The present invention provides a probe device comprising an inner cutting probe and an outer cutting probe. wherein the outer cutting probe has a first side cutting and sucking port in communication with a sliding channel thereof, and the inner probe is slidable within the sliding channel of the outer cutting probe and shaped to have a first end blade edge, a second side port with a second side blade edge and a third side blade edge opposite to the second side blade edge in a cross-sectional view thereof. When the inner cutting probe is slidable within the sliding channel of the outer cutting probe in the forward and backward direction of one cutting cycle, three cuttings are achieved in the forward and backward direction of one cutting cycle, thereby improving the cutting efficiency of the operation.

A system for preparation of an implant and ab interno insertion of the implant into an eye including a handle having one or more actuators and an elongated shaft having an outer sheath and an elongate member positioned within a lumen of the tubular outer sheath. The system includes a recess sized for holding a patch of material fixed relative to the handle and a cutting member movable relative to the handle and to the recess. The cutting member cuts the patch of material into an implant as the cutting member moves towards a cutting configuration. The implant, once cut, is axially aligned with the lumen of the tubular outer sheath. The inner elongate member is movable relative to the tubular outer sheath to advance the implant into a deployment position in the lumen of the tubular outer sheath for delivery into the eye. Related devices and methods are provided.

The present invention relates to ophthalmic surgical devices, systems, and methods, in particular to vitrectomy device with a rotating inner tube.

The invention concerns an confocal scanning laser ophthalmoscope for providing retinal therapy of an eye comprising: a first light source configured to emit a treatment beam with a first wavelength to a selected area of the retina, whereby the retina is external to the confocal scanning laser ophthalmoscope; a retinal functional tracking means comprising a second light source and a detector, wherein the second light source is arranged to emit light within a spectrum to the selected area of the retina, and wherein the detector is configured to analyse reflected light by the retina at the selected area, wherein the detector is adapted to determine a change in the spectrum of the reflected light; and wherein the confocal scanning laser ophthalmoscope is configured to adapt a therapeutic dose emitted by the first light source in response to the determination of a change in the spectrum of the reflected light.

The invention also concerns a method for detecting a change in retinal cells of an eye stimulated by a light beam of a first light source.

An accommodating intraocular lens assembly can include a first lens, a first stanchion, a second lens, and a second stanchion. The first lens can have a first anterior side and a first posterior side. The first stanchion can have a first distal end connected to the first lens and a first base end. The second lens can have a second anterior side and a second posterior side. The second stanchion can have a second distal end connected to the second lens and a second base end. The first lens and the second lens can move laterally relative to one another during contraction of the ciliary muscle in a vertically-extending plane containing the optic axis of the eye and substantially centered in the eye.

An ophthalmic surgical laser system includes a laser beam delivery system having multiple moving components for scanning a laser focal spot in a target eye tissue, where the motors that actuate some of the moving components are equipped with respective digital encoders that measure actual motor positions. A controller controls the laser beam delivery system to perform a treatment scan, while recording the actual motor positions from the encoders. Using the actual motor positions and a calibration relationship between actual motor positions and delivered laser focal spot positions in a target tissue, a laser cutting pattern is digitally reconstructed, which represents the incisions actually achieved by the treatment scan. The reconstructed laser cutting pattern may be visually inspected and further analyzed, e.g. to compare it to the intended laser cutting pattern used to execute the treatment scan, to calculate the achieved refractive correction, or to simulate tissue resetting.

An exemplary surgical device includes an element positionable within a shaft having a lumen defined therethrough with the element movable from a stored position to a deployed position in which a larger portion of the element extends out of the distal end of the lumen. The element forming a closed loop which is positioned around the lens while the lens is within a capsular bag. The closed loop is reduced in size to form a cut in the lens.

An ophthalmic surgical instrument includes a housing and a snare operably coupled to the housing. The snare is configured to transition between an insertion configuration and a deployed configuration, in which the snare is sized to encircle lenticular tissue. The ophthalmic surgical instrument is designed to prevent elevation and/or tilting of the lenticular tissue as the snare transitions toward the insertion configuration to divide the lenticular tissue.

Medical devices and methods for removing a predetermined portion of soft tissue from a target tissue layer, thereby creating a channel between two side walls of the target tissue layer, are described. The medical device is a cutting tool comprising: an elongated round body extending along a longitudinal axis and having a uniform outer cross-section at a proximal side thereof; a cutting portion at a distal side of the elongated body, comprising at a distal end thereof a cutting edge of a first cross-section being smaller than said outer cross-section, and a distally and continuously decreasing outer cross-section; and a chamber extending along the longitudinal axis inside the cutting tool from said cutting portion, the chamber having dimensions enabling storing of the removed soft tissue portion inside the chamber thereby providing a validation to the channel creation.

A surgical instrument (1) is provided with a rigid probe (2), and cuts off the trabecular meshwork by inserting this probe (2) into the canal of Schlemm. An inner tube portion having a cutter is equipped inside the probe, and the trabecular meshwork sucked in from a hole portion (22) is cut off by the cutter due to the movement of the inner tube portion. A protection portion (21) is formed on the tip the probe (2) and protects the outer wall of the canal of Schlemm when cutting the trabecular meshwork. According to the invention, an ophthalmic surgical instrument for glaucoma patients is provided, the surgical instrument having excellent operability and preventing cutting of parts that should not be cut off without fail.