A device for superimposing parameters and/or image data in the stereoscopic observation path of ophthalmological devices relates to an apparatus for reflecting relevant parameters and/or image data into the stereoscopic observation beam path of ophthalmic devices, for example for therapeutic laser treatments of an eye. The device includes an additional micro-display, which is connected to the control unit, and a beam deflection element for reflecting the parameters and/or image data shown on the micro-display into the stereoscopic observation beam path, which are for example arranged in the parallel beam path. Even though the apparatus is intended for ophthalmic devices for therapeutic laser treatment in the eye, it can also be used, in principle, for ophthalmic devices for examination, diagnosis and surgical interventions.

Devices and methods for novel retinal irradiance distribution modification (IDM) to improve, stabilize or restore vision are described herein. Also encompassed herein are devices and methods to reduce vision loss from diseases, injuries and disorders that involve damaged and/or dysfunctional and/or sensorily deprived retinal cells. Conditions that may be treated using devices and methods described herein include macular degeneration, diabetic retinopathy and glaucoma. Therapy provided by retinal IDM devices and methods described herein may also be used in combination with other therapies including, but not limited to, pharmacological, retinal laser, gene and stem cell therapies.

The invention provides an excimer laser system including a means for authenticating laser probes to be used with the excimer laser system via radio-frequency identification techniques.

A voice control system for ophthalmologic laser treatment systems sets parameters for delivering laser energy based on voice commands and prevents potentially harmful parameters due to operator mistakes and misunderstood voice commands by providing incremental parameter adjustment and restricting the amount by which the parameters can be adjusted for each executed voice command. Valid voice commands include indications of which parameter to set, a value for the parameter, and whether to increase or decrease the value of the parameter. In one example, parameter values can only be increased or decreased by a certain percentage with respect to the current value. In another example, the parameters are adjusted by selecting the next highest or lowest value with respect to the current parameter value from a predetermined sequence of possible values for particular parameters. Voice control functionality can also be deactivated under certain conditions such as when it is determined that a parameter was not set.

The present invention includes a device for effecting deformation of a sclera of an eye, including an expandable, mesh tube having holes dispersed through an entire surface thereof and with first and second tapered ends, and inserted unexpanded to deform the sclera when expanded. A central portion is intrascleral, with the first and second tapered ends external to the sclera on top of an intact scleral surface to deform during expansion, and simultaneously causes the sclera to be deformed so that the sclera moves towards the inside of the eye while simultaneously causing the sclera to move towards the outside of the eye. The mesh tube includes struts, connecting points of the struts are of different sizes, the first and second tapered ends and the connecting points within the tapered ends are thicker than the connecting points of the mesh tube, and the mesh tube includes fixation tabs.

A device for fusing two or more tissues is disclosed. The device comprises a hand held probe comprising a fluid receiving opening, a channel and an outlet in fluid communication whereby fluid passes through the channel and exits the outlet where it is directed to at least one of the two or more tissues and/or a space in-between. A disruptive emitter, in the form of a laser, is comprised on the probe which emits a force sufficient to fuse the two or more tissues. The device finds particular application to treatment of a detached retina by fusing the retina and the retinal pigmented epithelium. A method of fusing two or more tissues including a retina and underlying retinal pigmented epithelium is also disclosed.

The present invention relates to a conical contact type ophthalmic digital microscope, and more particularly, to a conical contact type ophthalmic digital microscope allowing observation of a magnified eyeball while being placed above a cornea of a patient. The corneal contact type ophthalmic digital microscope according to the present invention includes a housing, an objective lens part installed below the housing and configured to come in contact with a cornea of an eyeball, an image sensor part installed in the housing and configured to capture the eyeball visible through the objective lens part and generate an eyeball image, a position adjuster configured to change a position of the image sensor part, and a control part configured to control operations of the image sensor part and the position adjuster and output the eyeball image through a display provided outside the housing.

The present invention discloses a device suitable for delivery of a fluid composition to an eye, especially therapeutic compositions, comprising: a hollow needle with a bore having a proximal end and a distal end, said distal end configured to pass into a passage in a sclera of an eye, said bore configured to function as a conduit for a fluid from said proximal end to said distal end, and a solid separator having a distal tip, configured to move inside said bore of said hollow needle allowing said distal tip of said separator to protrude from said distal end of said needle.

A process for heat treating biological tissue includes providing a plurality of energy emitters formed into an array. Treatment energy in the form of ultrasound energy is generated from the plurality of emitters and applied to target tissue. The treatment energy has energy and application parameters selected so as to raise the target tissue temperature sufficiently to create a therapeutic effect while maintaining an average temperature of the target tissue over several minutes at or below a predetermined temperature so as not to destroy or permanently damage the target tissue.

A lens/sensor subassembly (318) may include a feedback sensor (324), a data transmission line (302), and an electrical element (328). The feedback sensor (324) may be configured to measure a phenomenon in an eye (100) of a patient during a laser-based ophthalmological therapy. The data transmission line (302) may be configured to communicate feedback data measured by the feedback sensor (324) to a laser-based ophthalmological treatment system (200). The electrical element (328) may be degradable in response to exposure to therapeutic radiation (316). The degradation of the electrical element (328) may interrupt communication of the feedback data measured by the feedback sensor (324) to the laser-based ophthalmological treatment system (200).