Abstract: 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.

Abstract: 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.

Abstract: The present invention refers to a photosensitive pixel structure (10) comprising a substrate (15) with a front surface and a back surface, wherein at least one photosensitive diode (12, 12?) is provided on one of the surfaces of the substrate (15). A first material layer (30) is provided at least partially on the back surface of the substrate (15), wherein the material layer (30) 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 (1) and an implant comprising such a photosensitive pixel structure (10), as well as to a method to produce the pixel structure (10).

Abstract: The present invention relates to a photosensitive pixel structure (10). The pixel structure (10) comprises a substrate (15) and at least one photosensitive diode (12, 12?, 12?), a stimulating electrode (14), and a resistor (16). The resistor (16) is electrically connecting the stimulating electrode (14) and a counter electrode (18). Further, the resistor (16) is at least partially covered by the stimulating electrode (14) and/or the resistor (16) is at least partially covered by the counter electrode (18).

Abstract: The present invention relates to a photosensitive implant comprising at least one pixel (10) having at least one diode (12, 12?), a stimulating electrode (14), a counter electrode (18), and a resistor (16), wherein the resistance of the resistor (16) is chosen according to a predetermined relation of resistance, a size of the stimulating electrode (14), and a size of the diode (12, 12?). Further, the present invention concerns a method to provide such an implant.

Abstract: The object,—to create a printed circuit board for an implant having improved properties in connection with the electrical contacting via the contact points of the conductor tracks on the printed circuit board,—is achieved, according to the present invention, by means of a device for contacting and/or electrostimulation of living tissue cells or nerves with having a printed circuit board having with at least one contact point for electrical contacting, the printed circuit board encompassing comprising a flexible multilayer system with at least one conductor track. In accordance with the invention, the contact points for the conductor track in the multilayer system are galvanically reinforced. To this end, a galvanically reinforced layer is grown onto the already preprocessed contact point, for example by means of a galvanic process.

Abstract: A visual prosthesis in the form of a retinal implant, which is distinguished by the least possible space requirement inside the eye, is achieved by a visual prosthesis having an intraocular implant and an extraocular implant, which supplies the intraocular implant with energy and controls it. Virtually all the electronic components, which do not necessarily need to be accommodated with the intraocular implant inside the eye, can be arranged outside the eyeball, for example on the sclera. In this way, the space requirement of the stimulation system inside the eye is reduced and the operative intervention for implanting the stimulation system inside the eye is kept as small as possible. A bidirectional inductive interface between an extracorporeal part of the visual prosthesis and an intracorporeal part, including the intraocular and extraocular implants, via which a current supply and bidirectional data transmission can be carried out is provided.

Abstract: The object of providing a device for reversibly attaching an implant to an eye, with which the implant can be attached in a simple way to the eye and can if necessary be detached or removed from the eye, is achieved according to the present invention by means of a device for attaching an implant by means of a pin that comprises a substantially elongated shaft, wherein the implant includes an implant film for contacting living tissue or nerves in the visual system of the eye and the implant film has an opening through which the shaft of the pin can be at least partially inserted, characterised in that the device includes a holding element that can be arranged on the shaft of the pin so that the holding element engages on the shaft of the pin and is fixed in an attachment position to the pin.

Abstract: Retinal prostheses are configured to apply retinal stimulus signals based on retinal cell classification such as cell types or cell clusters identified based on retinal cell signals. Cell types are identified based on spontaneous or induced retinal electrical signals and analyzed based on temporal patterns of electrical activity, spatio-temporal voltage waveforms, and signal correlations that can be obtained from temporal spike patterns. Cell type indications are stored, and a signals are applied to the retina based on the stored cell type indications.

Abstract: A visual prosthesis in the form of a retinal implant, which is distinguished by the least possible space requirement inside the eye, is achieved by a visual prosthesis having an intraocular implant and an extraocular implant, which supplies the intraocular implant with energy and controls it. Virtually all the electronic components, which do not necessarily need to be accommodated with the intraocular implant inside the eye, can be arranged outside the eyeball, for example on the sclera. In this way, the space requirement of the stimulation system inside the eye is reduced and the operative intervention for implanting the stimulation system inside the eye is kept as small as possible. A bidirectional inductive interface between an extracorporeal part of the visual prosthesis and an intracorporeal part, including the intraocular and extraocular implants, via which a current supply and bidirectional data transmission can be carried out is provided.

Abstract: The task of providing a device which makes it possible for the natural visual faculty of a partially vision-impaired person to be restored or supported as realistically as possible by means of a visual aid or visual prosthesis is achieved with the visual aid according to the invention in that, beyond the pure acquisition of a two-dimensional image, additional information is included in the image processing. For this purpose, a visual aid system is proposed which, during the reproduction of the processed image, visualizes additional information regarding the spatial position and/or specific attributes of objects in the acquired image which is associated with objects in the acquired image.

Abstract: The present invention relates to a microelectronics element, such as an optical receiver element, for a medical implant device to be implanted in the human or animal body, particularly for a retinal implant device. The microelectronics element comprises a functional unit including application specific microelectronics, such as a photodiode, for performing a function in the medical implant device, and rectifier means adapted for converting an AC supply voltage into a DC voltage. The DC voltage provided by the rectifier means, or an operating voltage derived from the DC voltage, is configured to be supplied to the functional unit. Further, the functional unit and the rectifier means are integrated on a common semiconductor substrate and configured such that the rectifier means isolates the microelectronics element from application of an external DC supply voltage. The invention also relates to a medical implant device, such as a retinal implant, which incorporates such a microelectronics element.

Abstract: A power supply for a retina implant at least partly located in the interior of a patient's eye is described. The power supply comprises a first transmission coil (4, 23), a second transmission coil (5, 24). The power supply further comprises a signal generation unit adapted for generating a first high frequency signal and a second high frequency signal, and for applying the first high frequency signal to the first transmission coil and the second high frequency signal to the second transmission coil, the second high frequency signal being phase shifted relative to the first high frequency signal. The first transmission coil is adapted for transmitting the first high frequency signal, and the second transmission coil is adapted for transmitting the second high frequency signal.

Abstract: A device for stimulating living tissue or nerves by individual or repeated stimulating pulses via stimulating electrodes which stimulate living tissue or nerves by stimulating pulses includes an electrical circuit which regulates the electric voltage or charge on the stimulating electrodes as a function of the electric voltage between the stimulating electrodes and reduces or equalises imbalances of electric charges on the stimulating electrodes. This device is capable of equalizing the electric charge on the stimulating electrodes of a stimulation system. The device and the process for using the device have the advantage that imbalances of electric charges on the stimulating electrodes, and the associated disadvantageous effects on the tissue and on the nerves, are avoided or eliminated. Furthermore, the device has a small space requirement.

Abstract: The present invention provides a visual prosthesis comprising: image capture means for capturing an image from a surrounding environment; image processing means for processing the image and converting the image into a transmissible image signal; signal processing means for processing and converting the image signal into a stimulation signal; and a retina stimulation device (10) adapted to stimulate the retina of both left and right eyes in accordance with the stimulation signal. The retina stimulation device (10) comprises a left-side stimulation unit (11) having an electrode array (12) for stimulating the retina of the left eye, and a right-side stimulation unit (11?) having an electrode array (12?) for stimulating the retina of the right eye, with the left-side stimulation unit (11) having a configuration which is reversed with respect to a configuration of the right-side stimulation unit (11?).

Abstract: The present invention relates to a microelectronics element, such as an optical receiver element, for a medical implant device to be implanted in the human or animal body, particularly for a retinal implant device. The microelectronics element comprises a functional unit including application specific microelectronics, such as a photodiode, for performing a function in the medical implant device, and rectifier means adapted for converting an AC supply voltage into a DC voltage. The DC voltage provided by the rectifier means, or an operating voltage derived from the DC voltage, is configured to be supplied to the functional unit. Further, the functional unit and the rectifier means are integrated on a common semiconductor substrate and configured such that the rectifier means isolates the microelectronics element from application of an external DC supply voltage. The invention also relates to a medical implant device, such as a retinal implant, which incorporates such a microelectronics element.

Abstract: The object,—to create a printed circuit board for an implant having improved properties in connection with the electrical contacting via the contact points of the conductor tracks on the printed circuit board,—is achieved, according to the present invention, by means of a device for contacting and/or electrostimulation of living tissue cells or nerves with having a printed circuit board having with at least one contact point for electrical contacting, the printed circuit board encompassing comprising a flexible multilayer system with at least one conductor track. In accordance with the invention, the contact points for the conductor track in the multilayer system are galvanically reinforced. To this end, a galvanically reinforced layer is grown onto the already preprocessed contact point, for example by means of a galvanic process.

Abstract: The present invention provides an electrode array for a medical implant device, comprising a substrate supporting a plurality of electrodes, the substrate comprising at least two layers of material including a first layer and a second layer, wherein the first layer of material and the second layer of material have different coefficients of thermal expansion. The plurality of electrodes may be supported on the first layer of material, and are preferably incorporated in and/or project from the second layer of material. The second layer of material may itself have a layered structure comprising multiple material layers, with the plurality of electrodes incorporated within the said multiple material layers. The first layer of material preferably has a higher coefficient of thermal expansion than the second layer of material. The invention furthermore provides a medical implant device including an electrode array according to the invention, and a method of manufacturing such an electrode array.

Abstract: The object,—to create a printed circuit board for an implant having improved properties in connection with the electrical contacting via the contact points of the conductor tracks on the printed circuit board,—is achieved, according to the present invention, by means of a device for contacting and/or electrostimulation of living tissue cells or nerves with having a printed circuit board having with at least one contact point for electrical contacting, the printed circuit board encompassing comprising a flexible multilayer system with at least one conductor track. In accordance with the invention, the contact points for the conductor track in the multilayer system are galvanically reinforced. To this end, a galvanically reinforced layer is grown onto the already preprocessed contact point, for example by means of a galvanic process.