A medical device stores a set of stimulation profiles, wherein each stimulation profile of the set of stimulation profiles is associated with a set of values for stimulation parameters; selects from the set of stimulation profiles, one or more active stimulation profiles; produces, by a stimulation generator, multiple electrical pulses based on the one or more active stimulation profiles; and separately controls parameter values of respective individual pulses of the multiple pulses.

Devices and methods for manipulating devices such as micro-scale devices are provided. The devices can include a tether of various materials surrounded by a stiff body. The tether interfaces with microscale devices to draw them against the stiff body, holding the microscale devices in a locked position for insertion into or extraction out of tissue. The tensional hook and stiff body are configurable in a multitude of positions and geometries to provide increased engagement. Such configurations allow for a range of implantation and extraction surgical procedures for the device within research and clinical settings.

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.

A method to treat a patient having a pelvic floor dysfunction by establishing a neurostimulator having a processor and a signal generator to generate a stimulation signal. The processor is set to one or more parameters effective in the treating of the patient's pelvic dysfunction when the stimulation signal is applied to a saphenous nerve of the patient. The neurostimulator is configured to provide the stimulation signal to a stimulator in accordance with a stimulation protocol. At least one stimulator is positioned next to a portion of the saphenous nerve of at least one lower limb of a patient. The processor is operationally activated to provide the stimulation signal to the stimulator for treatment of the patient.

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 of stimulating muscle in a person having neurological damage, by applying electric current to nerves at an area above an area of neurological damage, bypassing or bridging an area of neurological damage, and moving the muscle in a natural manner. A method of moving muscles of a paraplegic or a person who suffers from other movement-related disorders of the body by applying electric current to nerves at an area above an area of neurological damage, bypassing or bridging an area of neurological damage, and moving normally non-functioning muscles and moving normally non-functioning limbs.

A method for treatment of incontinence by targeted nerve stimulation where a signal generator is provided to generate a stimulation signal to modulate a patient's voiding disorder having the symptoms of abnormal urgency, incontinence or retention. A stimulator targets a portion of the patient's nervous tissue where the nervous tissue may be the patient's saphenous nerve, the patient's lateral plantar nerve or the patient's medial plantar nerve. The stimulation signal is applied to the patient's nervous tissue to activate the nervous tissue in order to modulate the voiding disorder.

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.

In some examples, a medical device is configured to deliver high dose electrical stimulation therapy to a patient by at least generating and delivering an electrical stimulation signal having a relatively high duty cycle, and a stimulation intensity less than a perception or paresthesia threshold intensity level for the patient. The pulses of the electrical stimulation signal may each have a relatively low amplitude, but due at least in part to a relatively high number of pulses per unit of time, a dose of the electrical stimulation may be high enough to elicit a therapeutic response from the patient.

A method to treat a patient having a pelvic floor dysfunction by establishing a neurostimulator having a processor and a signal generator to generate a stimulation signal. The processor is set to one or more parameters effective in the treating of the patient's pelvic dysfunction when the stimulation signal is applied to a saphenous nerve of the patient. The neurostimulator is configured to provide the stimulation signal to a stimulator in accordance with a stimulation protocol. At least one stimulator is positioned next to a portion of the saphenous nerve of at least one lower limb of a patient. The processor is operationally activated to provide the stimulation signal to the stimulator for treatment of the patient.