The present invention predicts prior to a laser iris color-change procedure what a patient's iris color will be after the procedure. The present invention does so by identifying and measuring a variety of anatomical features of the patient's eye that affect or are otherwise relevant to predicting the patient's post-operative iris color, translating these measurements into a post-operative iris color prediction, and communicating this prediction to the patient in a manner sufficient to manage the patient's expectations with respect to the aesthetic outcome of the procedure.

Rather than rely solely upon pupillary occlusion or tracking of eye movement to protect the fundus from accidental exposure to electromagnetic radiation, the present invention also utilizes an electromagnetic radiation pathway with a profile such that the energy density at the iris is greater than the energy density at the posterior portion of the eye. This disparity in energy density allows for efficacy at the anterior iris treatment site, without injury to the fundus.

A system for altering the eye color of a patient with a color alteration procedure includes a laser system having a housing around at least one component of the laser system. The laser system also has a perimeter circuit configured to detect a breach of the housing based on the perimeter circuit being broken resulting in an electrical current flowing through the perimeter circuit being ceased or a change in resistance in the perimeter circuit. The system also includes software that detects, by the perimeter circuit, the breach based on the perimeter circuit being broken. The software also executes, based on the breach, an electronic lockout of the laser system such that the laser system cannot be operated without receipt of a command lifting the electronic lockout.

The present invention relates to a device for permanently changing the color of the iris, such as from brown to blue. The invention is a system that includes a slit lamp microscope, a source of intense pulsed light (IPL), optical tracking and measuring systems, and a device that prevents the application of light to the pupil. The IPL provides a simultaneous application of a range of wavelengths, rather than the single wavelength typically applied by lasers. In a preferred embodiment, the IPL is applied as annular ring, striking only the iris and not the pupil or the sclera. Air or liquid cooling can be used to prevent the eye from overheating.

Systems and methods are described for cataract intervention. In one embodiment a system comprises a laser source configured to produce a treatment beam comprising a plurality of laser pulses; an integrated optical system comprising an imaging assembly operatively coupled to a treatment laser delivery assembly such that they share at least one common optical element, the integrated optical system being configured to acquire image information pertinent to one or more targeted tissue structures and direct the treatment beam in a 3-dimensional pattern to cause breakdown in at least one of the targeted tissue structures; and a controller operatively coupled to the laser source and integrated optical system, and configured to adjust the laser beam and treatment pattern based upon the image information, and distinguish two or more anatomical structures of the eye based at least in part upon a robust least squares fit analysis of the image information.

Methods for targeted therapy are disclosed. In certain embodiments, a method includes injecting nanoparticles into a target site in or adjacent to an eye, irradiating the target site with light from a light source, and activating the nanoparticles with the light.

A method for altering an eye color of a patient with a color alteration procedure is disclosed that may include imaging the iris with an image sensor prior to the color alteration procedure to generate an image of the iris. A mapping of the iris may be generated from the image. The mapping may include a number of regions corresponding to varying absorption coefficients of a treatment wavelength in the stromal pigment of the iris. A laser system may be set, based on the mapping, to deliver laser light at a laser power sufficient to cause elimination of at least a portion of stromal pigment in the iris. The laser light may then be delivered with the laser system.

A method for altering an eye color of a patient with a color alteration procedure is disclosed that may include imaging the iris with an image sensor prior to the color alteration procedure to generate an image of the iris. A mapping of the iris may be generated from the image. The mapping may include a number of regions corresponding to varying absorption coefficients of a treatment wavelength in the stromal pigment of the iris. A laser system may be set, based on the mapping, to deliver laser light at a laser power sufficient to cause elimination of at least a portion of stromal pigment in the iris. The laser light may then be delivered with the laser system.

A method for altering an eye color of a patient with a color alteration procedure is disclosed that may include determining a laser power to deliver to stromal pigment in an iris of the eye of the patient by at least retrieving a set of laser criteria for delivery of an exposure less than 100 times a maximum permissible exposure that causes elimination of at least a portion of the stromal pigment. A laser system may be set to deliver laser light at the laser power which is less than the set of laser criteria and the laser light may be delivered with the laser system.

A system for a treatment with laser of pigmented ocular tissues. the system comprising a first subsystem (1) for imaging an pigmented ocular tissue of a person. a second subsystem (2) for planning a laser treatment of the pigmented ocular tissue, and a third subsystem (3) for performing the laser treatment, wherein: the first subsystem (1) comprises image analysis means (15), a camera, an optical coherence tomography apparatus (12) and at least one first head positioner (13, 14); the second subsystem (2) comprises a computer (21); the third subsystem (3) comprises an eye tracker, three or more lasers (111) of respective different wavelengths, an optical assembly (91), control means (115) and a second head positioner (92).