A pulse current generation circuit (100) for neural stimulation includes an analogue signal receiving device (101) for receiving an analogue signal; an analogue-to-digital converter (102) for converting the analogue signal into a digital control signal; a current signal controller (103) for producing, according to the digital control signal, pulse current parameters for generating bidirectional pulse current signals; and a current generator (104) for generating, according to the pulse current parameters, bidirectional pulse current signals for neural stimulation, and the current generator can generate pulse currents of different precisions according to the pulse current parameters. In addition, the present invention further relates to a charge compensation circuit, a charge compensation method, and an implantable electrical retina stimulator using the pulse current generation circuit or the charge compensation circuit.

The present disclosure relates to a monolithic thin-film lead assembly and methods of microfabricating a monolithic thin-film lead assembly. Particularly, aspects of the present disclosure are directed to a monolithic thin-film lead assembly that includes a cable having a proximal end, a distal end, a supporting structure that extends from the proximal end to the distal end, and a plurality of conductive traces formed on a portion of the supporting structure. The supporting structure includes one or more layers of dielectric material. The monolithic thin-film lead assembly may further include an electrode assembly formed on the supporting structure at the distal end of the cable. The electrode assembly includes one or more electrodes in electrical connection with one or more conductive traces of the plurality of conductive traces.

A three-dimensional annular electrode array (AEA) device is disclosed for use as a cybernetic neural interface for the neural control and sensory feedback of a bionic prosthetic device. The AEA, designed for implantation into a nerve, is comprised of a body (6) that can be coupled to a sleeve(s) (9, 10) or a sleeve(s) with a compartmentalized inner core (12) for connection to the proximal and distal ends of a transected nerve, respectively. Regenerating nerve axons capture and sequester laterally projecting electrode terminals (4) arranged in radiating clusters (5) of a plurality of electrode sub-array nodes (2) that make up the array; connected by a primary electrode lead (7) to a connector contact array (3) in a plurality of connectors (1) for connection to wired or wireless electromechanical systems.

The present disclosure provides systems and methods for generating waveforms for an implantable pulse generator of a neurostimulation system. A waveform generation system includes a computing device, at least one buffer memory, and at least one programmable current regulator. The at least one buffer memory is coupled between the computing device and the at least one programmable current regulator. The computing device is configured to load a string of output current values into the at least one buffer memory, and the at least one buffer memory is configured to sequentially feed each output current value to the at least one programmable current regulator. Further, the at least one programmable current regulator is configured to control current supplied to a plurality of electrodes based on the received output current values.

A method of treating osteoarthritis includes an implantable stimulator generating stimulation sessions at a duty cycle that is less than 0.05 and applying the stimulation sessions by way of the central electrode and the annular electrode to a location within a patient that includes at least one of an acupoint labeled ST35, an acupoint labeled EX-LE-4, or a location on a line that intersects the acupoints labeled ST35 and EX-LE-4.

An implantable electroacupuncture device (IEAD) treats Parkinson's disease or Essential Tremor through application of stimulation pulses applied to at least one of the acupoints on the chorea line. The IEAD includes an hermetically-sealed implantable electroacupuncture (EA) device and a conduit extending therefrom. At least one electrode is located on the outside of the housing. At least one electrode is located at an opening formed through the conduit. The housing contains a primary power source and pulse generation circuitry. A sensor wirelessly senses externally-generated operating commands, such as ON, OFF and AMPLITUDE. The pulse generation circuitry generates stimulation pulses. The stimulation pulses are applied to the specified acupoint or nerve through the electrodes in accordance with a specified stimulation regimen.

A current generation architecture for an implantable stimulator device such as an Implantable Pulse Generator (IPG) is disclosed. Current source and sink circuitry are both divided into coarse and fine portions, which respectively can provide coarse and fine current resolutions to a specified electrode on the IPG. The coarse portion is distributed across all of the electrodes and so can source or sink current to any of the electrodes. The coarse portion is divided into a plurality of stages, each of which is capable via an associated switch bank of sourcing or sinking a coarse amount of current to or from any one of the electrodes on the device. The fine portion of the current generation circuit preferably includes source and sink circuitry dedicated to each of the electrode on the device, which can comprise digital-to-analog current converters (DACs).

There is disclosed a device and method for delivering constant target current to a muscle for electro-stimulation of that muscle. One device is a completely self-contained device with no external means for the adjustment and control of the electro-stimulation delivered to the muscle during treatment. The microprocessor based device monitors indirectly the actual current delivered to the muscle during electro-stimulation via measurement of the return path voltage through the muscle and optionally in addition monitors and adjusts for the internal battery voltage during use of the device in order to deliver a more consistent an accurate and effective target output current to the muscle being stimulated at each and every pulse delivered from the device. The device is pre-programmed with an electro-stimulation treatment cycle and the whole treatment cycle, including the monitoring and adjustment required to achieve this treatment cycle, is automatic within the device.

An example of a neurostimulation system may include a storage device, a programming control circuit, and a graphical user interface (GUI). The storage device may be configured to store individually definable waveforms. The programming control circuit may be configured to generate stimulation parameters controlling the delivery of the neurostimulation pulses according to a pattern. The GUI may be configured to define the pattern using one or more waveforms selected from the individually definable waveforms. The GUI may display waveform tags each selectable for access to a waveform of the individually definable waveforms, and display a waveform builder in response to selection of one of the waveform tags. The waveform builder may present a graphical representation of the accessed waveform and allow for the accessed waveform to be adjusted by editing the graphical representation of the accessed waveform on the GUI.

In illustrative implementations of this invention, interferential stimulation is precisely directed to arbitrary regions in a brain. The target region is not limited to the area immediately beneath the electrodes, but may be any superficial, mid-depth or deep brain structure. Targeting is achieved by positioning the region of maximum envelope amplitude so that it is located at the targeted tissue. Leakage between current channels is greatly reduced by making at least one of the current channels anti-phasic: that is, the electrode pair of at least one of the current channels has a phase difference between the two electrodes that is substantially equal to 180 degrees. Pairs of stimulating electrodes are positioned side-by-side, rather than in a conventional crisscross pattern, and thus produce only one region of maximum envelope amplitude. Typically, current sources are used to drive the interferential currents.