Abstract: A system for a neurostimulator coupled to electrodes, and a method of providing therapy to a patient using the electrodes implanted within the patient. A target multipole relative to the electrodes is defined. The target multipole is emulated by defining an initial electrical current distribution for the electrodes, such that a first set of active electrodes respectively has electrical current values of a first polarity. Each of the electrical current values of the first polarity is compared to a first threshold value, and at least one of the electrodes in the first active electrode set is zeroed-out based on the comparison. The electrical current value of each of the zeroed-out electrode(s) is redistributed to remaining ones of the electrodes to define a new electrical current distribution for the electrodes. Electrical current is conveyed to the electrodes in accordance with the new electrical current distribution, thereby providing the therapy.

Abstract: An external control device for use with a neurostimulation system having a plurality of electrodes capable of conveying an electrical stimulation field into tissue in which the electrodes are implanted is provided. The external control device comprises a user interface having one or more control elements, a processor configured for generating stimulation parameters designed to modify the electrical stimulation field relative to one or more neurostimulation lead carrying the electrodes. The external control device further comprises output circuitry configured for transmitting the stimulation parameters to the neurostimulation system.

Abstract: Systems and methods are disclosed in which an external device such as a consumer mobile device (e.g., smart phone) is used as an external controller to bi-directionally communicate with an Implantable Medical Device (IMD) using a dedicated patient remote control (RC) as an intermediary device to translate communications between the two. The dedicated RC contains a graphical user interface allowing for control and monitoring of the IMD even if the mobile device is not present in the system, which is useful as a back-up should the mobile device experience problems. Use of the dedicated RC as an intermediary device broadens the utility of other computing devices to operate as an external controller for an IMD even if the computing device and IMD do not have compliant communication means.

Abstract: A neuromodulation customization system includes a field definition user interface, a neuromodulation signaling engine, and a supervisor engine. The field definition user interface is to facilitate entry of a customized electrotherapy field definition, with the field definition user interface including a set of input controls for defining field shape, field intensity, and field steering parameters of the customized electrotherapy field. The neuromodulation signaling engine is to produce commands for neuromodulation output circuitry to control generation of a customized electrotherapy field via a set of electrodes based on the customized electrotherapy field definition. The supervisor engine is to assess compliance of the customized electrotherapy field to be generated with applicable predefined criteria, and to modify generation of the customized electrotherapy field in response to an assessed non-compliance with the criteria.

Abstract: A device for use with a stimulation system comprises a user interface for receiving input from a user, displaying graphical parameter objects respectively corresponding to stimulation parameter sets, and displaying graphical program objects corresponding to stimulation programs. The device further comprises a controller/processor for selecting a graphical parameter object, dragging the graphical parameter object, dropping the graphical parameter object into a graphical program object, and storing the stimulation parameter set corresponding to the graphical parameter object in association with the stimulation program corresponding to the graphical program object. The user interface may further display graphical program objects corresponding to stimulation programs, and a graphical schedule object.

Abstract: An external control device for use with a neurostimulator coupled to a plurality of electrodes capable of conveying electrical stimulation energy into tissue in which the electrodes are implanted. The external control device comprises a user interface configured for receiving direct input from a user specifying a target value for a target electrode. The user interface includes a display screen configured for displaying graphical representations of the electrodes. The user interface comprises a controller/processor configured for, in response to the direct user input, assigning a new stimulation amplitude value to the target electrode, and output circuitry configured for transmitting the new stimulation amplitude value to the neurostimulator.

Abstract: An example of a system may include an electrode arrangement, a neural modulation generator configured to use electrodes in the electrode arrangement to generate a modulation field, a communication module configured to receive commands, a memory configured to store modulation field parameter data, and a controller configured to control the neural modulation generator to generate the modulation field. The controller may be configured to implement a trolling routine to troll the modulation field through neural tissue positions, and implement a marking routine multiple times as the modulation field is trolled through the neural tissue positions to identify when the modulation field provides patient-perceived modulation.

Abstract: An example of a system for delivering neurostimulation pulses to a patient using a plurality of electrodes and controlling the delivery of the neurostimulation pulses by a user may include a programming control circuit and a user interface. The programming control circuit may be configured to generate a plurality of stimulation parameters controlling delivery of neurostimulation pulses according to one or more stimulation waveforms. The interface may include a display screen and an interface control circuit. The interface control circuit may be configured to define the one or more stimulation waveforms, and may include an impedance presentation module. The impedance presentation module may be configured to determine values of impedances each between two electrodes of the plurality of electrodes for all of combinations of two electrodes available from the plurality of electrodes and display the determined values of impedances on the display screen.

Abstract: A system for a neurostimulator coupled to electrodes, and a method of providing therapy to a patient using the electrodes implanted within the patient. A target multipole relative to the electrodes is defined. The target multipole is emulated by defining an initial electrical current distribution for the electrodes, such that a first set of active electrodes respectively has electrical current values of a first polarity. Each of the electrical current values of the first polarity is compared to a first threshold value, and at least one of the electrodes in the first active electrode set is zeroed-out based on the comparison. The electrical current value of each of the zeroed-out electrode(s) is redistributed to remaining ones of the electrodes to define a new electrical current distribution for the electrodes. Electrical current is conveyed to the electrodes in accordance with the new electrical current distribution, thereby providing the therapy.

Abstract: 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.

Abstract: An example of a system may include an arrangement of electrodes configured to be operationally positioned for use in modulating targeted neural tissue, a neural modulator, a communication module, and a controller. The neural modulator may be configured to use at least some electrodes within the arrangement of electrodes to generate a modulation field. The communication module may be configured to receive user-provided selections. The controller may be configured to use the communication module to receive a user-provided selection of a desired electrode list where the electrode list identifies electrodes within the arrangement of electrodes that are available for use in modulating the targeted neural tissue, control the neural stimulation modulator to generate the modulation field, and use the electrodes identified in the electrode list to modulate the targeted neural tissue.

Abstract: An external control device for use with a neurostimulator coupled to electrodes. The external control device comprises a user interface configured for receiving input from a user, and including a display screen configured for displaying graphical representations of the electrodes. The external control device further comprises a controller/processor configured for, in response to the input from the user, linking a subset of the electrodes together, and globally assigning at least one of the same stimulation amplitude value and same on/off state to each of the electrodes. The controller/processor may also be configured for, in response to the input from the user, assigning at least one stimulation parameter value to one of the electrodes, copying/cutting the at least one stimulation parameter value from the one electrode, and pasting the at least one stimulation parameter value to the other electrode and modifying current values of other electrodes to maintain 100% current.

Abstract: An external control device, a neurostimulation system, and a method for providing therapy to a patient are provided. A plurality of stimulation parameter sets are defined, electrical stimulation energy is serially conveyed to tissue of the patient in accordance with the plurality of stimulation parameter sets, a historical log file is stored, and the plurality of stimulation parameter sets are logged in the historical log file.

Abstract: A filtering algorithm implemented by a filtering module in an implantable medical device (IMD), or in an external device for communicating with an IMD, is disclosed which reviews blocks based on a number of rules. The filtering module preferably comprises both firewall and instruction analysis modules. The instruction analysis module analyzes the instructions and associated data (if present) in each block to determine whether such blocks would compromise operation of the IPG or injure a patient if executed. Instruction rules corresponding to an instruction identified in the block are retrieved by the instruction analysis module. The instruction analysis module reviews the block per the retrieved rules, and possibly also in light of current and historical IPG therapy setting or mode data, or other received but un-executed blocks. If a block is compliant, it is executed by the IMD or transmitted to the IMD.

Abstract: An example of a system for delivering neurostimulation may include a programming control circuit and a user interface. The programming control circuit may be configured to generate stimulation parameters controlling delivery of neurostimulation pulses according to one or more stimulation waveforms associated with areas of stimulation each defined by a set of electrodes. The neurostimulation pulses are each delivered to an area of stimulation. The user interface may include a display screen and an interface control circuit. The interface control circuit may be configured to define the one or more stimulation waveforms and the areas of stimulation, and may include a stimulation frequency module configured to display a stimulation rate table on the display screen. The stimulation rate table may present stimulation frequencies associated with each of the areas of stimulation for selection by a user.

Abstract: An example of a system may include an electrode arrangement, a neural modulation generator configured to use electrodes in the electrode arrangement to generate a modulation field, a communication module configured to receive commands, a memory configured to store modulation field parameter data, and a controller configured to control the neural modulation generator to generate the modulation field. The controller may be configured to implement a trolling routine to troll the modulation field through neural tissue positions, and implement a marking routine multiple times as the modulation field is trolled through the neural tissue positions to identify when the modulation field provides patient-perceived modulation.

Abstract: 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.

Abstract: A filtering algorithm implemented by a filtering module in an implantable medical device (IMD), or in an external device for communicating with an IMD, is disclosed which reviews blocks based on a number of rules. The filtering module preferably comprises both firewall and instruction analysis modules. The instruction analysis module analyzes the instructions and associated data (if present) in each block to determine whether such blocks would compromise operation of the IPG or injure a patient if executed. Instruction rules corresponding to an instruction identified in the block are retrieved by the instruction analysis module. The instruction analysis module reviews the block per the retrieved rules, and possibly also in light of current and historical IPG therapy setting or mode data, or other received but un-executed blocks. If a block is compliant, it is executed by the IMD or transmitted to the IMD.

Abstract: An electrical neuromodulation system configured for minimizing energy consumption of a neuromodulation device includes an external control device configured for receiving input from a user, the neuromodulation device in communication with the external control device, and control/processing circuitry. The control/processing circuitry is configured for automatically (a) adjusting a modulation parameter value (e.g., by a step size) to create a currently adjusted modulation parameter value that decreases the energy consumption of the neuromodulation device, (b) instructing the neuromodulation device to deliver electrical energy to at least one electrode in accordance with the currently adjusted modulation parameter value, (c) determining whether a manual parameter adjustment was made by the user in response to step (b), and (d) if the manual parameter adjustment was not made, deeming the currently adjusted modulation parameter value as a previously adjusted modulation parameter value and repeating steps (a)-(d).

Abstract: External control devices, neurostimulation systems, and programming methods. A neurostimulator includes a feature having a numerical range. Information identifying a type of the neurostimulator is transmitted to an external control device. The external control device receives the information from the neurostimulator, identifies the type of the neurostimulator based on the received information, and programs the neurostimulator in accordance with the numerical range of the feature corresponding to the identified type of the neurostimulator.