Systems and methods for stimulating an anatomical element are provided. The system may comprise an implantable pulse generator configured to generate a current and an electrode device comprising a plurality of electrodes configured to apply the current to the anatomical element. Each of the plurality of electrodes may comprise at least one of an anode or a cathode. The electrode device may be customized by assigning each of the plurality of electrodes as at least one of an anode or a cathode and at least one of active or inactive. The current may be applied to the anatomical element in a predetermined pattern using the plurality of electrodes.

Electrical stimulation of neural activity in the neural innervation of the spleen that is associated with neurovascular bundles provides a useful way to treat acute medical conditions, such as trauma, hemorrhaging and shock.

The invention is a medical implant which is a wrap-around cuff comprising a flexible, biocompatible, film carrier substrate, that has a carrier substrate region which is wrapped around a wrap axis to form a tube. The invention has a protective structure directly or indirectly attached to the carrier substrate, which can be transformed from a first, open state into a second closed state that encloses the carrier substrate region that is wrapped to form a tube at least axially around a wrapping axis extending in the peripheral direction of the tube.

Neuromodulation of cranial nerves can be used to treat sleep or breathing disorders, among other diseases and disorders. A neuromodulation system can include a housing configured for implantation in an anterior cervical region of a patient, such as at or under a mandible of the patient, such as at least partially in one or more of a submental triangle, a submandibular triangle, and a carotid triangle. The system can include an electrode lead coupled to the housing, and the electrode lead can include an electrode configured to be disposed at or near a cranial nerve target in the patient. The system can be configured to generate electrical neuromodulation signals for delivery to the cranial nerve target using the electrode.

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.

An arrangement for reducing intraocular pressure includes a pulse signal source, a probe coupling, and at least one electrode. The probe coupling is configured to be supported on a portion of a living eye. The electrodes are supported on the probe coupling. The electrodes are operably coupled to receive a pulse signal from the pulse signal source.

The present disclosure relates to neuromuscular stimulation and sensing cuffs. The neuromuscular stimulation cuff has at least two fingers and a plurality of electrodes disposed on each finger. More generally, the neuromuscular stimulation cuff includes an outer, reusable component and an inner, disposable component. One or more electrodes are housed within the reusable component. The neuromuscular stimulation cuff may be produced by providing an insulating substrate layer, forming a conductive circuit on the substrate layer to form a conductive circuit layer, adhering a cover layer onto the conductive circuit layer to form a flexible circuit, and cutting at least one flexible finger from the flexible circuit. The neuromuscular stimulation cuff employs a flexible multi-electrode design which allows for reanimation of complex muscle movements in a patient, including individual finger movement.

A medical device with closed-loop responsive stimulation may include techniques to mitigate the impact on the therapy output of noise coupled into the medical device. A medical device according to this disclosure may determine the presence of noise and alter the closed loop policy to provide the necessary therapy to the patient and avoid prolonged under stimulation caused by the noise. The medical device may continue therapy, while testing for noise. When the device determines the noise level no longer affects the output therapy, the device may return the closed loop policy to a no-noise mode of operation. The medical device may also include techniques to mitigate the impact of manual adjustment while the medical device is subject to noise or is responding to changes in the patient's physiological signals.

An implant that includes an electrode is advanced to a nerve of a subject using a tube. The tube and the implant are arranged at a nonzero angle with respect to a skin surface of the subject, and the implant is passed distally from an opening of the tube, in a vicinity of a portion of the nerve. A longitudinal axis of the implant is realigned to become generally parallel with the skin surface, by proximally withdrawing the tube from the subject. Other embodiments are also described.

An electrode lead may comprise a flexible circuit that includes a planar dielectric substrate including an elongated lead substrate portion having opposing ends, an electrode carrying substrate portion disposed on one end of the lead substrate portion, and a connector substrate portion disposed on the other end of the lead substrate portion, wherein the lead substrate portion is pre-shaped into a three-dimensional structure. The flexible circuit may further include an electrically conductive trace extending from the connector substrate portion to the electrode carrying substrate portion, a first window formed in the connector substrate portion to expose the electrically conductive trace to form a connector pad, and a second window formed in the electrode carrying substrate portion to expose the electrically conductive trace to form an electrode pad. The electrode lead may further comprise a lead connector that incorporates the connector substrate portion.