Devices, systems, and techniques for controlling electrical stimulation therapy are described. In one example, a system may be configured to deliver electrical stimulation therapy to a patient, the electrical stimulation therapy comprising a plurality of therapy pulses at a predetermined pulse frequency over a period of time and deliver, over the period of time, a plurality of control pulses interleaved with at least some therapy pulses of the plurality of therapy pulses. The system may also be configured to sense, after one or more control pulses and prior to an immediately subsequent therapy pulse of the plurality of therapy pulses, a respective evoked compound action potential (ECAP), adjust, based on at least one respective ECAP, one or more parameter values that at least partially defines the plurality of therapy pulses, and deliver the electrical stimulation therapy to the patient according to the adjusted one or more parameter values.

Provided is a system and method for cavernosal neuromodulation as directed by a wireless remote controller and power supply. The system including: an implantable lead having at least one electrode structured and arranged to be disposed proximate to the cavernous nerve in a penis; a portable power supply; and a controller having wireless communication electronics and control circuitry associated with the wireless communication electronics structured and arranged to wirelessly couple the power supply to the at least one electrode, the controller further structured and arranged to permit a user to select at least one instruction set for the at least electrode. The controller and power supply may be provided by a control ring. An associated method of use is also provided.

Devices, systems, and methods for coupling with an implantable neurostimulator for delivering one or more electrical pulses to a target region within a patient's body are disclosed herein. A device, such as a charger, can include: a power source for storing electrical energy; a resonant circuit that can have a plurality of selectable natural frequencies; a driver coupled to the power source and the resonant circuit; and a processor coupled to the resonant circuit to control the natural frequency of the resonant circuit. The processor can determine the natural frequency of the implantable neurostimulator, and can control the resonant circuit according to the determined natural frequency of the neurostimulator.

Methods and devices for improving pelvic floor dysfunction in a patient suffering therefrom by electrically modulating neural tissue in a minimally invasive fashion using an electrical micro stimulator are provided.

A system may receive first information relating to a patient captured during a baseline period that is prior to the patient receiving stimulation. The system may receive second information relating to the patient captured during an initial therapy assignment. The second information may include testing data generated by delivering stimulation during an implant procedure. The system may determine initial stimulation program settings based on the first information, the second information and population-informed information. The population-informed information may be related to other patients. The system may cause, during a training period, delivery of therapy based on the initial stimulation program settings.

An implantable stimulation system having an implantable stimulation unit coupled to a programmable controller, a stimulation circuit and an array of electrodes disposed on a pair of flexible paddles is provided for selectively stimulating at least one cavernous nerve. The programmable controller is pre-programmed to run an excitation electrode routine that selectively scans the electrode arrays on the paddles with a series of directional current flows, in at least two directions and within at least two regions, to optimize electrode selection for use in stimulating the cavernous nerve. The implantable stimulation system may be programmed to run a first stimulation pulse sequence corresponding to a first mode for invoking a rapid erectile response, and optionally, a second nerve rehabilitation stimulation mode selected to rehabilitate neural transmission in a cavernous nerve, and/or a third penile rehabilitation mode selected to reduce penile fibrosis. Methods of operating the system also are provided.

An implantable stimulation system having an implantable stimulation unit coupled to a programmable controller, a stimulation circuit and an array of electrodes disposed on a pair of flexible paddles is provided for selectively stimulating at least one cavernous nerve. The programmable controller is pre-programmed to run an excitation electrode routine that selectively scans the electrode arrays on the paddles with a series of directional current flows, in at least two directions and within at least two regions, to optimize electrode selection for use in stimulating the cavernous nerve. The implantable stimulation system may be programmed to run a first stimulation pulse sequence corresponding to a first mode for invoking a rapid erectile response, and optionally, a second nerve rehabilitation stimulation mode selected to rehabilitate neural transmission in a cavernous nerve, and/or a third penile rehabilitation mode selected to reduce penile fibrosis. Methods of operating the system also are provided.

The present disclosure involves systems and methods of programming electrical stimulation therapy for a patient. A communications link is established with a pulse generator that is configured to generate electrical stimulation pulses. An intermittent electrical coupling between the pulse generator and a diagnostic tool is simulated. This simulation is performed by instructing, for a plurality of cycles, the pulse generator to automatically turn on and off the generation of electrical stimulation pulses. Each cycle includes a first time period and a second time period following the first time period. The simulating includes: instructing the pulse generator to generate the electrical stimulation pulses during the first time period; and instructing the pulse generator to stop generating the electrical stimulation pulses during the second time period.

A non-zero starting value for ramping up a stimulation parameter for an electrical stimulation to be delivered to a patient is determined. The non-zero starting value is customized to the patient. A pulse generator is caused to generate the electrical stimulation, which is delivered to the patient via an implanted lead. The pulse generator is caused to ramp up, from the determined non-zero starting value and toward a predefined maximum limit value, the stimulation parameter for a plurality of electrode contacts on the lead. Feedback is received from the patient in response to the ramping up. The feedback is received via an electronic patient feedback device. Based on the ramping up and the received feedback from the patient, a perception threshold is determined for each of the plurality of electrode contacts. The perception threshold is a value of the stimulation parameter that corresponds to the patient feeling the electrical stimulation.

Techniques for delivering electrical stimulation therapy comprising a complex variation to at least one electrical stimulation parameter are described. In one example, processing circuitry of an implantable medical device (IMD) identifies a plurality of electrical stimulation parameters for at least one pulse train of electrical stimulation. The processing circuitry defines a complex variation to at least one electrical stimulation parameter of the plurality of electrical stimulation parameters. The processing circuitry modifies the at least one pulse train of electrical stimulation by introducing the complex variation to the electrical stimulation parameter function and controls a stimulation generator of the IMD to generate, as modified, the at least one pulse train of electrical stimulation.