The present invention provides a micropackaged device comprising: a substrate for securing a device with a corrosion barrier affixed to the substrate, wherein the corrosion barrier comprises a first thin-film layer, a metal film coating the thin-film layer and a second thin-film layer to provide a sandwich layer; and optionally at least one feedthrough disposed in the substrate to permit at least one input and or at least one output line into the micropackaged device, wherein the micropackaged device is encapsulated by the corrosion barrier. Methods of producing the micropackaged device are also disclosed.

An electrotherapeutic device for treating a visual disease using microcurrent stimulation is provided. The device includes a signal generator in which a waveform controller digitally controls a waveform signal source so as to generate a waveform in which one or more waveform parameters (e.g., pulse width, pulse period, pulse position, pulse coding, peak current amplitude, duty cycle, and/or pulse shape) are varied in accordance with a protocol for treating a visual disease. The device also includes an applicator connected to the signal generator and configured to apply the waveform to at least one stimulation point within an eye region.

The invention relates to a system for electrical and/or magnetic neuronal stimulation, comprising a signal generator for generating a stimulation signal, in particular an alternating-current stimulation signal, an applicator for applying the stimulation signal, in particular in an area on or directly around the optic nerve, a lead for deriving a measurement signal, in particular an EEG signal, a biomarker calculation unit for calculating a biomarker based on the measurement signal, and an optimization unit, in particular for performing a stochastic optimization process, for optimizing the value of the biomarker by varying the stimulation signal.

A visual prosthesis apparatus and a method for providing artificial vision are disclosed in the present disclosure. The visual prosthesis apparatus comprises a camera for capturing a video image, a video processing unit configured to convert the video image to stimulation patterns, and a retinal stimulation system configured stimulate neural tissue in a subjects eye based on the stimulation patterns. An artificial vision may be provided by capturing a video image, converting the video image to stimulation patterns, and stimulating neural tissue in a subjects eye based on the stimulation patterns.

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 disclosure provides a computer-implemented method for enhancing vision for a vision impaired user. The method comprises, for a point in an input image, determining (210) a weight for the point based on visual importance of the point in the input image; comparing (220) the weight for the point to a threshold; and if the weight for the point meets the threshold, determining (230) a first output value for an imaging element of a vision enhancement apparatus so that a difference between the first output value and an intensity level of a portion of the input image neighbouring the point increases with the weight, wherein the difference is at least one Just-Noticeable-Difference of the vision enhancement apparatus, such that when the first output value is applied to the imaging element of the vision enhancement apparatus to create a first visual stimulus, the first visual stimulus is substantially perceivable by the vision impaired user.

A glaucoma treatment device applies electrolysis into an eye has a plurality of electrodes connected to a voltage source, and a controller coupled to a pressure sensor. The electrodes apply an electric field within an eye, and the controller regulates the delivery of current to the electrodes based on intraocular pressure measurements from the pressure sensor. The device has an enclosure for the pressure sensor, controller, and voltage source. The voltage source can recharge via an external source and the controller can accept adjustments remotely. The device also operates as a component in a method to convert aqueous humor into gas. The method utilizes electrolysis to reduce the volume of fluid in the anterior chamber of an eye. The method modulates electric current during usage of the invention. The method and device combine to reduce intraocular pressure within an eye thus lessening the progression of glaucoma.

The present invention is a method of improving the persistence of electrical neural stimulation, and specifically a method of improving the persistence of an image supplied to a retina, or visual cortex, through a visual prosthesis. A continuously stimulated retina, or other neural tissue, will desensitize after a time period in the range of 20 to 150 seconds. However, an interruption of the stimulation on the order of a few milliseconds will restore the retinal sensitivity without the user perceiving the interruption, or with the user barely perceiving the interruption.

The present invention refers to a photosensitive pixel structure comprising a substrate with a front surface and a back surface, wherein at least one photosensitive diode is provided on one of the surfaces of the substrate. A first material layer is provided at least partially on the back surface of the substrate, wherein the material layer comprises a reflective layer, in order to increase a reflectivity at the back surface of the substrate. Further, the present invention refers to an array and an implant comprising such a photosensitive pixel structure, as well as to a method to produce the pixel structure.

Disclosed are apparatus, systems, devices, methods, and other implementations, including an apparatus that includes at least one contact lens fittable on an eye of a patient, with the contact lens including circuitry for receiving electrical activity signals associated with electrical activity produced by nerve tissue located proximal to the contact lens. The apparatus further includes a first sensor configured to sense the electrical activity produced by the nerve tissue and to provide the electrical activity signals, and a first stimulator to trigger a response in a body of the patient based, at least in part, on the electrical activity signals provided by the first sensor.