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.

A dissection system for corneal transplants includes a housing including a contact side to be positioned against a cornea. The housing includes an interior passageway with an opening at the contact side. The dissection system includes a blade assembly disposed in the interior passageway. The blade assembly includes a first blade and a second blade. The first blade includes a first cutting edge and the second blade includes a second cutting edge. The first blade and the second blade are movable relative to the housing such that the first cutting edge and the second cutting edge extend through the opening of the housing and out of the interior passageway. The first cutting edge produces a first cut in the cornea. The second cutting edge produces a second cut in the cornea. The first cut and the second cut define a volume of tissue for removal from the cornea.

A device for manipulating an implant includes a handle coupled to a guide extending from the handle to a distal end. The device includes an engagement mechanism disposed at the distal end of the guide and configured to engage an implant. The device includes a first actuator disposed on the handle and coupled to the engagement mechanism. The first actuator causes the engagement mechanism to engage the implant. The device includes an air chamber disposed in an interior chamber of the handle and configured to hold air. The device includes a lumen coupled to the air chamber and extending along the guide to the distal end. The lumen includes an air channel extending through the lumen. The device includes a second actuator disposed on the handle. The second actuator causes the air chamber to deliver the air, via the air channel, to the distal end.

A modified, novel surgical technique of Boston Keratoprosthesis (B-KPro) Type II is provided to restore the visual acuity in patients with bilateral end-stage ocular surface disorders, comprising 1) Preparing auricular cartilage; 2) Exposing corneal stroma and sclera surface and removing the corneal epithelium; 3) Assembling the keratoprosthesis device; 4) Implanting the assembled device into recipient cornea; 5) Implanting the autologous cartilage; and 6) Suturing the Tenon's capsule and conjunctiva to the ocular surface layer by layer to cover and reinforce the KPro.

The present application provides a delivery device (10) for percutaneously implanting a medical implant (1) in tissue of a patient. The delivery device comprises a delivery sheath (12, 13, 53, 61, 62, 65, 66) adapted to at least partially surround the medical implant and carry the medical implant for percutaneous delivery in the patient's tissue. The delivery device also includes a power delivery system (37) adapted to provide electric power to the medical implant within the delivery sheath.

A tissue-augmented corneal inlay surgery technique is disclosed herein. In one embodiment, the surgery method includes the steps of: (i) implanting a corneal inlay into a recipient cornea of an eye of a patient; (ii) applying laser energy to a central portion of the corneal inlay and a portion of stromal tissue of the recipient cornea underneath the corneal inlay so as to modify the refractive power of the eye; (iii) applying a cross-linking solution that includes a photosensitizer to the recipient cornea of the eye of the patient; and (iv) irradiating the corneal inlay and surrounding corneal tissue so as to activate cross-linkers in the corneal inlay and the surrounding corneal tissue. In this embodiment, the central portion of the corneal inlay remains clear for the patient without being obstructed by swollen tissue so that the patient is able to see immediately after the corneal inlay surgery.

Medical kits and methods for performing small incision DLEK include a corneal transplantation donor tissue graft formed into an implantable and compact rolled configuration using the flexible substrate.

Assemblies for storing, handling, transporting, viewing, evaluating, and/or shipping corneal tissue are provided. The assembly includes a corneal tissue carrier within a vial, the transport vial removably coupled to a stabilization base, wherein the ease of access to the graft carrier allows administering the corneal tissue sample to a patient in rapid succession so that more surgeries can be performed by a single surgeon in a single day.

An implanting device is used for implanting a membrane in a biological tissue. The implanting device includes a sleeve, a membrane storage element, an injection element and a bubble generating element. The membrane storage element is fixed at the sleeve. The injection element is inserted in the sleeve and the membrane storage element, and includes a capturing end and connecting end. The capturing end is for capturing the membrane and has a hole. The bubble generating element is connected to the connecting end, and is for providing a gas that is then outputted via the hole. By the rotation of the injection element, the capturing end extends straight out of the membrane storage element or retracts straight into the membrane storage element.

An apparatus (200, 200A, 200B, 200C) has central lens body (212, 212A, 212B, 212C) for providing vision correction for a patient. The lens body (212, 212A, 212B, 212C) has an initial index of refraction and is formed from at least one material configured to have a second index of refraction when subjected to a laser and/or radiation.