Methods and kits for treating or preventing an eye condition or for cleaning an eye area tissue are provided. A method of the invention includes administering an isoprenoidal essential oil to eye area tissue, chafing eye area tissue with an abrasive, and removing the abrasive. A kit according to the invention includes an isoprenoidal essential oil, an abrasive for chafing eye area tissue, and in instruction for use for treating an eye condition or cleansing an eye area tissue. The invention also includes a composition of matter comprising an isoprenoidal essential oil and a plurality of abrasive particles in ophthamologically acceptable base.

Lacrimal implants, methods of making lacrimal implants, and methods of treating ocular, respiration or other diseases or disorders using lacrimal implants are disclosed.

A conformable covering comprises an outer portion with rigidity to resist movement on the cornea and an inner portion to contact the cornea and provide an environment for epithelial regeneration. The inner portion of the covering can be configured in many ways so as to conform at least partially to an ablated stromal surface so as to correct vision. The conformable inner portion may have at least some rigidity so as to smooth the epithelium such that the epithelium regenerates rapidly and is guided with the covering so as to form a smooth layer for vision. The inner portion may comprise an amount of rigidity within a range from about 1×10−4 Pa*m3 to about 5×10−4 Pa*m3 so as to deflect and conform at least partially to the ablated cornea and smooth an inner portion of the ablation with an amount of pressure when deflected.

A conformable covering comprises an outer portion with rigidity to resist movement on the cornea and an inner portion to contact the cornea and provide an environment for epithelial regeneration. The inner portion of the covering can be configured in many ways so as to conform at least partially to an ablated stromal surface so as to correct vision. The conformable inner portion may have at least some rigidity so as to smooth the epithelium such that the epithelium regenerates rapidly and is guided with the covering so as to form a smooth layer for vision. The inner portion may comprise an amount of rigidity within a range from about 1×10−4 Pa*m3 to about 5×10−4 Pa*m3 so as to deflect and conform at least partially to the ablated cornea and smooth an inner portion of the ablation with an amount of pressure when deflected.

A method of treating a subject with dry-form age-related macular degeneration (AMD) is disclosed. The method comprises administering into the subretina of the subject a therapeutically effective amount of a pharmaceutical composition comprising human RPE cells, wherein at least 95% of the cells thereof co-express premelanosome protein (PMEL17) and cellular retinaldehyde binding protein (CRALBP), wherein the trans-epithelial electrical resistance of the cells is greater than 100 ohms to the subject, thereby treating the subject.

An adherence device 100, including an attachable component to secure to an eye drop bottle cap and a monitoring component 110. The monitoring component 110 includes a sensor 170 to detect each eye drop administration. The attachable camponent may be a “universal cap” capable of securing onto any eye drop bottle cap while still permitted normal FDA-approved water-tight closure. The cap is capable of being removed and transferred to a different eye drop bottle for reuse.

An adherence device 100, including an attachable component to secure to an eye drop bottle cap and a monitoring component 110. The monitoring component 110 includes a sensor 170 to detect each eye drop administration. The attachable camponent may be a “universal cap” capable of securing onto any eye drop bottle cap while still permitted normal FDA-approved water-tight closure. The cap is capable of being removed and transferred to a different eye drop bottle for reuse.

A fluid dispensing device includes a light source, and a nozzle spaced from the light source. The device also includes a membrane positioned within a beam path of the light source, where the membrane is configured to allow a portion of light from the light source through to the nozzle. The device also includes a fluid chamber positioned between the membrane and the nozzle, where the nozzle is configured to allow a beam of the portion of light to pass through along the beam path, and where the nozzle is further configured to form a stream of fluid expelled from the fluid chamber along the beam path.

The present invention relates to improved contact lens packages and methods of use, manufacture, and assembly. A contact lens package houses a contact lens and packaging solution in which the contact lens may be held by surface tension to an intermediate plug, by which the user may insert the contact lens into the wearer's eye. The plug may have an adhesive that temporarily holds the plug to the user's fingertip while the contact lens is inserted into the wearer's eye.

Described here are systems and methods for accessing Schlemm’s canal and for delivering an ocular device or fluid composition therein. The ocular devices may maintain the patency of Schlemm’s canal without substantially interfering with transmural fluid flow across the canal. The fluid composition may be a viscoelastic fluid that is delivered into the canal to facilitate drainage of aqueous humor by disrupting the canal and surrounding trabeculocanalicular tissues. Tools for disrupting these tissues and minimally invasive methods for treating medical conditions associated with elevated intraocular pressure, including glaucoma, are also described.