treated.

Abstract: The invention provides a treatment device (100) for fractional laser-based treatment. The treatment device comprises a treatment generator (80) comprising a treatment laser (20) and a laser scanning system (30). The laser scanning system comprises at least one movable deflection element and is configured and arranged for scanning laser light across an emission window (70) towards skin tissue (110) from a plurality of locations (74) in the emission window by moving the at least one deflection element relative to the emission window, whereby, in use, laser-based lesions (120) are generated inside the skin tissue. The treatment device also comprises a controller (60) for generating a predefined disposition of lesions (120) in the skin tissue by emitting laser light via selected ones of the plurality of locations in the emission window while the treatment device is moved relative to the skin surface (105).

Abstract: A powered surgical apparatus for engaging tissue includes a housing assembly and a movable portion operatively connected to the housing assembly. The movable portion is movable with respect to the housing assembly. In addition, the surgical apparatus includes a power source configured to supply electrical power, and a transmission system configured to transfer at least one of a signal and electrical power between the handle assembly and the movable portion, the transmission system including a first electronic board disposed in the handle assembly and a second electronic board positioned in the movable portion, the second electronic board including a primary control circuit and a secondary control circuit wherein the movable portion is configured and adapted to rotate about a longitudinal axis defined by the powered surgical apparatus.

Abstract: The invention provides a non-invasive device comprising an optical system having a laser light source for generating a light beam, being configured such that, in use, the light beam exits the device and impinges on an outer surface of the skin to be treated; the optical system being configured to focus, in use, the light beam at a position of a treatment location inside the skin, whereby Laser Induced Optical Breakdown is induced at the position of the treatment location; an opening disposed such that, in use, light returning from the skin enters the device as a measurement light beam; and a first and second intensity detection channel configured and arranged to detect the intensity in, respectively, a first and a second bandwidth range of the measurement light beam, wherein the first and the second bandwidth ranges both comprise a wavelength of light produced in the skin as a result of Laser Induced Optical Breakdown, and the first bandwidth range comprises the Second Harmonic Generation wavelength of the la

Abstract: A new and novel method for determining post procedural treatment is disclosed herein. In one embodiment, the method includes the steps of: determining a depth at which a surgical procedure on at least one eye of a patient is to be performed or was performed; providing a first set of instructions for administering a first medication for a first length of time to said at least one eye of said patient, said first length of time based at least in part upon said depth; providing a second set of instructions for administering a second different pressure lowering medication for a second length of time to said at least one eye of said patient, and physically administering the first medication and second different pressure lowering medication based upon the instructions.

Abstract: Embodiments of the present disclosure are directed to a phototherapy eye device. In an example, the phototherapy eye device includes a number of radioluminescent light sources and an anchor. Each radioluminescent light source includes an interior chamber coated with phosphor material, such as zinc sulfide, and containing a radioisotope material, such as gaseous tritium. The volume, shape, phosphor material, and radioisotope material are selected for emission of light at a particular wavelength and delivering a particular irradiance on the retina (when implanted in an eyeball). The wavelength is in the range of 400 to 600 nm and the irradiance is substantially 109 to 1011 photons per second per cm2.