Drug delivery devices comprising a non-bioabsorbable polymer structure configured to support a composition comprising an active agent. The devices include a plurality of portions fused together and a recess configured to support the composition. At least one of the portions includes an impermeable polymer and at least one other portion includes a rate-limiting water-permeable polymer. The rate-limiting water-permeable polymer allows for transportation of the active agent to an exterior of a the device.

The present invention provides benzothiadiazine and chroman derivatives and particularly diazoxide and cromakalim derivatives for use in treating glaucoma, retinopathy, treating age related macular degeneration, treating, stabilizing and/or inhibiting blood and lymph vascularization, and reducing intraocular pressure by administering a pharmaceutically effective amount of a prodrug disposed in an ophthalmically acceptable carrier to the eye, wherein the prodrug specifically modulates a K.sub.ATP channel to reduce an intraocular pressure.

The present invention relates to methods and pharmaceutical compositions for the treatment of choroddal neovascularisation. In particular, the present invention relates to a method of treating choroidial neovascularisation in a subject in need thereof comprising administering to the subject of therapeutically effective amount of a mineralocorticoid receptor antagonist.

The present invention relates to a method of increasing the bioavailability and/or prolonging ophthalmic action of a drug, the method comprising instilling into the eye an aqueous suspension comprising reversible clusters of drug loaded nano-resin particles, said clusters having a D50 value of at least 2 micrometer and said drug loaded nano-resin particles have a particle size distribution characterized in that the D90 value is 70 nanometer to 900 nanometer. The present invention further relates to an aqueous suspension comprising reversible clusters of drug loaded nano-resin particles, said clusters have a D50 value of at least 2 micrometers and said drug loaded nano-resin particles have a particle size distribution characterized in that the D90 value is 70 nanometers to 900 nanometers.

The disclosure describes a fusogenic liposome-coated porous silicon nanoparticles for high loading efficiency of anionic payloads (small molecules, dyes, nucleic acids), and for non-endocytic delivery of hydrophilic and lipophilic payloads by membrane fusion. The liposome coating can be further modified with targeting peptides or antibodies via covalent binding chemistry between the ligands and functionalized poly(ethylene glycol). The surface moieties can be transferred to the cellular membrane surface by fusogenic uptake. The composition of the disclosure can be applied in the treatment of diseases by delivering entrapped/encapsulated payloads.

This invention relates to a bioerodible drug delivery device that can be implanted in a patient at or near an area in need of treatment. The bioerodible drug delivery device can be used to deliver a wide variety of different pharmaceutically active agents, and can do so at a controlled rate and over an extended period of time. The bioerodible drug delivery device includes a bioerodible polymeric outer housing with one or more delivery ports for delivering the pharmaceutically active agent(s) contained therein. The polymer used as the bioerodible polymeric outer housing is not substantially degraded during the dosing of the pharmaceutically active agent(s) in the bioerodible drug delivery device. The invention also provides methods of making the bioerodible drug delivery device and using it for the treatment of diseases and disorders.

This disclosure relates to a drug delivery system comprising a neurotrophic agent, an apoptosis signaling fragment inhibitor (FAS) or FAS-ligand (FASL) inhibitor, a tumor necrosis factor-α (TNF-α) or TNF receptor (TNFR) inhibitor, a mitochondrial peptide, an oligonucleotide, a chemokine inhibitor, a cysteine-aspartic protease inhibitor, including any combination of these compounds and, optionally, a sustained delivery component. This type of drug delivery system can be used to treat a medical condition such as an inherited or age-related choroid, retina, optic nerve disorder, or optic nerve degeneration; an otic disorder; a neurologic or CNS disorder; or a related condition; or a condition related to occlusion or obstruction of a blood vessel or blood circulation such as a stroke, myocardial or renal infarction. Medicaments, methods of manufacturing medicaments, kits, and other related products or methods are also described.

A method of refraction-correcting ophthalmic surgery in tissue of an eye after at least one previous ophthalmic surgery in the tissue, comprising accessing information on a pre-operative cut and defining a cut surface on the basis of the information on the pre-operative cut of the at least one previous ophthalmic surgery of the tissue of the eye.

The disclosure relates to compounds and compositions for sustained release of ocular therapeutics.

An ocular medical injector is provided for drug delivery. A method includes inserting a puncture member of the medical injector into the eye until the puncture member reaches the SCS. The puncture member defines a lumen therethrough. With the puncture member disposed within the SCS, a flexible cannula is advanced distally through the lumen of the puncture member, beyond the distal end portion of the puncture member and along the SCS towards a posterior region of the eye. The flexible cannula has an atraumatic distal tip and defines a lumen therethrough. With the distal tip of the flexible cannula disposed within the SCS beyond a distal end portion of the puncture member, a therapeutic substance is administered to the SCS.