A disposable medical handpiece configured for phaco emulsification surgery includes an ultrasonic drive coupled to a phaco tip for vibrating the phaco tip at an ultrasonic frequency for emulsifying cataract. The phaco tip has an aspiration passage coupled to a cannula disposed within the ultrasonic drive for aspirating the emulsified cataract. The ultrasonic drive and the phaco tip are disposed in a housing having an integrated irrigation tube for irrigating the surgery site with an irrigation liquid. The disposable medical handpiece is configured to allow the ultrasonic drive to be reusable while the cannula and the housing to be disposable. The medical handpiece can include haptic feedback to allow the surgeon to know the status of the handpiece and the characteristics of the cataract. The medical handpiece can include a frequency selector to allow the surgeon to change the ultrasonic frequency based on the characteristics of the cataract.

A technique can consistently achieve thicknesses of ≤50 μm for corneal tissue for Descemet stripping automated endothelial keratoplasty (DSAEK). Grafts with thicknesses of ≤50 μm are also known as nanothin DSAEK (NT-DSAEK) grafts. Evidence shows that using thinner DSAEK grafts, particularly NT-DSAEK grafts, can significantly improve visual outcomes. According to an example embodiment, a method for producing a corneal graft includes drying a donor cornea to cause a pre-cut thickness of the donor cornea to decrease. The method includes, concurrently with drying the donor cornea, determining pre-cut thickness measurements for the donor cornea. The method includes, in response to the pre-cut thickness measurements indicating the pre-cut thickness of the donor cornea has decreased to a predetermined value, cutting the donor cornea to a post-cut thickness of ≤100 μm, or more particularly ≤50 μm, to produce a corneal graft.

A technique can consistently achieve thicknesses of ≤50 μm for corneal tissue for Descemet stripping automated endothelial keratoplasty (DSAEK). Grafts with thicknesses of ≤50 μm are also known as nanothin DSAEK (NT-DSAEK) grafts. Evidence shows that using thinner DSAEK grafts, particularly NT-DSAEK grafts, can significantly improve visual outcomes. According to an example embodiment, a method for producing a corneal graft includes drying a donor cornea to cause a pre-cut thickness of the donor cornea to decrease. The method includes, concurrently with drying the donor cornea, determining pre-cut thickness measurements for the donor cornea. The method includes, in response to the pre-cut thickness measurements indicating the pre-cut thickness of the donor cornea has decreased to a predetermined value, cutting the donor cornea to a post-cut thickness of ≤100 μm, or more particularly ≤50 μm, to produce a corneal graft.

A method and system for controlling an ultrasonically driven handpiece employable in an ocular surgical procedure is provided. The method includes operating the ultrasonically driven handpiece in a first tip displacement mode, such as a longitudinal mode according to a first set of operational parameters, and enabling a user to alter the ultrasonically driven handpiece to employ a second tip displacement mode, such as a transversal or torsional mode, using a second set of operational parameters. Enabling the user to alter performance of the handpiece comprises the user being enabled to dynamically select operational parameters for the first tip displacement mode relative to the second tip displacement mode by using, for example, a switching apparatus such as a footpedal.

Systems, devices, and methods for treating a glaucomatous eye are provided. An amount of pulsed laser energy is delivered to the pars plana of the eye by a hand-holdable device which comprises a hand-holdable elongate member and a contact member disposed on an end of the elongate member. A contact surface of the contact member is placed in direct contact with the eye so that a reference edge of the contact member aligns with the limbus and a treatment axis defined by the elongate member is angularly offset from the optical axis of the eye. The amount of pulsed laser energy delivered is insufficient to effect therapeutic photocoagulation but is sufficient to increase uveoscleral outflow so as to maintain a reduction from pre-laser treatment intraocular pressure. Amounts of pulsed laser energy will be transmitted to a circumferential series of tissue regions of the eye.

A work tip for a surgical hand piece has a solid blade connected to a source of ultrasonic energy in the hand piece. The knife has grooves in its surfaces. The work tip further including an irrigation and aspiration tubes extending along opposite surfaces of the blade and being at least partially within the grooves. The blade has a collar adjacent its distal end and at least the aspiration tube extends ends at a distance from the collar. The edges of the collar are made sharp enough to emulsify cataract tissue when vibrated at ultrasonic frequencies so that occlusion of the aspiration tube is prevented.

A phacoemulsification handpiece is provided for ophthalmic surgery. The phacoemulsification handpiece includes a housing having a cavity positioned at a distal end of the housing. The phacoemulsification handpiece further includes a horn positioned within the cavity. An irrigation line is coupled to the housing and is exterior to the housing. A port is coupled between the irrigation line and the cavity and the port is configured to direct fluid into the cavity to a side of the horn (e.g., without directly impinging on the horn, etc.).

A system for deploying an implant cut from a biological tissue into an eye of a patient including a delivery device and a nose cone assembly, a tubular shaft projecting from the distal end region of the nose cone and comprising a lumen. Related devices, systems, and methods are provided.

Devices to perform femtolaser ablation and phacoemulsification are physically and/or operationally combined. In some embodiments the femtolaser ablation and phacoemulsification are housed together, and in other embodiments they are housed separately, but operated through a common display screen. At least some software can be shared by the femtolaser ablation and phacoemulsification functionalities. A non-transitory computer-readable memory can provide data that can be used to operate each of at least one femtolaser ablation functionality and at least one phacoemulsification functionality.

The present disclosure provides a recovery device and a method for recovering a magnetic particle. The recovery device includes a main pipe, a needle tube, and a suction power mechanism. The needle tube is connected to a first end of the main pipe, and a terminal of the needle tube is magnetic for adsorbing a magnetic particle to the terminal of the needle tube. The suction power mechanism is configured to absorb the magnetic particle attached on the terminal of the needle tube into the main pipe. The present disclosure utilizes a magnetic needle tube to implement adsorption of the magnetic particle while the magnetic particle is absorbed into the main pipe by an absorption power mechanism, thus achieving recovering of the magnetic particle.