There is provided a method for creating artificial vision with an implantable visual stimulation device. The method comprises receiving image data comprising, for each of multiple points of the image, a depth value, performing a local background enclosure calculation on the input image to determine salient object information, and generating a visual stimulus to visualise the salient object information using the visual stimulation device. Determining the salient object information is based on a spatial variance of at least one of the multiple points of the image in relation to a surface model that defines a surface in the input image.

An implantable device includes a flexible cable, a circuit chip, a fluid adhesion layer, and a vapor deposited layer. The flexible cable includes a lead-in part, a stimulation part and a connection part connected between the lead-in part and the stimulation part. The circuit chip is fixed to a surface of one side of the lead-in part, and is electrically connected to the lead-in part. The fluid adhesion layer is adhered to an outer side of the circuit chip and an outer side of the lead-in part. The vapor deposited layer (4) is directly deposited on an outer side of the fluid adhesion layer.

A method for creating artificial vision with an implantable visual stimulation device. The method comprises receiving image data comprising, for each of multiple points of an image, a depth value, performing a local background enclosure calculation on the image data to determine salient object information, and generating a visual stimulus to visualise the salient object information using the implantable visual stimulation device. Performing the local background enclosure calculation is based on a subset of the multiple points of the input image, and the subset of the multiple points is defined based on the depth value of the multiple points.

The present invention relates to photosensitive arrays comprising a plurality of photosensitive elements disposed in or on a suitable substrate. The photosensitive arrays are useful as implants, in particular as retinal implants. Methods for manufacturing such arrays are also provided.

A charging energy control system includes an implantable medical device (IMD) and an external charger for effectuating wireless power transfer. The IMD receives charging energy to recharge a battery during an ON period and rejects the charging energy during an OFF period. A series switch is disposed between the IMD's coil and rectifier circuitry that is controlled by voltage regulation circuitry operative to generate a clamp control signal configured to detune the coil in the OFF state.

A neural stimulator system which generates stimulation from an implantable stimulator circuit which generates stimulation outputs which mimic biological signals. The user/operator can select stimulation generated from recorded waveforms, or by selecting the characteristics for generating stimulation based on randomized inter-pulse-intervals (IPI). A control unit controls the operation of the implantable stimulator circuit, and receives sets of stimulation parameters based on user input from a user input device executing application specific programming.

Flexible implant for electrically recording or stimulating a nerve structure, said flexible implant comprising: a first layer of electrically insulating diamond; an electrode of electrically conductive doped diamond, in contact with the first layer of electrically insulating diamond; an electrically conductive layer in contact with the electrode and the first layer, so as to define a conductive track for the electrode; and a second layer of electrically insulating diamond, at least in contact with the electrically conductive layer and a remaining portion of the first layer, all of the above arranged such that: electrically insulating diamond/electrically conductive doped diamond sealing is provided at the electrode (3) by resumption of epitaxial growth; and the electrically conductive layer is encapsulated by the electrode (3), the first layer and the second layer, at the electrode and over the entirety of the remaining surface thereof except over an area defining an electrical contact. The implant has two faces, namely: a front face comprising one of the two layers of electrically insulating diamond, open locally, providing access to the electrode and the area defining an electrical contact; and a rear face comprising the other of the two layers of electrically insulating diamond.

Retinal prostheses are described with visual acuity better than 20/150, and higher sensitivity, dynamic range, and FOV than the state-of-the-art. At least two different techniques are presented, the first being an optically-switched vertical single-transistor amplifier for ultrahigh photocurrent amplification, and the second being nanopatterned pillar electrodes.

Provided is an artificial retina system for improving contrast sensitivity. The artificial retina system includes an artificial retina which is installed under the retina and includes a plurality of photodiode cells and a microcomputer. The microcomputer compares, with at least one reference value, the magnitude of an electric signal outputted from a photodiode in each of the photodiode cells. The microcomputer controls to amplify or reduce the electric signal outputted by each of the photodiode cells according to the result of comparison. Visual cells corresponding to each of the photodiode cells can be stimulated with an electric signal controlled by the microcomputer.

The present invention relates to a tip for use with delivery devices, particularly for use in implanting retinal implants into the retinal space of an eye. The tip includes a flexible envelope and an internal sliding member. Further, the invention relates to an inserter attachment and a delivery device including said tip.