A system for treatment of obstructive sleep apnea (OSA) is described. The system includes an introducer needle having an elongated body. The introducer needle is configured to create an opening in a tongue of a patient for implantation of a lead for treating OSA. One or more electrically conductive areas are located on the elongated body. A medical device is configured to deliver a stimulation signal via the introducer needle through the one or more electrically conductive areas to the tongue of the patient to stimulate one or more motor points of a protrusor muscle within the tongue of the patient.

The device relates to methods and devices for the treatment of obstmctive sleep apnea syndrome.

Disclosed is a system for stimulation of a subject. The stimulation may be to provide therapy to treat the subject. Stimulation may be of selected muscle groups and/or portions.

In an example, the disclosure describes a system with a lead having a proximal end and a distal end and an elongated lead body. The lead has one or more electrodes. A fixation member is located on the elongated lead body and is configured to secure the lead to tissue within a patient. The fixation member is located on the lead so the fixation member is closer to the proximal end than the one or more electrodes of the lead. A trialing adaptor receives the proximal end of the lead and is removable when a trialing period is completed. A sheath encloses at least a portion of the lead and covers the fixation member. The sheath is configured to remain in place over the lead during the trialing period.

A sleep apnea treatment/anti-snoring device optionally having controlled positive air-flow using a micro-blower to maintain an individual's upper airway unobstructed (pharynx area). Optionally the device includes a lower jaw mandibular advancement component. The device has built-in sensors, microprocessor and other items required for data acquisition and transfer.

An electrical stimulation system and method for the treatment of neurological disorders is disclosed. In a preferred embodiment, the electrical stimulation system includes channels of electrodes positioned in electrical contact with tissue of a neuromuscular target body region of a patient to provide pattered neuromuscular stimulation to the patient's musculature. In addition, at least one electrode from a channel is positioned in electrical contact with a tissue of the motor control region of the brain. A series of patterned electrical pulses are then applied to the patient through the channels to provide peripheral neuromuscular stimulation, and a direct current is applied transcranially to the brain. Various exemplary embodiments of the invention are disclosed.

Intraoral neuromodulation for the treatment clinical conditions such as, e.g., dysphagia, migraines, or speech problems can be achieved with a neuromodulation system that includes an intraoral neural stimulator, e.g., integrated into a wearable device to be positioned in the oral cavity, that is controlled based on one or more measured signals associated with an intraoral organ or nerve related to the clinical condition.

A trans mucosal neuromuscular electrical stimulation device (1) including a mouthpiece (3, 103) and electrodes (32a, 33a, 132a, 133a) associated with the mouthpiece (3, 103). The device (1) and/or mouthpiece (3, 103) incorporates electrical circuitry operatively connecting the electrodes (32a, 33a, 132a, 133a) to a power source and is configured to provide, in use, electrical stimulation to one or more palate and/or tongue muscles via the electrodes (32a, 33a, 132a, 133a) through the oral mucosa. The treatment regime, including the location of stimulation and the parameters used, is designed to increase resting muscle tone and/or muscle tone during sleep.

Systems and methods for the concurrent treatment of multiple oral diseases and defects while promoting general oral hygiene utilizing electricity are provided for non-human animals. Electrodes are used to deliver an electrical current to the gingival tissues of a mouth in order to achieve a number of therapeutic, prophylactic, and regenerative benefits. These benefits include killing oral microbes, increasing oral vasodilation, reducing oral biofilm, improving oral blood circulation, reversing oral bone resorption, promoting oral osteogenesis, treating gum recession, and fostering gingival regeneration. Other benefits include the treatment of gingivitis, periodontitis, and oral malodor, and other systemic diseases correlated with oral pathogens.

A system for providing non-invasive neuromodulation to a patient includes a mouthpiece and a controller. The mouthpiece includes an elongated housing, a printed circuit board, control circuitry mounted within the elongated housing, and a cable for connecting to a controller. The controller includes an elongated u-shaped element, an electronic receptacle, and a microcontroller. A method for providing non-invasive neurorehabilitation of a patient including connecting a mouthpiece to a controller, transmitting a numeric sequence to the mouthpiece, generating a first hash code, transmitting the first hash code to the controller, generating a second hash code, comparing the second hash code with the first hash code, enabling electrical communication between the mouthpiece and the controller only if the first hash code matches the second hash code, contacting the mouthpiece with the patient's intraoral cavity, and delivering neurostimulation to the patient's intraoral cavity.