Ophthalmic implants, their methods of use and manufacture. The implants may include a transparent optic portion and a peripheral non-optic portion coupled to the optic portion. The transparent optic portion may be made of a transparent optic material adapted to allow visible light to pass therethrough, and the peripheral non-optic portion may be made of a light absorbing material adapted to absorb visible light.

The present disclosure provides devices and methods for the treatment of ophthalmological conditions such as dry eye. Among the devices provided are punctal plugs and devices for inserting punctal plugs. The punctal plugs may be shaped for insertion in the punctum and/or the canaliculus. They may also be coated with a bioadhesive. Methods for inserting the punctal plugs are provided, as well as methods for preparing bioadhesive-coated punctal plugs. A method is also provided to treat dry-eye using a bioadhesive without use of a punctal plug.

Methods are disclosed for fabricating a three-dimensional engineered blood retinal barrier (BRB) comprising a choroid and retinal pigment epithelial cells. The methods include the use of bioprinting. Also disclosed is a three-dimensional engineered BRB, and its use. Methods are also disclosed for using the three-dimensional engineered BRB, such as for the treatment of retinal degeneration in a subject or screening. A three-dimensional printing insert that is adapted for bioprinting on a culture substrate sheet that is securely retained within and exposed through a printing frame is also disclosed.

The present disclosure provides devices and methods for the treatment of ophthalmological conditions such as dry eye. Among the devices provided are punctal plugs and devices for inserting punctal plugs. The punctal plugs may be shaped for insertion in the punctum and/or the canaliculus. They may also be coated with a bioadhesive. Methods for inserting the punctal plugs are provided, as well as methods for preparing bioadhesive-coated punctal plugs. A method is also provided to treat dry-eye using a bioadhesive without use of a punctal plug.

The invention provides methods and polymer compositions for treating retinal detachment and other ocular disorders, where the methods employ polymer compositions that can form a hydrogel in the eye of a subject. The hydrogel is formed by reaction of (i) a nucleo-functional polymer that is a biocompatible polymer containing a plurality of thio-functional groups —R1-SH wherein R1 is an ester-containing linker, such as a thiolated poly(vinyl alcohol) polymer and (ii) an electro-functional polymer that is a biocompatible polymer containing at least one thiol-reactive group, such as a poly(ethylene glycol) polymer containing alpha-beta unsaturated ester groups.

Glaucoma treatment systems are disclosed. In various example, the glaucoma treatment systems include a body and a fluid conduit configured to facilitate an evacuation of fluid, such as aqueous humor, from a fluid-filled body cavity, such as an anterior chamber of an eye. In some examples, the fluid conduit is soft and compliant, and the glaucoma treatment system includes one or more stiffening members coupled with the fluid conduit to temporarily stiffen the fluid conduit and help aid in the delivery of the glaucoma treatment device. In some examples, the stiffening members are removable from the fluid conduit after the glaucoma treatment system has been implanted.

Several embodiments disclosed herein relate to compositions and methods for treating or repairing damage to ocular tissue. In particular, several embodiments relate to patches that interact, e.g., by way of an adhesive, with damaged retinal tissue to repair or mend a hole, tear or detachment of the retina from underlying ocular tissue. Still additional embodiments relate to self-assembling patches.

Intraocular lenses with pressure sensors embedded therein, and methods of manufacture.

A bioanalogic implantable ophthalmic lens (“BIOL”) capable of replacing the natural crystalline lens (NCL) in its various essential functions after the NCL having been removed and BIOL implanted into the posterior eye chamber and placed into the capsular bag vacated from the NCL. At least the posterior surface of the lens has a convex shape and is made from a transparent flexible hydrogel material. At least the anterior and posterior optical surfaces are defined by rotation of one or more conic sections along the main optical axis and the surfaces defined by the rotation will include a plane perpendicular to the axis and conical surface symmetrical by the axis. A hydrogel implantable ophthalmic lens whose optical parameters can be optimized and/or customized by a controlled absorption of electromagnetic radiation resulting in a change of the refractive index of the irradiated hydrogel.

Disclosed are co-polymers which are produced from reactive monomer mixtures and which have both high refractive index and a high Abbe number. These materials are well suited for use as implantable ophthalmic devices and have a refractive index which may be edited through application of energy. When used for an intraocular lens, the high refractive index allows for a thin lens which compresses to allow a small incision size.