Technologies are described for detection of eye surface vibrations to determine cell damage within a treatment area of an eye undergoing laser treatment. Eye surface vibrations may be caused by intraocular pressure waves that form during the laser treatment. For example, the pressure waves may originate from a plurality of bubbles forming and/or rupturing inside cells located in the treatment area. The bubbles may form as energy from a treatment laser beam is absorbed by the retinal tissue. The pressure waves may be measured at the surface of the eye through Doppler vibrometry to determine if the cells within the treatment area have been damaged. The damage to the cells may include cell lysis, a rupture of cell membranes, scarring, and/or photocoagulation, among other examples.

A system for treating an eye includes a laser light source providing photoactivating light. The system includes a scanning system to receive the photoactivating light as a laser beam and to move the laser beam over a cornea treated with a cross-linking agent. The system includes a controller that provides control signal(s) to programmatically control the laser light source and the scanning system. The control signal(s) cause the laser beam to visit region(s) of the cornea more than once according to a scan pattern and expose the region(s) to the photoactivating light. The photoactivating light causes the cross-linking agent in the exposed region(s) to react with oxygen to generate cross-linking activity in the exposed region(s). The scan pattern causes a predetermined period of time to pass between visits by the laser beam to the exposed region(s), the predetermined period of time allowing oxygen in the exposed region(s) to replenish.

The present invention relates to an ophthalmic treatment apparatus and a control method therefor, and the present invention provides an ophthalmic treatment apparatus comprising: a treatment light generation unit for generating a treatment light which is radiated to a treatment area of an eye tissue; a sensing unit for sensing a signal generated as the state of the tissue changes due to each treatment light radiated to the tissue of the treatment area; and a guide unit for displaying, to a user, information about damage to the tissue caused by each treatment light radiated on the basis of the signal sensed by the sensing unit.

A handheld device for delivering therapeutic light toward an eye of a patient includes a device housing that is configured to be held by a user in delivering the therapeutic light, a plurality of light sources disposed within the device housing, and an array of lenses disposed near the distal end of the device housing. Each light source is configured to independently emit a beam of therapeutic light and each lens of the array is aligned with a respective light source so that each beam of therapeutic light that is emitted from the respective light sources is focused and directed by the respective lenses of the array to target tissue of the eye in order to therapeutically treat to the target tissue.

The present invention relates to an ophthalmic treatment device and a method for operating the same. The present invention provides an ophthalmic treatment device and a method for operating the same, the ophthalmic treatment device comprising: a treatment beam generation unit for generating a treatment beam; a beam delivery unit for forming a path along which the treatment beam generated from the treatment generation unit is delivered to a treatment area positioned on the fundus; a monitoring unit for emitting a detecting beam along the path of delivery of the treatment beam and sensing treatment area state information on the basis of information regarding a change in speckle of the detecting beam, which is scattered and reflected from the treatment area; and a control unit for controlling the driving of the treatment beam generation unit on the basis of the treatment area state information sensed by the monitoring unit.

A patient interface includes an eye interface device, a scanner, a first support assembly, and a beam source. The eye interface device is configured to interface with an eye of a patient. The scanner is configured to be coupled with the eye interface device and operable to scan an electromagnetic radiation beam in at least two dimensions in an eye interfaced with the eye interface device. The scanner and the eye interface device move in conjunction with movement of the eye. The first support assembly supports the scanner so as to accommodate relative movement between the scanner and the first support assembly parallel so as to accommodate movement of the eye. The beam source generates the electromagnetic radiation beam. The electromagnetic radiation beam propagates from the beam source to the scanner along an optical path having an optical path length that varies in response to movement of the eye.

Technologies are described for detection of eye surface vibrations to determine cell damage within a treatment area of an eye undergoing laser treatment. Eye surface vibrations may be caused by intraocular pressure waves that form during the laser treatment. For example, the pressure waves may originate from a plurality of bubbles forming and/or rupturing inside cells located in the treatment area. The bubbles may form as energy from a treatment laser beam is absorbed by the retinal tissue. The pressure waves may be measured at the surface of the eye through Doppler vibrometry to determine if the cells within the treatment area have been damaged. The damage to the cells may include cell lysis, a rupture of cell membranes, scarring, and/or photocoagulation, among other examples.

System and method for making incisions in eye tissue at different depths. The system and method focuses light, possibly in a pattern, at various focal points which are at various depths within the eye tissue. A segmented lens can be used to create multiple focal points simultaneously. Optimal incisions can be achieved by sequentially or simultaneously focusing lights at different depths, creating an expanded column of plasma, and creating a beam with an elongated waist.

A device for altering an optical and/or mechanical property of a lens that is implanted in an eye, the device including a laser device, which has a laser beam source that provides a pulsed laser beam and an optical unit, which impinges on the implanted lens with the pulsed laser beam. The device also includes a control device, which controls the laser device such that the optical and/or mechanical property of the lens is altered on the basis of non-linear interaction between the laser beam and the lens material.

A patient interface includes an eye interface device, a scanner, a first support assembly, and a beam source. The eye interface device is configured to interface with an eye of a patient. The scanner is configured to be coupled with the eye interface device and operable to scan an electromagnetic radiation beam in at least two dimensions in an eye interfaced with the eye interface device. The scanner and the eye interface device move in conjunction with movement of the eye. The first support assembly supports the scanner so as to accommodate relative movement between the scanner and the first support assembly parallel so as to accommodate movement of the eye. The beam source generates the electromagnetic radiation beam. The electromagnetic radiation beam propagates from the beam source to the scanner along an optical path having an optical path length that varies in response to movement of the eye.