Abstract: A system and method of performing therapy on target eye tissue. A light source produces a beam of light, and a scanning device deflects the light beam to produce an pattern of the light beam. An ophthalmic lens assembly includes a mirror for reflecting the light beam pattern onto the target eye tissue. The mirror is rotatable to angularly align the light beam pattern to the target tissue. Control electronics control the scanning device to apply the light beam pattern onto the reflective optical element at first and second angular orientations separated by a predetermined angle RA. The predetermined angle RA is set such that light beam patterns applied to the target tissue at the first and second angular orientations, which are also angularly aligned to the target tissue through rotation of the mirror, automatically are adjacently abutting to each other on the target tissue.

Abstract: Systems and processes for the optimization of laser treatment of an eye are disclosed. The process can include receiving a set of parameters of a laser treatment (e.g., an aerial beam size, contact lens, pulse duration, and the desired clinical grade), determining an estimated size of a lesion to be generated by the laser treatment beam, receiving a lesion pattern density (e.g., full grid, mild grid, or other), and determining a recommended pattern of laser treatment beam spots. The recommended pattern of laser treatment beam spots may include a recommended number of laser treatment spots and a spacing between the spots.

Abstract: Systems and processes are described relating to laser-based ophthalmic intervention technologies and, more specifically, to techniques for delivering reproducible amounts of laser energy to create visible and sub-visible lesions on an eye. The subject technology may provide a user with the ability to adjust the amount of energy to be delivered to the eye tissue by selecting a single numerical value. In response, the system may adjust the power and/or duration of the laser treatment beam pulse according to an operating curve determined by the system.

Abstract: A system and method for treating ophthalmic target tissue, including a light source for generating a beam of light, a beam delivery system that includes a scanner for generating patterns, and a controller for controlling the light source and delivery system to create a dosimetry pattern of the light beam on the ophthalmic target tissue. One or more dosage parameters of the light beam vary within the dosimetry pattern, to create varying exposures on the target tissue. A visualization device observes lesions formed on the ophthalmic target tissue by the dosimetry pattern. The controller selects dosage parameters for the treatment beam based upon the lesions resulting from the dosimetry pattern, either automatically or in response to user input, so that a desired clinical effect is achieved by selecting the character of the lesions as determined by the dosimetry pattern lesions.

Abstract: A system and method for treating ophthalmic target tissue, including a light source for generating a beam of light, a beam delivery system that includes a scanner for generating patterns, and a controller for controlling the light source and delivery system to create a dosimetry pattern of the light beam on the ophthalmic target tissue. One or more dosage parameters of the light beam vary within the dosimetry pattern, to create varying exposures on the target tissue. A visualization device observes lesions formed on the ophthalmic target tissue by the dosimetry pattern. The controller selects dosage parameters for the treatment beam based upon the lesions resulting from the dosimetry pattern, either automatically or in response to user input, so that a desired clinical effect is achieved by selecting the character of the lesions as determined by the dosimetry pattern lesions.

Abstract: A system and method for treating ophthalmic target tissue, including a light source for generating a beam of light, a beam delivery system that includes a scanner for generating patterns, and a controller for controlling the light source and delivery system to create a dosimetry pattern of the light beam on the ophthalmic target tissue. One or more dosage parameters of the light beam vary within the dosimetry pattern, to create varying exposures on the target tissue. A visualization device observes lesions formed on the ophthalmic target tissue by the dosimetry pattern. The controller selects dosage parameters for the treatment beam based upon the lesions resulting from the dosimetry pattern, either automatically or in response to user input, so that a desired clinical effect is achieved by selecting the character of the lesions as determined by the dosimetry pattern lesions.

Abstract: Laser beam positioning systems for material processing and methods for using such systems are disclosed herein. One embodiment of a laser-based material processing system, for example, can include (a) a radiation source configured to produce a laser beam and direct the beam along a beam path, and (b) a laser beam positioning assembly in the beam path. The laser beam positioning assembly can include a first focusing element, first and second reflective optical elements, and a second focusing element. The first focusing element can focus the laser beam to a first focal point between the first and second reflective optical elements. The first and second reflective optical elements can direct the laser beam toward a material processing area while the laser beam has a decreasing or increasing cross-sectional dimension. The second focusing element can focus the laser beam and direct the beam toward the material processing area.

Abstract: Embodiments of recirculating filtration and exhaust systems for material processing systems are disclosed herein. A material processing system configured in accordance with one embodiment includes an enclosure for processing a workpiece, the enclosure having an enclosure inlet and an enclosure outlet. The system also includes a first flow path fluidly coupled to the enclosure inlet and the enclosure outlet, and a first filtration assembly in the first flow path. The first filtration assembly draws airflow from the enclosure and returns the airflow to the enclosure. The system further includes a second flow path in fluid communication with the first flow path upstream from the enclosure inlet, and a second filtration assembly in the second flow path. The second filtration assembly draws airflow from the first flow path and returns airflow to the first flow path.

Abstract: Laser-based material processing systems and methods for using such systems are disclosed herein. In one embodiment, for example, a laser-based material processing system includes a workpiece support, a positioning assembly over at least a portion of the workpiece support, and a laser. The system includes a laser beam director carried by the positioning assembly to direct a beam generated by the laser toward the workpiece support. The system also includes a dispensing unit carried by the positioning assembly to discharge a material toward the workpiece support. The system further includes a controller operably coupled to the positioning assembly, the laser beam director, and the dispensing unit. The controller can be configured to move the laser beam director and the dispensing unit relative to the workpiece support such that (a) the beam is directed toward a first portion of the workpiece support, and (b) the dispensing unit discharges material toward the first portion of the workpiece support.

Abstract: Systems and processes are described relating to laser-based ophthalmic intervention technologies, and, more specifically, to techniques for creating lesions on an eye using a modular system featuring one or more coherent fiber bundles configured to deliver laser energy to the eye from a separate housing wherein a laser source is located. The subject technology may be utilized to not only separate a patient from certain portions of the hardware, but also to facilitate patterned lesion creation using mobile devices such as LIO and laser endoprobe devices.

Abstract: A beam delivery system for treating target tissue that includes an input for receiving a light beam, a variable attenuator for providing variable attenuation of the light beam, a power and wavelength detection assembly, a spot size adjustment assembly, and a controller. The power and wavelength detection assembly measures the power level of the beam, and detects when unwanted wavelengths are present in the light beam. The spot size adjustment assembly selectively feeds the beam through different optical fibers to achieve different spot sizes of the beam. The controller controls the variable attenuator, the power and wavelength detection assembly, and the spot size adjustment assembly to achieve the desired power and wavelength, and beam spot size.

Abstract: Laser-based material processing systems, exhaust systems, and methods for using such systems are disclosed herein. One embodiment of a laser-based material processing system can include an exhaust assembly configured to remove contaminants from a material processing area. The exhaust assembly can include a vacuum source and an exhaust plenum carried by a moveable arm of a gantry-style laser beam positioning assembly. The moveable arm can extend along a first axis and can be moveable along a second axis generally normal to the first axis. The exhaust plenum can extend lengthwise in a direction generally parallel with the first axis. The exhaust assembly can also include an intake slot extending lengthwise along the exhaust plenum across at least a portion of the material processing area. The exhaust assembly can further include one or more flexible exhaust ducts in fluid communication with the vacuum source and the exhaust plenum.

Abstract: Output beam from laser diode bar (1) has divergence around 40 degrees along the fast axis and around 12 degrees along the slow one. The quality of such a beam along the fast axis is good and fast axis collimating lens (FAC) (2) can compensate its high divergence down to 0.5-1 degrees. In the direction of the slow axis the beam from the laser diode bar is focused by cylindrical lens (3) onto the pumping face of laser active medium (5). The pumping face is wider than the pumping spot on it to ensure efficient collection of pumping light. Laser active medium has two parallel faces which form a waveguide for the pumping light. As a result, the pumping light is confined within the waveguide along the slow-axis direction and collimated (near parallel) in the fast-axis direction. Therefore, length of the pump volume (6) can be as long as the laser element itself.

Abstract: Laser conversion systems and methods for converting laser systems for operation in different laser safety classification modes are disclosed herein. In one embodiment, a laser system includes a laser configured to emit radiation greater than about 5 mW and an exterior housing containing the laser. The exterior housing has a section configured to be in a first arrangement in which the laser system is classified as a class I system and a second arrangement in which the laser system is classified as a class IV system. The laser system further includes a conversion module operably coupled to the laser system and the section. The conversion module is configured to enable one or more regulatory features required for class IV operation of the laser system when the section is in the second arrangement and disable the regulatory features required for class IV operation of the laser system when the section is in the first arrangement.

Abstract: A laser includes a laser source and an power source arranged such that both components have substantially the same cross-section, with cooling fins arranged axially along the length of each element. The components are arranged end-to-end in a series to form an assembly with substantially the same cross-section along the entire length of the assembly. A shroud mounted along the assembly forms a single air channel directing air from a fan along the entire length of the assembly, for cooling both the power source and the laser source with the total air flow from the at least one fan. The laser source and the power source are arranged in series such that the laser source is cooled first, and the subsequent air flow, although slightly warmer from cooling the laser source, is sufficient to cool the power source.

Abstract: Laser-based material processing systems, exhaust systems, and methods for using such systems are disclosed herein. One embodiment of a laser-based material processing system can include an exhaust assembly configured to remove contaminants from a material processing area. The exhaust assembly can include a vacuum source and an exhaust plenum carried by a moveable arm of a gantry-style laser beam positioning assembly. The moveable arm can extend along a first axis and can be moveable along a second axis generally normal to the first axis. The exhaust plenum can extend lengthwise in a direction generally parallel with the first axis. The exhaust assembly can also include an intake slot extending lengthwise along the exhaust plenum across at least a portion of the material processing area. The exhaust assembly can further include one or more flexible exhaust ducts in fluid communication with the vacuum source and the exhaust plenum.

Abstract: Laser beam positioning systems for material processing and methods for using such systems are disclosed herein. One embodiment of a laser-based material processing system, for example, can include (a) a radiation source configured to produce a laser beam and direct the beam along a beam path toward a material processing area, and (b) a laser beam positioning assembly in the beam path. The laser beam positioning assembly can include a first focusing element, first and second reflective optical elements (e.g., movable mirrors), and a second focusing element. The first focusing element can focus the laser beam to a first focal point between the first and second reflective optical elements. The first and second reflective optical elements can direct the laser beam toward the material processing area while the laser beam has a decreasing or increasing cross-sectional dimension (e.g., diameter).

Abstract: Gas lasers including nanoscale catalysts and methods for producing such lasers are disclosed herein. In one embodiment, a gas laser includes a gas containment structure having a gas discharge region and a laser gas medium in the gas discharge region. The gas laser also includes a plurality of optical elements spaced apart from each other at opposite ends of the gas discharge region to form a laser resonator. The gas laser further includes a nanoscale catalyst proximate to and in communication with the gas discharge region to modify oxidation and/or decomposition processes of selected components of the laser gas medium. In one embodiment, the nanoscale catalyst can include a metal-oxide support substrate carrying a plurality of nanoscale particulates. The nanoscale particulates can be composed of one or more of the following: gold, silver, or platinum, and have an average size of about 1-50 nm.

Abstract: An air cooled laser includes a laser housing with a laser module and heat sinks therein connected to a high pressure blower structure for causing an airflow to remove heat from the heat sinks and maintain the laser module at a stable operating temperature.

Abstract: Gas lasers including nanoscale catalysts and methods for producing such lasers are disclosed herein. In one embodiment, a gas laser includes a gas containment structure having a gas discharge region and a laser gas medium in the gas discharge region. The gas laser also includes a plurality of optical elements spaced apart from each other at opposite ends of the gas discharge region to form a laser resonator. The gas laser further includes a nanoscale catalyst proximate to and in communication with the gas discharge region to modify oxidation and/or decomposition processes of selected components of the laser gas medium. In one embodiment, the nanoscale catalyst can include a metal-oxide support substrate carrying a plurality of nanoscale particulates. The nanoscale particulates can be composed of one or more of the following: gold, silver, or platinum, and have an average size of about 1-50 nm.