Abstract: A system and method for controlling non-paresthesia stimulation of neural tissue of a patient. The method delivers a non-paresthesia stimulation waveform, senses sensory action potential (SAP) signals from the neural tissue of interest and analyzes the SAP signals to obtain SAP activity data for at least one of an SAP C-fiber component or an SAP A-delta fiber component. The method determines whether the SAP activity data satisfies a criteria of interest and adjusts at least one of the therapy parameters to change the non-paresthesia stimulation waveform when the SAP activity data does not satisfy the criteria of interest.

Abstract: A fully implantable trial neurostimulation system for implant within a patient is provided that includes one or more leads equipped to deliver neurostimulation to patient tissues under the control of a trial neurostimulation control device designed as a capsule for removable implant within the patient. The control capsule is provided with minimal components to power and control the delivery of neurostimulation during a trial evaluation period and is shaped and configured to facilitate removal from the patient following completion of the trial period. In some examples, both the lead and the trial control capsule are removed from the patient following the trial period for replacement with a chronic or long-term neurostimulation system (assuming further neurostimulation is warranted.) In other examples, the lead remains within the patient and the trial control capsule is replaced with a long-term neurostimulation controller device. Various minimally-intrusive implantation procedures are also described.

Abstract: A system and method for controlling non-paresthesia stimulation of neural tissue of a patient. The method delivers a non-paresthesia stimulation waveform, senses sensory action potential (SAP) signals from the neural tissue of interest and analyzes the SAP signals to obtain SAP activity data for at least one of an SAP C-fiber component or an SAP A-delta fiber component. The method determines whether the SAP activity data satisfies a criteria of interest and adjusts at least one of the therapy parameters to change the non-paresthesia stimulation waveform when the SAP activity data does not satisfy the criteria of interest.

Abstract: A system and method for controlling non-paresthesia stimulation of neural tissue of a patient. The method delivers a non-paresthesia stimulation waveform, senses sensory action potential (SAP) signals from the neural tissue of interest, and analyzes the SAP signals to obtain SAP activity data for at least one of an SAP C-fiber component or an SAP A-delta fiber component. The method determines whether the SAP activity data satisfies a criteria of interest and adjusts at least one of the therapy parameters to change the non-paresthesia stimulation waveform when the SAP activity data does not satisfy the criteria of interest.

Abstract: A system and method for controlling non-paresthesia stimulation of neural tissue of a patient. The method delivers a non-paresthesia stimulation waveform, senses sensory action potential (SAP) signals from the neural tissue of interest, and analyzes the SAP signals to obtain SAP activity data for at least one of an SAP C-fiber component or an SAP A-delta fiber component. The method determines whether the SAP activity data satisfies a criteria of interest and adjusts at least one of the therapy parameters to change the non-paresthesia stimulation waveform when the SAP activity data does not satisfy the criteria of interest.

Abstract: A system and method for controlling non-paresthesia stimulation of neural tissue of a patient. The method delivers a non-paresthesia stimulation waveform, senses sensory action potential (SAP) signals from the neural tissue of interest, and analyzes the SAP signals to obtain SAP activity data for at least one of an SAP C-fiber component or an SAP A-delta fiber component. The method determines whether the SAP activity data satisfies a criteria of interest and adjusts at least one of the therapy parameters to change the non-paresthesia stimulation waveform when the SAP activity data does not satisfy the criteria of interest.

Abstract: A system and method for controlling non-paresthesia stimulation of neural tissue of a patient. The method delivers a non-paresthesia stimulation waveform, senses sensory action potential (SAP) signals from the neural tissue of interest, and analyzes the SAP signals to obtain SAP activity data for at least one of an SAP C-fiber component or an SAP A-delta fiber component. The method determines whether the SAP activity data satisfies a criteria of interest and adjusts at least one of the therapy parameters to change the non-paresthesia stimulation waveform when the SAP activity data does not satisfy the criteria of interest.

Abstract: A system and method for controlling non-paresthesia stimulation of nervous tissue of a patient. The method delivers a non-paresthesia stimulation waveform, senses sensory action potential (SAP) signals from the nervous tissue of interest, and analyzes the SAP signals to obtain SAP activity data for at least one of an SAP C-fiber component or an SAP A-delta fiber component. The method determines whether the SAP activity data satisfies a criteria of interest and adjusts at least one of the therapy parameters to change the non-paresthesia stimulation waveform when the SAP activity data does not satisfy the criteria of interest.

Abstract: A wireless implantable system is provided that is externally powered and comprises of a closed-loop feedback for treating both patients with obstructive and central sleep apnea. A method is provided for treating sleep apnea using an implantable device. The method comprises sensing an inspiration (IN) signal representative of inspiration experienced by a patient from a respiratory surrogate signal and sensing a respiratory effort (RE) signal representative of an amount of effort exerted by the patient during respiration.

Abstract: A neurostimulation patch is affixed to a patient's skin (e.g., via a medical skin adhesive) and provides stimulation energy for an implanted lead. The patch may be used for SCS trials or other applications where is it desirable to avoid implanting a stimulation device within a patient. Circuitry in the patch generates stimulation signals and couples these signals to the implanted lead. The signals may be coupled to the lead via a direct physical connection or via a wireless connection. In some embodiments, the neurostimulation patch is configured in a manner that enables the patch to be placed immediately above the puncture site where an associated percutaneous lead passes through a patient's skin, thereby protecting the puncture site and facilitating secure routing of the lead.

Abstract: The present disclosure provides methods and systems for neurostimulation at the tract of Lissauer. A neurostimulation system includes an implantable pulse generator, and a lead assembly electrically coupled to the implantable pulse generator, the lead assembly including a plurality of sensing electrodes configured to sense pain signals at a tract of Lissauer of a subject, and a plurality of stimulating electrodes configured to apply stimulation to a dorsal column of the subject based on the sensed pain signals.

Abstract: A system and method are provided for controlling stimulation of nervous tissue of a patient. The method comprises delivering a stimulation waveform to at least one electrode located proximate to nervous tissue of interest, the stimulation waveform including a series of pulses configured to excite at least one of A-beta (A?) fibers, A-delta (A?) fibers or C-fibers of the nervous tissue of interest, the stimulation waveform defined by therapy parameters. The method also provides sensing an evoked compound action potential (ECAP) signal from the nervous tissue of interest. The method also analyzes a frequency content of the ECAP signal to obtain ECAP frequency data indicative of activity by at least one type of nerve fibers from a group comprising A?, A? and C fibers. The method also determines the type of nerve fibers that were activated by the stimulation waveform based on the ECAP frequency data.

Abstract: A system and method are provided for controlling stimulation of nervous tissue of a patient. The method comprises delivering a stimulation waveform to at least one electrode located proximate to nervous tissue of interest, the stimulation waveform including a series of pulses configured to excite at least one of A-beta (A?) fibers, A-delta (A?) fibers or C-fibers of the nervous tissue of interest, the stimulation waveform defined by therapy parameters. The method also provides sensing an evoked compound action potential (ECAP) signal from the nervous tissue of interest. The method also analyzes a frequency content of the ECAP signal to obtain ECAP frequency data indicative of activity by at least one type of nerve fibers from a group comprising A?, A? and C fibers. The method also determines the type of nerve fibers that were activated by the stimulation waveform based on the ECAP frequency data.

Abstract: A system and method for controlling non-paresthesia stimulation of nervous tissue of a patient. The method delivers a non-paresthesia stimulation waveform, senses sensory action potential (SAP) signals from the nervous tissue of interest, and analyzes the SAP signals to obtain SAP activity data for at least one of an SAP C-fiber component or an SAP A-delta fiber component. The method determines whether the SAP activity data satisfies a criteria of interest and adjusts at least one of the therapy parameters to change the non-paresthesia stimulation waveform when the SAP activity data does not satisfy the criteria of interest.

Abstract: A system and method for simultaneous burst and tonic stimulation of nerve tissue is provided. The system and method includes providing a lead with at least one stimulation electrode configured to be implanted at a target position proximate to nerve tissue of interest. The system and method further includes coupling the lead to an implantable pulse generator (IPG). The IPG generates current pulses that are delivered through blocking capacitors to the stimulation electrodes. The system and method further provides programming the IPG to deliver a first series of current pulses configured as a tonic stimulation waveform to the stimulation electrodes and to deliver a second series of current pulses configured as a burst stimulation waveform to the stimulation electrodes. The tonic and burst stimulation waveforms each include at least two current pulses with different amplitude polarities.

Abstract: A wireless implantable system is provided that is externally powered and comprises of a closed-loop feedback for treating both patients with obstructive and central sleep apnea. A method is provided for treating sleep apnea using an implantable device. The method comprises sensing an inspiration (IN) signal representative of inspiration experienced by a patient from a respiratory surrogate signal and sensing a respiratory effort (RE) signal representative of an amount of effort exerted by the patient during respiration.

Abstract: A neurostimulation lead including an elongated lead body having a distal end and a proximal base. The lead body may have an elastic property such that the lead body is capable of flexing between different geometries. The lead may also include electrodes positioned along the lead body. The lead body may be configured to be straightened into a substantially linear geometry for delivering the lead body into an epidural space and may be biased such that the lead body is configured to have a wave-like geometry when disposed within the epidural space. The lead body may form first and second lateral segments that are joined by a corresponding linking portion when in the wave-like geometry.

Abstract: A neurostimulation patch is affixed to a patient's skin (e.g., via a medical skin adhesive) and provides stimulation energy for an implanted lead. The patch may be used for SCS trials or other applications where is it desirable to avoid implanting a stimulation device within a patient. Circuitry in the patch generates stimulation signals and couples these signals to the implanted lead. The signals may be coupled to the lead via a direct physical connection or via a wireless connection. In some embodiments, the neurostimulation patch is configured in a manner that enables the patch to be placed immediately above the puncture site where an associated percutaneous lead passes through a patient's skin, thereby protecting the puncture site and facilitating secure routing of the lead.