Systems and methods for providing a trial neurostimulation to a patient for assesssing suitability of a permanently implanted neurostimulation are provided herein. In one aspect, a trial neurostimulation system includes an EPG patch adhered to a skin surface of a patient and connected to a lead extending through a percutaneous incision to a target tissue location. The EPG may be a modified version of the IPG used in the permanent system, the EPG may be smaller and/or lighter than the corresponding IPG device. The EPG and a lead extension may be sealed to allow improved patient mobility and reduced risk of infection. The EPG may be compatible with wireless systems used to control and monitor the IPG such that operation and control of the EPG is substantially the same in each system to allow seemless conversion to the permanently implanted system.

The present invention provides improved methods for positioning of an implantable lead in a patient with an integrated EMG and stimulation clinician programmer. The integrated clinician programmer is coupled to the implantable lead, wherein the implantable lead comprises at least four electrodes, and to at least one EMG sensing electrode minimally invasively positioned on a skin surface or within the patient. The method comprises delivering a test stimulation at a stimulation amplitude level from the integrated clinician programmer to a nerve tissue of the patient with a principal electrode of the implantable lead. Test stimulations are delivered at a same stimulation amplitude level for a same period of time sequentially to each of the four electrodes of the implantable lead. A stimulation-induced EMG motor response is recorded with the integrated clinician programmer for each test stimulation on each electrode of the implantable lead via the at least one pair of EMG sensing electrodes so as to facilitate initial positioning of the implantable lead at a target stimulation region.

Methods and apparatuses for monitoring and regulating physiological states and functions are disclosed. Several embodiments include application of one or more microelectrode arrays to a dorsal root ganglion for measurement of sensory neuron activity, or stimulation of sensory reflex circuits. The methods and apparatuses can be used, for example, for monitoring or controlling bladder function in a patient.

An example method includes delivering one or more electrical stimulation signals to a patient, sensing a composite stimulation-evoked signal comprising a composite of signals generated by one or more signal sources in response to the one or more electrical stimulation signals, and controlling delivery of electrical stimulation therapy to the patient based on the composite stimulation-evoked signal.

The present invention relates to a preoperative test method, to an implantation system (20) and to an implantation method for implanting a neuroprosthesis in the area of the pubic bone (31), wherein implantation is ultimately simplified and made more effective directly or indirectly by the subject-matters of the invention.

A method for implanting a stimulator for genital nerves stimulation, including approaching the genital nerves of a patient, defined as the dorsal nerve of the penis/clitoris (DNP), the cavernous nerve (CN) or both the DNP and CN, ventrally by way of the retropubic space to implant a stimulator to contact the genital nerves in this location; and controlling the stimulator to influence at least one of the genital nerves.

This disclosure describes systems, devices, and techniques for adjusting an anatomical atlas to patient anatomy. In one example, a system may include processing circuitry configured to generate, for display at a user interface, a representation of an anatomical region of a patient, generate, for display at the user interface, a representation of one or more atlas-defined anatomical structures at a first position over the representation of the anatomical region of the patient, receive a user annotation that defines an adjustment to at least one atlas-defined anatomical structure relative to the representation of the anatomical region of the patient, and adjust, based on the adjustment, the first position of the representation of the one or more atlas-defined anatomical structures to a second position of the representation of the one or more atlas-defined anatomical structures over the representation of the anatomical region of the patient.

Nerve stimulation systems and methods are disclosed for providing modulation of nerve targets in the lower limbs typically at or below the knee. For example, transcutaneous electrical nerve stimulation (TENS), percutaneous nerve stimulation, and implantable stimulation systems and methods are disclosed for providing stimulation to the saphenous nerve (SAFN). Additionally, systems and methods are provided for co-stimulating the posterior tibial nerve (PTN) and SAFN in combination with unique stimulation, and with control and display of OAB therapy protocols for multiple sites. Systems and methods of treatment can provide for management of usage and compliance monitoring, obtain and operating upon patient input responses to queries and management of payments and permissions related to provision of therapies for various disorders. Monitoring of usage and compliance can be managed both locally and remotely from a user. Stimulation provided in combination with a passive implantable component is also disclosed.

In certain variations, systems and/or methods for electromagnetic induction therapy are provided. One or more ergonomic or body contoured applicators may be included. The applicators include one or more conductive coils configured to generate an electromagnetic or magnetic field focused on a target nerve, muscle or other body tissues positioned in proximity to the coil. One or more sensors may be utilized to detect stimulation and to provide feedback about the efficacy of the applied electromagnetic induction therapy. A controller may be adjustable to vary a current through a coil to adjust the magnetic field focused upon the target nerve, muscle or other body tissues based on the feedback provide by a sensor or by a patient. In certain systems or methods, pulsed magnetic fields may be intermittently applied to a target nerve, muscle or tissue without causing habituation.

Devices and methods for providing neurostimulation to a patient, particularly in trial systems assessing suitability of a permanently implanted neurostimulation. Such trial systems can utilize a trial neurostimulation lead that includes a coiled conductor coupled to a proximal contact connector that is coupled with an external pulse generator. The trial neurostimulation lead can be a coiled conductor of a closed wound configuration that can be stretched to form an open coil portion or gaps between adjacent coils to provide more resistance to migration or regression of the lead.