The invention provides systems and methods for monitoring electrical biosignals of one or more biological cells, tissues, and/or organs of a patient and assessing a condition of the patient based on the electrical biosignals.

Embodiments of the instant invention relate to applying motor learning to promote remyelination following demyelination in a subject having a condition or disease. In certain embodiments, applying motor learning alone or in combination with vagus nerve stimulation (VNS) induces the production of new and preserves surviving oligodendrocytes. In accordance with certain embodiments of the disclosure, motor learning, when properly timed, enhances oligodendrogenesis after injury and recruits mature oligodendrocytes to participate in remyelination through the generation of new myelin sheaths. In other aspects of the disclosure, VNS paired with motor learning enhances remyelination following demyelination.

The present disclosure provides an apparatus for stimulating neural activity in a pudendal nerve of a subject, the apparatus comprising of: at least one primary electrode configured to apply a first electrical signal to said nerve; and a controller coupled to said primary electrode (s) and controlling the first electrical signal to be applied thereby, wherein said controller is configured to cause said at least one primary electrode to apply said first electrical signal that stimulates neural activity in the pudendal nerve to improve bladder function, and wherein the first electrical signal is applied in a burst pattern.

The invention provides systems and methods providing precision targeting of neural structures for the treatment of a condition while avoiding collateral damage to surrounding structures, such as blood vessels and/or other nerve tissue. The invention further provides systems and methods for treating at least one of rhinitis, congestion, and/or rhinorrhea via thrombus formation. The invention further provides systems and methods for detection, identification, and precision targeting of neural tissue for the treatment of a neurological condition while minimizing or avoiding collateral damage to surrounding or adjacent non-neural tissue, such as blood vessels and bone, as well as non-targeted neural tissue.

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.

Devices, systems and methods are described for providing muscle contraction stimulation therapy to treat myriad diseases, including heart failure, Type 2 diabetes, and peripheral vascular disease using a skin patch or implantable stimulator that includes a multiplicity of electrodes, a processor, a stimulation circuit, one or more sensors and programming for a patient interface unit, wherein the processor is programmed to control selection of a subset of the multiplicity of electrodes and of operation of the stimulation circuit responsive to an indication of an adverse physiologic response. The indication of patient discomfort may be determined by monitoring a physiologic parameter of the subject using the one or more sensors, by direct input from the subject via the patient interface unit programming, or a combination thereof. The devices, systems and methods also provide for automatically optimizing the stimulation parameters applied by the stimulation circuit responsive to feedback from the one or more sensors and/or by using direct input from the subject.

A method is provided for treating an intervertebral disc of a subject, the method including implanting at least one intra-pulposus exposed electrode surface in a nucleus pulposus of the intervertebral disc, and implanting one or more extra-pulposus exposed electrode surfaces outside the nucleus pulposus, in electrical communication with the intervertebral disc. Control circuitry, while electrically coupled to the at least one intra-pulposus exposed electrode surface and the one or more extra-pulposus exposed electrode surfaces, is activated to drive fluid and introduce nutritional substances into the intervertebral disc, by applying a voltage between the at least one intra-pulposus exposed electrode surface and the one or more extra-pulposus exposed electrode surfaces. Other embodiments are also described.

Modulation of neural activity in the superior laryngeal nerve (SLN) or cervical sympathetic trunk (CST) is effective in treating diseases and conditions mediated by thyroid and parathyroid hormones, in particular diseases associated with calcitonin secretion (e.g. osteoporosis) or diseases associated with thyroxine secretion (e.g. hypothyroid syndrome).

Devices, systems, and techniques are disclosed for managing electrical stimulation therapy and/or sensing of physiological signals such as brain signals. For example, a system may assist a clinician in identifying one or more electrode combinations for sensing a brain signal. In another example, a user interface may display brain signal information and values of a stimulation parameter at least partially defining electrical stimulation delivered to a patient when the brain signal information was sensed.

The present disclosure provides a stimulation lead for providing stimulation signals to nerve tissue and improved methods for constructing and manufacturing such a stimulation lead. The stimulation lead and/or methods includes a lead with a cable disposed within. At each end of the lead body a portion of the cable is exposed, and a metal ferrule is securely attached to the exposed cable portion. An electrode/contact is then securely attached to the metal ferrule such that the electrode covers the metal ferrule, a portion of the lead body, and a transition point where the exposed cable exits the lead body. A tine component may be swaged around a portion of the term end, configured to provide a retaining force against an force acting upon the stimulation lead, while allowing insertion of the stim end of the stimulation lead during implantation, and extraction of the stim end during explantation.