A device for reducing the incidence of surgical debris migration within a mammalian eye comprising an anterior portion, the anterior portion with an anterior inner surface and an opposing anterior outer surface, the anterior inner surface and the anterior outer surface terminating at an anterior edge that defines an open anterior end; and a posterior portion, with a posterior inner surface and an opposing posterior outer surface, the posterior inner surface and the posterior outer surface terminating at a posterior edge, the posterior edge defining an open posterior end; and a waist connecting the anterior portion and the posterior portion, the waist comprising a waist inner surface and an opposing waist outer surface; and an aperture extending from the open anterior end, through the waist, and to the open posterior end, the aperture bounded by the anterior inner surface, the waist inner surface, and the posterior inner surface.

The present technology is directed to adjustable flow glaucoma shunts, systems, and methods for making and using such devices. In many of the embodiments described herein, the shunts include a drainage element configured to fluidly couple an anterior chamber of an eye and a target outflow location, such as a subconjunctival bleb space. The shunts can further include a flow control assembly coupled to the drainage element and configured to control the flow of fluid (e.g., aqueous) therethrough. The shunts can further include an outer membrane or bladder that encases the flow control assembly. The outer membrane can include a plurality of apertures that fluidly couple an interior of the outer membrane with an environment exterior to the outer membrane.

Provided are embodiments of systems, devices and methods to aid in or perform the capsulotomy procedure via access into an eye through a small incision. Embodiments of the present disclosure may employ the unique characteristics of shape-memory materials to enable device access into the eye through the requisite small incision size, and via simple mechanical means either to create a template for surgeons to follow in order to create an appropriately-sized capsulotomy, or to create such a capsulotomy via cutting, tearing, or abrading the lens capsule.

A process of making a diverging-light fiber optics illumination delivery system includes providing a micro-post comprising a glass-ceramic light-scattering element that includes at least one of a ceramic, a glass ceramic, an immiscible glass, a porous glass, opal glass, amorphous glass, an aerated glass, and a nanostructured glass; and fusion-splicing the glass-ceramic micro-post to the optical fiber by pulling an arc between electrodes across a gap formed by the optical fiber and the glass-ceramic micro-post; maintaining the arc for a time sufficiently long to make facing surfaces of the optical fiber and the micro-post one of malleable and molten; and pushing and thereby fusing together the facing surfaces of the optical fiber and the micro-post. Some embodiments can include fusing the glass-ceramic micro-post to the optical fiber by applying a laser beam to heat up at least one of the facing surfaces of the optical fiber and the glass-ceramic micro-post.

A process of making a diverging-light fiber optics illumination delivery system includes providing a micro-post comprising a glass-ceramic light-scattering element that includes at least one of a ceramic, a glass ceramic, an immiscible glass, a porous glass, opal glass, amorphous glass, an aerated glass, and a nanostructured glass; and fusion-splicing the glass-ceramic micro-post to the optical fiber by pulling an arc between electrodes across a gap formed by the optical fiber and the glass-ceramic micro-post; maintaining the arc for a time sufficiently long to make facing surfaces of the optical fiber and the micro-post one of malleable and molten; and pushing and thereby fusing together the facing surfaces of the optical fiber and the micro-post. Some embodiments can include fusing the glass-ceramic micro-post to the optical fiber by applying a laser beam to heat up at least one of the facing surfaces of the optical fiber and the glass-ceramic micro-post.

A glaucoma drainage device includes an elongated body extending axially from a distal end to a proximal end. The distal end forms a wedge with a leading distal edge. During implantation of the device into the suprachoroidal space of the eye, the wedge can facilitate penetration into and spreading open the tissue of the suprachoroidal space. The elongate body has one or more outer surfaces that define at least one open groove extending from at or near the proximal end towards the distal end of the body. With the distal end of the elongate body located in the suprachoroidal space of the eye and the distal end of the elongate body extending into the anterior chamber of the eye, the at least one open groove is configured such that aqueous humor flows along the open groove from the anterior chamber of the eye to the suprachoroidal space of the eye.

Projection of visible, non-treatment light onto an eye to illuminate specific areas of the surgical field is disclosed herein. A surgical system may include a surgical console; a microscope communicatively coupled to the surgical console; a camera communicatively coupled to the surgical console; and a projector operable to project light onto an eye. The projector may be communicatively coupled to the surgical console. A method for light projection may include collecting information from an eye using a camera; determining the light projection based, at least in part, on the collected information; and projecting visible, non-treatment light onto the eye using a projector.

An ophthalmic surgical instrument for cataract removal surgery includes a helical coil structure including a wire or elongated structure coiled in a plurality essentially similar diameter coils of 360-degree turns in a corkscrew having a coil diameter sufficiently small to fit within an incision of a human ocular lens capsule for entering the human ocular lens capsule during a cataract removal surgery. A pointed sharp end pierces and grasps a human ocular lens under the control of a surgeon upon being inserted in a human ocular lens capsule within said ocular lens capsule during a cataract removal surgery. The corkscrew structure firmly holds the human ocular lens and controls the position and movement of the human ocular lens during said cataract removal surgery.

Methods for treating Blepharitis, Meibomian Gland Dysfunction and Dry Eye Syndrome include thermal massage, thermal debridement, and thermal expression. Particular embodiments include use of handheld devices that provide the thermal therapy to tissue by contacting a surface heated with thermal energy to a patient's tissue. Thermal energy can be continuously provided during operation. In particular embodiments, a handheld device comprises a base assembly operatively connected to a removeable thermal energy applicator. A wide range of thermal applicators may be connected to the base assembly to provide different treatments, including heat application, debridement, and expression of the treated tissue or gland.

Apparatus and methods are described including a robotic unit configured to move the tool through six degrees-of-freedom, and a control component that comprises at least one control-component arm configured to be moved by a user, The control-component arm includes three rotary encoders, each of the three rotary encoders coupled to a respective joint and configured to detect movement of the respective joint and to generate rotary-encoder data indicative of an XYZ location of a tip of the control-component tool, in response thereto, and an inertial measurement unit comprising at least one of a three-axis accelerometer, a three-axis gyroscope, and a three-axis magnetometer, the inertial measurement unit being configured to generate inertial-measurement-unit data indicative of an orientation of the tip of control-component tool. Other applications are also described.