A device and method for applying light to the cornea of the eye as, for example, to promote crosslinking of collagen in the cornea for vision correction. The device may include a structure having form and size similar to a conventional contact lens. The structure may include an optically dispersive element such as a mass of an optically dispersive material that may be contained in a cavity of a reflective element. Light applied to the dispersive mass as, for example, by an optical fiber connected to the structure is dispersed in the structure and passes into the cornea. The patient may blink or close the eye during the procedure, which increases patient comfort and aids in maintaining hydration of the cornea.

Provided herein are ophthalmic phototherapy devices and associated phototherapy methods for promoting healing of damaged or diseased eye tissue. An ophthalmic phototherapy device includes a light emitting mechanism for transmitting light of at least one preselected wavelength to the eye tissue. An ophthalmic phototherapy method includes directing light of at least one wavelength for a selected period of time to a portion of damaged or diseased eye tissue, whereby the light transmitted to the damaged or diseased eye tissue stimulates cellular activity in the eye tissue to promote healing.

The present disclosure concerns a digital corneal crosslinking technology for adjusting the corneal curvature, comprising the following steps: administering in drops a composition comprising a photoinitiator compound to the corneal stromal of the subject, locally irradiating the corneal by utilizing digital micromirror device controlled by computer. The corneal curvature can be adjusted totally or locally. The invention also discloses an apparatus for the digital corneal crosslinking. The method and apparatus is minimum invasive and can be used to accurately and efficiently adjust the corneal curvature.

The invention relates to a device for a medical treatment of a sclera, the device (100) comprising a curved disc or a belt (102), wherein the disc/belt is configured to be placed into the Tenon's space; the disc/belt is formed such that the inner surface of the curved disc/belt is superficially contactable to the surface of an area of the sclera so as to superficially cover said area; and the disc/belt comprises one, two, three, four, or more independent channel systems (101).

Ophthalmic treatment systems and methods of using the systems are disclosed. The ophthalmic treatment systems include (a) a light source device; (b) at least one optical treatment head operatively coupled to the light source device, comprising a light source array, and providing at least one treatment light; and (c) a light control device, which (i) provides patterned or discontinuous treatment light projection onto an eye (e.g., the cornea and/or sclera of an eye); or (ii) adjusts intensity of part or all of the light source array, providing adjusted intensity treatment light projection onto an eye (e.g., the cornea and/or sclera of an eye). The at least one treatment light promotes corneal and/or scleral collagen cross-linking.

A change in the response of the cornea to ultrasonic energy directed into the cornea is monitored during irradiation of the cornea to bring about corneal crosslinking. Because the change in ultrasonic response is correlated with the degree of crosslinking achieved, a desired degree of crosslinking can be achieved by terminating the irradiation when the change reaches a threshold. The change in ultrasonic response can be determined by taking a baseline measurement before irradiation and additional measurements during irradiation using the same ultrasonic transducer (47). The transducers may be carried on a device (30) resembling a contact lens which overlies the eye and which transmits the light used in the irradiation step to the eye.

An ophthalmological device (10) for the treatment of corneal diseases such as keratoconus and glaucoma, comprises a moulding head (12), a suction body (14) and a UV lamp (15). The moulding head (12) has a hollow cylindrical configuration and includes a rigid moulding lens (18) for shaping the cornea of an eye (11) of a patient. The lens is curved and defines a plurality of apertures therein. The suction body (14) has a hollow cylindrical configuration. The lamp (15) is fitted to the suction body. Moulding head (12) and suction body (14) together define a chamber (32) from which air is evacuated so as to induce a partial vacuum within the chamber (32) for attracting the cornea onto the lens (18). A photo-sensitizer is applied to the eye and while the cornea is held against the mould, it is irradiated with UV light by lamp (15) so as to cross-link collagen fibres in the cornea.

The present application relates generally to a method for vision correction using corneal collagen crosslinking (CCXL), in which the physician is able to precisely control the pattern of ultraviolet (UV) energy delivered to the cornea, by means of a programmable masking array placed between the UV source and the cornea. A CCXL LCD masked is used to create various patterns of on and off pixels. The physician is able to control the degree of polarization of the LCD pixels, thereby allowing the physician to create various patterns of UV irradiation and thus, varying levels of CCXL.

Systems, methods, and devices for promoting eyelash hair growth includes an energy transducer, positionable proximate the eyelid, configured to provide light energy to a user's eyelids at an output wavelength suitable for stimulating eyelash hair growth, and a scleral shield, positionable inside of the eyelid, to protect the eye from the light energy. The device may be powered by an internal power source, such as a rechargeable battery or disposable batteries, or by an external power source, such as a plug used in connection with an AC outlet. In use, the eyelid is positioned between the energy transducer and the scleral shield, and the light energy from the energy transducer is applied to the eyelash region of the eyelid to promote eyelash hair growth.

An example system for corneal treatment includes an illumination system to generate cross-linking in at least one selected region of a cornea treated with a cross-linking agent by delivering photoactivating light according to one or more photoactivation parameters. The system includes a controller to receive input relating to one or more treatment parameters, which include the one or more photoactivation parameters. The controller is configured to output information for adjusting the one or more treatment parameters by (A) determining from the input, a distribution of cross-links for the at least one selected region of the cornea; (B) determining, from the distribution of cross-links, a shape change for the cornea; and (C) determining, from the shape change for the cornea, a change in vision for the subject. Responsive to the output from the controller, the illumination system is configured to adjust at least one of the one or more photoactivation parameters.