An ophthalmic stimulator for temporarily constricting a pupil of an eye comprises an irradiation control system, having a feedback system, to generate an irradiation control signal using a feedback of the feedback system, an irradiation source, coupled to the irradiation control system, to generate an irradiation; and an irradiation delivery system, having a targeting system and coupled to the irradiation control system, to receive the irradiation from the irradiation source, and to direct a patterned irradiation in a pattern to a treatment region of an iris of the eye using the targeting system; wherein the irradiation control system controls at least one of the irradiation source and the irradiation delivery system with the irradiation control signal so that the patterned irradiation causes a temporary constriction of the pupil, without causing a permanent constriction of the pupil.

Methods, devices, and systems for determining an orientation of a surgical tool during ophthalmic surgery are disclosed. An example method includes performing an optical imaging scan in the surgical site, using a scan pattern that intersects the surgical tool and generating a scan image from the optical imaging scan. The example method further comprises analyzing the scan image to determine a location in the scan image corresponding to where the surgical tool intersected the optical imaging scan, and determining an orientation of the surgical tool, based on the determined location.

The invention is related to iris color changing method that ensures a color change in iris by shedding the layer that contain the cells with melanin pigments in the upper superficial part and stroma of the iris, colored part of the eye, through photo-disruptive effect.

The object of the invention is a laser device for eye surgery used by ophthalmologists in the treatment with capsulotomy and iriditomy, and a device for selective laser trabeculoplasty. The essence of the ophthalmic laser combined device of the invention lies in that it has one single laser with one optical axis for both wavelengths; the basic wavelength of 1064 nm and the frequency doubled wavelength of 532 nm. Switching between both wavelengths is carried out by a polarization orientation switch. Frequency doubling is inactive at the wavelength of 1064 nm and it is active for the wavelength of 532 nm. At the wavelength of 532 nm additional optical elements for attenuating and collimating the laser pulse are switched on.

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.

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.

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.

In certain embodiments, an ophthalmic surgical system for adjusting a dimension of an eye includes a camera and a computer. The camera generates a surgical image of the eye in contact with a patient interface, which distorts the cornea. The surgical image includes the pupil with a real pupil diameter. The computer accesses a diagnostic image of the eye with the cornea having a natural curvature. The natural curvature affects the real pupil diameter to yield a diagnostic pupil diameter of the diagnostic image that is different from the real pupil diameter of the surgical image. The computer adjusts the real pupil diameter of the surgical image using an eye model to yield a refracted pupil diameter that takes into account the curvature of the cornea and uses the refracted pupil diameter to compensate for the difference between the diagnostic and real pupil diameters.

A method includes, using a laser, thinning a target site in an iris of an eye by irradiating the target site with one or more first radiation-pulses. Subsequently to thinning the target site, a peak intensity of radiation beams emitted by the laser is increased and, subsequently to increasing the peak intensity, a hole is formed through the target site by, using the laser, irradiating the target site with one or more second radiation-pulses.

A method and system of producing a digitally printed iris structure for an artificial eye by using suitable digital graphics software, the appearance of a dilating pupil/collarette is created within the combined center portion/inner ring area of a prosthetic eyein that a pupil appears to dilate from a small diameter in bright light to a comparatively large diameter in dimmer or darker light. The process of creating such effect is a unique extension of the knowledge that certain colors and pigments in bright light are most apparent, and in dark light tend to appear grey to black.