Abstract: A device, including an implantable electronic circuit integrated at least one of in or on a substrate, wherein the device includes a hermetic enclosure having a space therein, wherein the substrate forms at least a portion of the hermetic enclosure.

Abstract: The present invention relates to a method and apparatus for facilitating artificial vision using retinal electrical neuro-stimulation. Retinal ganglion cells are stimulated at two different sites in order to elicit better visual percepts. Primary stimulation is implemented at first site on the retina. Secondary stimulation is applied in the vicinity of the optic disc or optic nerve. The secondary stimulation modulates the signals elicited by the primary stimulation.

Abstract: A system and method are described for stimulating excitable tissue. The system includes a monopolar stimulation source that generates a sub-threshold field in the vicinity of the excitable tissue, the sub-threshold field being below a threshold at which activation of the excitable tissue occurs. One or more local stimulation sources generate a local field, which in combination with the sub-threshold field exceeds the threshold of the excitable tissue.

Abstract: The present invention relates to a neural prosthesis. In its most general form, the neural prosthesis comprises an electrode array including a stimulating electrode (801) and a bipolar return electrode (802). The neural prosthesis also comprises a monopolar return electrode (806), a first electrical return path (812) associated with the bipolar return electrode (802) and a second electrical return path (814) associated with the monopolar return electrode (806) wherein, in use, the stimulating electrode (801) provides a stimulating current to the tissue of a recipient and a total return current is divided between a first current in the first electrical return path (812) and a second current in the second electrical return path (814).

Abstract: A device, including an implantable electronic circuit integrated at least one of in or on a substrate, wherein the device includes a hermetic enclosure having a space therein, wherein the substrate forms at least a portion of the hermetic enclosure.

Abstract: A device, including an implantable electronic circuit integrated at least one of in or on a substrate, wherein the device includes a hermetic enclosure having a space therein, wherein the substrate forms at least a portion of the hermetic enclosure.

Abstract: A method of neural stimulation is described for maintaining the responsiveness of electrically excitable cells to repeated electrical stimulation. A stimulating signal (23) is applied to the electrically excitable cells. The stimulating signal is repeatedly applied (26, 29, 32, 35) with a progressively increasing signal strength. A quiescent period (44) may be interleaved between bursts (43, 45) of stimulation. The electrically excitable cells may be retinal cells.

Abstract: A system and method are described for stimulating excitable tissue. The system includes a monopolar stimulation source that generates a sub-threshold field in the vicinity of the excitable tissue, the sub-threshold field being below a threshold at which activation of the excitable tissue occurs. One or more local stimulation sources generate a local field, which in combination with the sub-threshold field exceeds the threshold of the excitable tissue.

Abstract: A system for transferring data and power between electronic devices implanted in a patient is described. The system comprises a first unit and a second unit that in use are both implanted in the patient and a cable connecting the first unit and the second unit. The first unit comprises a current supply unit that supplies a selected current output to the second unit via the cable and a processor configured to anticipate an action to be performed by the second unit and to select the current output dependent on the anticipated action.

Abstract: A device, including an implantable electronic circuit integrated at least one of in or on a substrate, wherein the device includes a hermetic enclosure having a space therein, wherein the substrate forms at least a portion of the hermetic enclosure.

Abstract: The present invention relates to a neural prosthesis. In its most general form, the neural prosthesis comprises an electrode array including a stimulating electrode (801) and a bipolar return electrode (802). The neural prosthesis also comprises a monopolar return electrode (806), a first electrical return path (812) associated with the bipolar return electrode (802) and a second electrical return path (814) associated with the monopolar return electrode (806) wherein, in use, the stimulating electrode (801) provides a stimulating current to the tissue of a recipient and a total return current is divided between a first current in the first electrical return path (812) and a second current in the second electrical return path (814).

Abstract: A method is disclosed for efficient multiplexing of a plurality of electrodes in a nerve stimulator using improved, predetermined, regular, repeatable geometric patterns arranged in a predetermined mosaic to form a desired array. Multiple electrodes within said array are addressed by the nerve stimulator as being a stimulating electrode by an instruction specifying a single identifier, indicating a position within each regular geometric pattern. As such, each electrode within the array, maintaining the specified position within its respective repeatable geometric pattern, becomes a stimulating electrode and is connected to the appropriate electronic circuit for subsequent, potential use in nerve stimulation.

Abstract: A method of neural stimulation is described for maintaining the responsiveness of electrically excitable cells to repeated electrical stimulation. A stimulating signal (23) is applied to the electrically excitable cells. The stimulating signal is repeatedly applied (26, 29, 32, 35) with a progressively increasing signal strength. A quiescent period (44) may be interleaved between bursts (43, 45) of stimulation. The electrically excitable cells may be retinal cells.

Abstract: A system for transferring data and power between electronic devices implanted in a patient is described. The system comprises a first unit and a second unit that in use are both implanted in the patient and a cable connecting the first unit and the second unit. The first unit comprises a current supply unit that supplies a selected current output to the second unit via the cable and a processor configured to anticipate an action to be performed by the second unit and to select the current output dependent on the anticipated action.

Abstract: A method is disclosed for the fabrication of feedthrough devices that can transmit a single or plurality of electrical signal(s) to or from within a leak-tight (hermetic) chamber from or to the outside of said leak-tight (hermetic) chamber. The invention allows materials known to be well-tolerated within the human body such as alumina-oxide ceramic and platinum to be used as raw materials in the fabrication of body-compatible, single or multi-channel leak-tight (hermetic) feedthroughs.

Abstract: A method is disclosed for efficient multiplexing of a plurality of electrodes in a nerve stimulator using improved, predetermined, regular, repeatable geometric patterns arranged in a predetermined mosaic to form a desired array. Multiple electrodes within said array are addressed by the nerve stimulator as being a stimulating electrode by an instruction specifying a single identifier, indicating a position within each regular geometric pattern. As such, each electrode within the array, maintaining the specified position within its respective repeatable geometric pattern, becomes a stimulating electrode and is connected to the appropriate electronic circuit for subsequent, potential use in nerve stimulation.

Abstract: An apparatus facilitating the delivery of electrical stimulation to physiologically excitable retinal nerve cells includes: (a), a receiver/decoder/stimulator comprising a semiconductor integrated circuit and other components hermetically sealed within a capsule, implanted and fixed within the eye of the patient such that it may receive power, and decode information from (b), an externally worn image processor/encoder/transmitter comprising an image detector, an image processor capable of translating the image into an array of discreet pixels of varying intensity, encoding the pixel information into a series of discreet data bursts representing the chosen current amplitude, pulse duration, stimulating electrode or electrodes, and reference electrode or electrodes, and transmitting this data to the receiver/decoder/stimulator through a tuned, inductive communication link such that the system may deliver controlled, charge balanced, diphasic, constant current stimulus pulses to (c), discreet metallic electrodes