Abstract: Automated assessment of neural response recordings involves storing a set of basis functions comprising at least one compound action potential basis function and at least one artefact basis function. Neural recordings of electrical activity in neural tissue are obtained by application of stimuli, using a single configuration of stimulation and recording. Each neural recording is decomposed by determining at least one parameter which estimates at least one of a compound action potential and an artefact. The at least one parameter is/are determined for each respective one of the plurality of neural recordings, to yield a plurality of values. A spread of the plurality of values is determined. An indication that the neural response recordings are of higher quality is output if the spread is small. An indication that the neural response recordings are of lower quality is output if the spread is large.

Abstract: This disclosure relates to implantable neuro stimulation devices with a feedback loop to control an amount of energy delivered into a neural tissue based on a measured evoked neural response. Stimulation electrodes deliver stimulation energy to neural tissue and a stimulator comprises a microprocessor and program memory with program code, which causes the microprocessor to perform closed-loop control of the stimulation energy based on a feedback signal that is indicative of an evoked neural response. A charge monitor monitors the delivery of energy to the stimulation electrodes by determining an amount of charge delivered by the stimulation electrodes and connected to the stimulator to provide a status signal indicative of the charge delivered to the stimulator. The device adjusts the control of the stimulation energy in response to the status signal from the charge monitor indicating undesirable charge delivery to the stimulation electrodes.

Abstract: This disclosure relates to implantable neuro stimulation devices with a feedback loop to control an amount of energy delivered into a neural tissue based on a measured evoked neural response. Stimulation electrodes deliver stimulation energy to neural tissue. A microprocessor performs closed-loop control of the stimulation energy based on a feedback signal that is indicative of an evoked neural response. A supervisor is connected to the feedback signal and detects malfunction of the stimulator based on the feedback signal. The supervisor is also connected to the stimulator to provide a status signal to the stimulator and changes the status signal to indicate malfunction upon detecting malfunction based on the feedback signal. The microprocessor adjusts the control of the stimulation energy in response to the status signal from the supervisor indicating malfunction.

Abstract: A neural stimulus comprises at least three stimulus components, each comprising at least one of a temporal stimulus phase and a spatial stimulus pole. A first stimulus component delivers a first charge which is unequal to a third charge delivered by a third stimulus component, and the first charge and third charge are selected so as to give rise to reduced artefact at recording electrodes. In turn this may be exploited to independently control a correlation delay of a vector detector and an artefact vector to be non-parallel or orthogonal.

Abstract: The invention is a distributed implantable neuro-stimulation system, comprising an implant controller including control logic to transmit two time-varying power signals, varying between two levels and out of phase with the other, and a command signal modulated onto at least one of the power signals. One or more electrode cells, each having control logic to extract charge from the power signals and recover commands from the command signal. A two-wire bus interconnecting the implant controller and all the electrode cells, to carry one of the time varying signals in each of the two wires, and to carry the command signal.

Abstract: A distributed implantable neurostimulation system. One or more electrode arrays each have at least one electrode configured to be positioned at a desired implant location within the body. An implantable control unit is configured to selectively direct stimulus and/or telemetry instructions and power to each electrode of each array. A shared bus extends to each of the plurality of electrode arrays, the bus interconnecting each array with the implantable control unit. There is at least one electrode cell associated with each electrode array. The electrode cell obtains electrical power and command signals from the shared bus, and controls operation of each electrode associated with that electrode cell. The bus is connected to the control unit and/or the electrode cell by docking contacts of the bus to form electrical contact with contacts of the control unit and/or electrode cell.

Abstract: The invention is a distributed implantable neuro-stimulation system, comprising an implant controller including control logic to transmit two time-varying power signals, varying between two levels and out of phase with the other, and a command signal modulated onto at least one of the power signals. One or more electrode cells, each having control logic to extract charge from the power signals and recover commands from the command signal. A two-wire bus interconnecting the implant controller and all the electrode cells, to carry one of the time varying signals in each of the two wires, and to carry the command signal.