Patent application number | Description | Published |
20120203075 | White coherent laser light launched into nano fibers for surgical illumination - Disclosed is an exemplary surgical illumination system that includes a first laser configured to emit a first light beam having a first spectral range, and an illumination probe optically connectable to the first laser. The first laser may be configured as a supercontinuum laser. The surgical illumination system may include a second laser configured to emit a second light beam having a second spectral range, and a beam combiner for combing the first and second laser beams to form a third laser beam having a spectral range of the first and second lasers. The illumination probe includes a fiber optic cable for delivering at least a portion of the first light beam to a surgical site. The fiber optic cable includes a fiber optic core having a diameter of 100 microns or less. | 08-09-2012 |
20120259321 | Systems and methods to deliver photodisruptive laser pulses into tissue layers of the anterior angle of the eye - The invention relates to systems and methods for measuring the angular accessibility limitations of the anterior angle of the eye, targeting one or multiple treatment zones within the anterior angle area of the eye and delivering highly focused photodisruptive laser pulses with pulse durations <50 picoseconds creating channels into various anatomical structures within the anterior angle of the eye. The invention further includes custom gonioscopy lens systems, patient interface systems and a laser delivery system to deliver highly focused laser beams to the anterior angle area of the eye. | 10-11-2012 |
20120316544 | LASER DELIVERY SYSTEM FOR EYE SURGERY - A photodisruptive laser delivery system and method for use in eye surgery. The photo disruptive laser delivered in pulses in the range of <10000 femtoseconds, used to create incisions in eye tissue is delivered by novel means to minimize optical aberrations without the use of a complex system of multiply precisely arranged lenses. This novel means include a scanning design that allows the focusing lens to always remain under normal incidence to the photodisruptive laser beam, negating the need for overly complex aberration correction set up. The focusing lens is configured to move within a surrounding beam to facilitate two dimensional controls over the treatment space. Controlling beam divergence prior to focusing allows for 3D incisions. The system and methods of use accomplish precise treatment without the need to contact the patient and can be integrated into standard surgical microscopes to improve operational efficiency and hospital workflow. | 12-13-2012 |
20130253406 | METHODS FOR DEPLOYING INTRAOCULAR SHUNTS - The present invention generally relates to methods for deploying intraocular shunts without the use of an optical apparatus that contacts an eye, such as a goniolens. In certain embodiments, methods of the invention involve inserting into an eye a deployment device configured to hold an intraocular shunt, determining that a distal portion of the device is properly positioned within the eye without use of an optical apparatus that contacts the eye, and deploying the shunt from the device. | 09-26-2013 |
20140066723 | White coherent laser light launched into nano fibers for surgical illumination - Disclosed is an exemplary surgical illumination system that includes a first laser configured to emit a first light beam having a first spectral range, and an illumination probe optically connectable to the first laser. The first laser may be configured as a supercontinuum laser. The surgical illumination system may include a second laser configured to emit a second light beam having a second spectral range, and a beam combiner for combing the first and second laser beams to form a third laser beam having a spectral range of the first and second lasers. The illumination probe includes a fiber optic cable for delivering at least a portion of the first light beam to a surgical site. The fiber optic cable includes a fiber optic core having a diameter of 100 microns or less. | 03-06-2014 |
20140180189 | INTRAOCULAR SHUNT PLACEMENT - Methods are provided for using an intraocular shunt deployment device to deploy an intraocular shunt from the device and into an eye. | 06-26-2014 |
20140236065 | INTRAOCULAR SHUNT DEPLOYMENT DEVICE - An intraocular shunt deployment device can release an intraocular shunt into an eye using a deployment mechanism that coordinates action between a pusher component, a shaft component, and a housing of the device. The deployment mechanism causes axial movement of the components in response to a rotational input force. | 08-21-2014 |
20140236066 | ADJUSTABLE INTRAOCULAR FLOW REGULATION - Methods and devices for adjusting or configuring the flow rate of an intraocular shunt are provided whereby hypotony can be avoided by increasing the flow rate through the device. In some embodiments, the device is a shunt that can have a first flow that can be modified to a second flow by modifying the shunt, such as by cutting the shunt. Additionally, one or more dissolvable portions can be present to provide an initial flow restriction and subsequent increase in flow over time. | 08-21-2014 |
20140236067 | ADJUSTABLE GLAUCOMA IMPLANT - Methods and devices for adjusting or configuring the flow rate of an intraocular shunt are provided whereby hypotony can be avoided by increasing the flow rate through the device. In some embodiments, the device is a shunt that can have a first flow that can be modified to a second flow by modifying the shunt, such as by cutting the shunt. Additionally, one or more dissolvable portions can be present to provide an initial flow restriction and subsequent increase in flow over time. | 08-21-2014 |
20140243730 | INTRAOCULAR SHUNT IMPLANTATION METHODS AND DEVICES - The present invention generally relates to devices and methods of implanting an intraocular shunt into an eye. In certain aspects, methods of the invention involve creating an opening in the sclera, and positioning a shunt in the anterior chamber of the eye such that the shunt terminates via the opening in the intra-scleral space, thereby facilitating fluid flow through both the opening and the intra-scleral space. | 08-28-2014 |
20140350533 | CONTACTLESS PHOTODISRUPTIVE LASER CATARACT SURGERY - Method, apparatus and systems for laser surgery as part of cataract surgery. The implementation thereof includes: A means to perform incisions in the cornea and inside the eye. In particular Limbal Relaxating Incisions and an anterior or posterior capsulotomy/capsulorhexis using a rapid fire sequence of photodisruptive laser pulses, placed to open the capsule for cataract surgery. The system and methods provides the means to target and direct the laser pulse sequence into the desired region of the eye without the need of a patient interface that is locked to the laser delivery system and holds the eye in a fixed position relative to the delivery system. | 11-27-2014 |
20150045714 | INTRASCLERAL SHUNT PLACEMENT - Glaucoma can be treated by implanting an intraocular shunt into an eye. The eye has an anterior chamber and sclera. A shunt can be placed into the eye to establish fluid communication between the anterior chamber of the eye and a space between layers of the sclera. | 02-12-2015 |
20150057591 | METHODS FOR INTRAOCULAR SHUNT PLACEMENT - Intraocular pressure can be reduced by insertion of an intraocular shunt in the eye such that it forms a drainage pathway between the anterior chamber and a region of lower pressure. A hollow shaft can be advanced through the anterior chamber with the hollow shaft (a) having a beveled tip at a distal end of the hollow shaft and (b) holding an intraocular shunt with a proximal end of the shunt within the hollow shaft. The sclera can be penetrated with the hollow shaft. A beveled surface of the beveled tip can be oriented such that the beveled surface faces toward the Tenon's capsule when the beveled tip passes out of the sclera. After the beveled tip passes out of the sclera, at least a portion of the shunt can be advanced from the hollow shaft. | 02-26-2015 |