Apparatus, systems and methods employing contact lens as power source for powering a retinal implant are provided. In an aspect, a contact lens includes a substrate that forms at least part of a body of the contact lens and a circuit disposed on or within the substrate comprising. The circuit includes a power harvesting component configured to receive energy in a first form from an external power source and convert the energy from the first form to a second form and an energy transfer component configured to transmit the energy in the second form to device remote from the contact lens when the contact lens is worn over an eye.

A method of manufacturing a contact lens 110 is disclosed. The method comprises manufacturing a rod of lens material 101, the rod 101 containing a plurality of electronic components 102 spaced apart along its length, separating the rod 101 into a plurality of lens blanks 106, each lens blank 106 containing at least one of said electronic components 102, and machining the front and/or back surface of a lens blank 106 to produce a contact lens 110 containing the at least one electronic component 102.

This invention discloses methods and apparatus for providing a media insert with an energy source to an ophthalmic lens. The energy source is capable of powering a component included within the ophthalmic lens. In some embodiments, an ophthalmic lens is cast molded from a silicone hydrogel and the component includes an electro-optical lens portion.

A system of power transmission to a contact lens comprises a contact lens and a magnetic component. The contact lens comprises at least a physiological signal sensing component, an induction coil, and an energy storage component. When the magnetic component has a motion relative to the induction coil, an induced voltage is produced in the induction coil for charging the energy storage component.

This invention discloses methods and apparatus for providing a media insert with an energy source to an ophthalmic lens. The energy source is capable of powering a component included within the ophthalmic lens. In some embodiments, an ophthalmic lens is cast molded from a silicone hydrogel and the component includes an electro-optical lens portion.

Apparatus, systems and methods employing contact lens as power source for powering a retinal implant are provided. In an aspect, a contact lens includes a substrate that forms at least part of a body of the contact lens and a circuit disposed on or within the substrate comprising. The circuit includes a power harvesting component configured to receive energy in a first form from an external power source and convert the energy from the first form to a second form and an energy transfer component configured to transmit the energy in the second form to device remote from the contact lens when the contact lens is worn over an eye.

A method for customizing active contact lenses, such as contact lens displays, for a plurality of wearers includes the following: Contact lens precursors are obtained for a plurality of wearers. The contact lens precursors include active electronics. The same contact lens precursors are used as a starting point to generate active contact lenses for many different individuals, but they are processed into active contact lenses that are customized for each individual wearer.

Described here are devices, systems, and methods for increasing tear production by stimulating the cornea, conjunctiva, and/or subconjunctiva. In some variations, the devices may be in the form of a contact lens. The contact lens may comprise a lens body and a stimulator chip, where the stimulator chip is embedded in the lens body. An external power source wirelessly transmits energy to the stimulator chip, where the stimulator chip may convert the energy to an electric waveform to stimulate the cornea, conjunctiva, and/or subconjunctiva. Stimulation may activate the lacrimal reflex to increase tear production. The devices and systems for increasing tear production may be used in methods of treating dry eye, reducing the symptoms of tired eye, increasing comfort for contact lens wearers, and extending the number of years a contact lens user can wear contacts. Also described are methods of manufacturing a contact lens.

The present invention provides methods for forming an ophthalmic lens that can include a media insert and/or electronic components. In particular, the present disclosure provides for adhesion promoting functionalization steps for a biocompatible coating to bind a hydrogel material to a plastic surface or electronic component prior to the polymerization of the hydrogel. In some aspects, the media insert can be used to contain energy sources and/or functional electronic components which may be, for example, in a stacked integrated component configuration to permit a generally arcuate shape that can conform to the anterior surface of an eye.

Methods of forming a lens include forming components on a lower substrate. The components are sealed on the lower substrate with a sealing layer. An upper substrate is formed over the sealing layer. The lower substrate is polished to a lower lens curvature.