Techniques for placing implantable electrodes to treat sleep apnea, and associated devices, systems, and methods are disclosed herein. A representative method includes percutaneously implanting one or more signal delivery devices, each at or near a respective target signal delivery location in a patient. Each signal delivery device can include one or more electrodes, and individual ones of the electrodes can be positioned to produce a net positive protrusive motor response of the patient’s tongue. The representative method further includes providing power to one or more of the electrodes from a wearable power source to cause the electrode(s) to deliver an electrical signal to the respective target signal delivery location(s) to produce the net positive protrusive motor response.

A method includes applying a stimulation profile having a plurality of stimulation signals to at least one muscle of a recipient and/or to at least one neuron configured to control the at least one muscle. The method further includes monitoring muscle fatigue of the at least one muscle during said applying the stimulation profile. The method further includes automatically modifying the stimulation profile in response to said muscle fatigue.

Bacteria, cancer cells, fungus and other harmful cells located beneath the surface of a mammal body can be effectively destroyed by passing an electrical current through the area to be treated. Electrodes are positioned on either side of the area to be treated, for example, gums, fingers, arms, legs, feet and torso, and an electric current is caused to flow between the electrodes and through the area to be treated. The electric current will destroy the bacteria, cancer cells, fungus or other harmful cells.

An oral care implement herein may be embodied as an oral device for placement in the oral cavity. The device may include an insert configured for placement in the oral cavity in contact with a wearer's teeth and an activating member configured for placement in the oral cavity and selectively attachable to the insert.

Apparatus (100) for training oral muscle tone, the apparatus (100) includes a mouthpiece (103) having first electrode means (132a, 132b, 133a, 133b) associated with the mouthpiece (103) and second electrode means (152a, 152b) for location exterior of the mouth of the user, electrical circuitry operatively connected to the first (132a, 132b, 133a, 133b) and second (152a, 152b) electrode means, wherein the apparatus (100) is configured to provide, in use, via the first (132a, 132b, 133a, 133b) and/or second (152a, 152b) electrode means electrical stimulation to one or more oral muscles to increase resting muscle tone and/or muscle tone during sleep, the second electrode means (152a, 152b) including a first and second electrode (152a, 152b), the first and second electrodes (152a, 152b) of the second electrode means being located or locatable lateral of a midline of the face of the user.

Implantable electrodes with power delivery wearable for treating sleep apnea, and associated systems and methods are disclosed herein. A representative system includes non-implantable signal generator worn by the patient and having an antenna that directs a mid-field RF power signal to an implanted electrode. The implanted electrode in turn directs a lowerfrequency signal to a neural target, for example, the patient's hypoglossal nerve. Representative signal generators can have the form of a mouthpiece, a collar or other wearable, and/or a skin-mounted patch.

A first medical device for obstructive sleep apnea therapy includes therapy delivery circuitry coupled to a first set of electrodes implantable proximate to a first hypoglossal nerve within a tongue of the patient and configured to deliver a first electrical stimulation signal to the first hypoglossal nerve that causes the tongue of the patient to advance and includes information to communicate to a second medical device implantable within the head or neck of the patient and coupled to a second set of electrodes implantable proximate to a second hypoglossal nerve within the tongue of the patient; and sensing circuitry coupled to the first set of electrodes and configured to receive a second electrical stimulation signal, delivered to the second hypoglossal nerve by the second medical device, that includes information that the second medical device communicates to the first medical device.

An apparatus for use with a treatment system to disrupt bacteria from a metallic dental implant includes apparatus configured for mechanical and electrical connection to a device capable of producing an electrical stimulation voltage, and in which a connective body is further configured for attachment to the mouth of a patient and including at least one metal contact. The apparatus can include a mouth guard having at least one integrated or releasably attachable metal contact. Alternatively, at least one clip member can be attached, the clip member having a metal contact portion. The apparatus can be used in conjunction with any electrode of a treatment system in which the electrode is disposed within the mouth of the patient or external.

An apparatus includes multiple first reservoirs and multiple second reservoirs joined with a substrate. Selected ones of the multiple first reservoirs include a reducing agent, and first reservoir surfaces of selected ones of the multiple first reservoirs are proximate to a first substrate surface. Selected ones of the multiple second reservoirs include an oxidizing agent, and second reservoir surfaces of selected ones of the multiple second reservoirs are proximate to the first substrate surface.

A wireless implantable neuromuscular stimulator includes an antenna for producing an induced current in response to being disposed in an electromagnetic field. The antenna includes a substrate having an upper surface and a lower surface. An upper coil including a plurality of coil turns is disposed on the upper surface of the substrate. A lower coil including a plurality of coil turns is disposed on the lower surface of the substrate. The upper and lower coils are electrically connected to each other in parallel. The parallel connection can be facilitated by a plurality of connectors that extend through the substrate and electrically connect the upper coil to the lower coil. In one example configuration, connectors connect each coil turn of the upper coil to a corresponding turn of the lower coil.