A method and system for deploying an ocular implant into Schlemm's canal of an eye. The method includes the steps of inserting a distal end of a cannula through a cornea of the eye and into an anterior chamber of the eye, the cannula having a distal opening extending from the distal end and through a side wall, a curved distal portion and a curved intermediate portion; placing the distal opening of the cannula into fluid communication with Schlemm's canal; advancing the ocular implant distally through the cannula with a delivery tool engaged with the ocular implant, a proximal portion of the ocular implant engaging the delivery tool proximal to a distal portion of the delivery tool; and disengaging the ocular implant and the delivery tool when the proximal portion of the ocular implant reaches the cannula distal opening.

A capsular tension ring inserter (10) and method includes a cannula (54) adapted to house a capsular tension ring (CTR) (26) having a leading eyelet (32), a hook element (56) disposed within the cannula (54) that engages and moves the CTR (26) during deployment, and a suture (28) placed on the leading eyelet (32) and fed back through the cannula (54) to allow a user to control insertion of the CTR (26) into a capsular bag (42) of an eye (40) by pulling on the suture (28) during insertion of the CTR (26).

Needle injectors and injector carriers for endothelial keratoplasty are provided. Needle injectors include first, second, and third portions each having a respective conduit therein. A first end of the second conduit is fluidly coupled to a second end of the first conduit, where the second conduit has a maximum diameter greater than a maximum diameter of the first conduit. A first end of the third conduit is configured to be fluidly coupled to a second end of the second conduit, where a second end of the third conduit is configured with a cutting surface for cutting and penetrating eye tissue. Injector carriers include a container, a cap configured to seal an opening of the container, and a coupling means configured to couple the needle injector to the cap and allow the needle injector to be disposed within the container.

The aim of the invention is to ensure a secure support and/or a secure transport of a graft (4) or an implant. This is achieved by a device for supporting and transporting a graft (4) or implant, comprising a container (2) which can be filled with a medium (1), preferably a nutrient medium, and a receiving device (3) which can be arranged in the container (2) for the graft (4) or implant. The receiving device (3) has a receiving chamber (5) for the graft (4) or implant and two passages (6, 7) which lead to the receiving chamber (5), at least one of said passages (6, 7) being dimensioned for introducing and/or removing the graft (4) or implant into or out of the receiving chamber (5). The device also comprises a respective closure device (8, 9) for each of the two passages (6, 7), at least one of the closure devices (8, 9) being permeable for the medium (1). The invention further relates to a corresponding receiving device (3) and to a set comprising a corresponding device.

A Light Adjustable Lens (LAL) Tracker comprises an Imaging System, for creating a LAL image by imaging a LAL implanted into an eye; and an Image Recognition System, coupled to the Imaging System, for determining a disk cross-correlator with the LAL image; determining an edge cross-correlator with the LAL image; and determining a LAL position by determining a combined cross-correlator from the disk cross-correlator and the edge cross-correlator. A Tracking-based Illumination Control System comprises the LAL Tracker for tracking a LAL implanted in an eye, including an Imaging System, and an Image Recognition System; and an Illumination Controller, coupled to the LAL Tracker, configured for determining a LAL misalignment factor, corresponding to a LAL misalignment that characterizes a misalignment of the LAL position with a LAL illumination pattern, and generating an illumination control signal in relation to the determined LAL misalignment factor.

Canisters are provided that include a cylindrical body and a cap welded to the body to define a cavity filled with carbon dioxide or other fluid. The canisters may be loaded into a medical device, e.g., to provide an energy source for operating the device. Methods for making such canisters are also provided.

Disclosed is an intrastromal insert, already preformed, of solid, transparent, impermeable, biocompatible, physiologically inert and chemically resistant material, with notches allowing the passage of metabolites, substances, cells or portions thereof, and drugs, configured to receive printing, which is adapted in the space of the corneal stroma to change the eye color and/or to solve the problem of insufficient pigmentation of the iris. The method and the related component to change, permanently and reversibly, the eye color for aesthetic purposes are described as well.

A method of corneal implantation with cross-linking is disclosed herein. In one or more embodiments, the method includes the steps of: (i) cutting a circular implant from a donor cornea; (ii) cutting the circular implant into a plurality of constituent pieces; (iii) forming a small incision in a recipient cornea of an eye of a patient; (iv) forming a pocket in the recipient cornea of the eye of the patient, the pocket being accessible through the small incision in the recipient cornea, and the pocket being bounded entirely by stromal tissue of the cornea; and (v) inserting each of the plurality of constituent pieces of the implant into the pocket of the recipient cornea via the small incision, wherein the implant is cross-linked so as to prevent an immune response to the implant and/or rejection of the implant by the patient.

An embodiment in accordance with the present invention provides a device and method for performing Descemet's membrane endothelial keratoplasty (DMEK). The device includes a tray for loading a corneal graft, a permeable cap, and a handle for facilitating delivery of the corneal graft into the eye of the recipient. The tray is configured such that the corneal graft is tri-folded on the tray or folded on the donor cornea. The permeable cap allows for hydration and protection of the graft during transit. When it is time to deliver the corneal graft into the eye of the recipient, the tray can be loaded onto the handle after the caps are be removed. A method according to the present invention includes a corneal graft being loaded onto the tray, covered with the permeable cap, and transmitted to the facility doing the corneal transplant.

Described here are systems, devices, and methods for delivering an implant to the orbit. In some instances, the systems may comprise a delivery device having a tongue member and a handle. The delivery device may further include an ejector configured to deliver an implant from the tongue member. The delivery device may also include a piercing member configured to create an opening in tissue. The systems may further comprise a piercing member for creating an opening in tissue. In some instances, the piercing member may have a first blade member rotatably connected to a second blade member.