Abstract: An implant includes tissue-contacting electrodes; at least one implant antenna configured to receive wireless power; and implant circuitry configured to use the received wireless power to drive the one or more electrodes to apply a current. A hand-held controller includes: (i) one or more controller antennas, configured to transmit the wireless power, and to communicate with a consumer device; (ii) a battery configured to store battery power; and (iii) controller circuitry configured to: (a) use the battery power to drive at least one of the controller antennas to transmit the wireless power, (b) identify a position of the controller with respect to the implant, and (c) drive at least one of the controller antennas to transmit juxtaposition information to the consumer device about the position of the controller with respect to the implant.

Abstract: An electrostimulator implant is percutaneously advanceable into tissue of a limb of a subject. The implant comprises (i) an intracorporeal sensor, configured to detect a factor indicative of local blood supply in the tissue of the limb; (ii) an electrode disposed at an outer surface of the implant; (iii) an antenna, configured to wirelessly receive power; and (iv) circuitry, powered by the received power, and configured to drive the electrode to apply a bloodflow-increasing current to the tissue at least in part responsively to the detected factor. Other embodiments are also described.

Abstract: Apparatus, comprising (1) a first controller comprising at least one first-controller antenna configured to transmit a first wireless power signal having a first signal power; and a first-controller control unit configured to use battery power to drive the first-controller antenna; (2) a second controller, comprising at least one second-controller antenna, configured to transmit a second wireless power signal having a second signal power; and a second-controller control unit, configured to use mains electricity power to drive the second-controller antenna; and (3) an implant, comprising one or more electrodes; at least one implant antenna configured to receive 1-10 percent of the first signal power, and to receive 0.01-1 percent of the second signal power; and circuitry configured to drive the one or more electrodes responsively to the received 1-10 percent of the first signal power, or the received 0.01-1 percent of the second signal power.

Abstract: Apparatus is provided, comprising: (a) an implantable excitation unit, configured to induce action potentials in a nerve of a subject by applying an excitatory current; (b) an implantable blocking unit, configured to block the induced action potentials from propagating along the nerve by applying a blocking current; and (c) an extracorporeal controller, comprising circuitry configured: (i) to wirelessly drive the excitation unit to apply the excitatory current, (ii) in a first mode, to wirelessly drive the blocking unit to apply the blocking current while not driving the excitation unit to apply the excitatory current, (iii) in a second mode, to wirelessly drive the blocking unit to apply the blocking current while driving the excitation unit to apply the excitatory current, and (iv) to wirelessly alter a parameter of the blocking current, based on sensing performed while the extracorporeal controller is in the second mode.

Abstract: An external transmitter inductive coil can be provided in, on, or with a belt designed to be placed externally around a part of a body of a patient. An implantable device (such as a VAD or other medical device) that is implanted within the patient's body has associated with a receiver inductive coil that gets implanted within that part of the patient's body along with the device. The externally-located transmitter inductive coil inductively transfers electromagnetic power into that part of the body and thus to the receiver inductive coil. The implanted receiver inductive coil thus wirelessly receives the inductively-transferred electromagnetic power, and operates the implant.

Abstract: Apparatus and methods are described, including a medical implant that includes a receiving coil. A transmitting device includes a first transmitting coil, and a second transmitting coil disposed with respect to the first transmitting coil such that a shortest distance from an edge of the second transmitting coil to an edge of the first transmitting coil is within 20% of a length of the receiving coil. A control unit is configured to transmit power to the medical implant by driving a current source to drive a current in a clockwise direction through one of the transmitting coils, and drive a current in a counterclockwise direction through the other one of the transmitting coils. Other applications are also described.

Abstract: An electrostimulator implant is percutaneously advanceable into tissue of a limb of a subject. The implant comprises (i) an intracorporeal sensor, configured to detect a factor indicative of local blood supply in the tissue of the limb; (ii) an electrode disposed at an outer surface of the implant; (iii) an antenna, configured to wirelessly receive power; and (iv) circuitry, powered by the received power, and configured to drive the electrode to apply a bloodflow-increasing current to the tissue at least in part responsively to the detected factor. Other embodiments are also described.

Abstract: A system for assisted coughing includes a first sensor for measuring a parameter which can indicate a closed glottis and producing a first signal, a processor for receiving the first signal, determining a state indicating the closed glottis and generating an instruction for a Functional Electric Stimulation (FES) controller based, at least in part, on the determining, and a FES controller for generating an electric stimulation signal.

Abstract: Apparatus and methods are described, including a medical implant that includes a receiving coil. A transmitting device includes a first transmitting coil, and a second transmitting coil disposed with respect to the first transmitting coil such that a shortest distance from an edge of the second transmitting coil to an edge of the first transmitting coil is within 20% of a length of the receiving coil. A control unit is configured to transmit power to the medical implant by driving a current source to drive a current in a clockwise direction through one of the transmitting coils, and drive a current in a counterclockwise direction through the other one of the transmitting coils. Other applications are also described.

Abstract: Apparatus, comprising (1) a first controller comprising at least one first-controller antenna configured to transmit a first wireless power signal having a first signal power; and a first-controller control unit configured to use battery power to drive the first-controller antenna; (2) a second controller, comprising at least one second-controller antenna, configured to transmit a second wireless power signal having a second signal power; and a second-controller control unit, configured to use mains electricity power to drive the second-controller antenna; and (3) an implant, comprising one or more electrodes; at least one implant antenna configured to receive 1-10 percent of the first signal power, and to receive 0.01-1 percent of the second signal power; and circuitry configured to drive the one or more electrodes responsively to the received 1-10 percent of the first signal power, or the received 0.01-1 percent of the second signal power.

Abstract: Apparatus including an implant is provided, the implant including: a rod-shaped housing, having a distal half and a proximal half, and configured to be injected distally into tissue of a subject; a cathode on the distal half of the housing; an anchor configured to protrude from the proximal half of the housing, no anchor being configured to protrude from the distal half of the housing; an anode; and circuitry disposed within the housing, configured to drive a current between the cathode and the anode. Other embodiments are also described.

Abstract: An external transmitter inductive coil can be provided in, on, or with a belt designed to be placed externally around a part of a body of a patient. An implantable device (such as a VAD or other medical device) that is implanted within the patient's body has associated with a receiver inductive coil that gets implanted within that part of the patient's body along with the device. The externally-located transmitter inductive coil inductively transfers electromagnetic power into that part of the body and thus to the receiver inductive coil. The implanted receiver inductive coil thus wirelessly receives the inductively-transferred electromagnetic power, and operates the implant.

Abstract: A system for detecting clinically-relevant features of a gastrointestinal (GI) tract of a subject. The system comprises an external magnetic field generator adapted to be affixed to a patient for generating at predetermined time intervals a magnetic field with respect to the subject. The magnetic field has a predetermined polarity and flux density, thereby establishing a patient coordinate system based upon the magnetic field. The system includes a capsule adapted to be swallowed by a subject. The system further includes at least one radiation source emitting X-ray or gamma radiation and at least one radiation detector. The radiation detector is configured to detect in a first energy window collimated X-ray fluorescence radiation from the X-ray contrast agent composition excited by the emitted radiation, and to detect a second energy window Compton-backscattered radiation from the X-ray contrast agent and the wall of the GI tract produced in response to the emitted radiation.

Abstract: A device for controlling respiration during sleep, the device comprising: an odor disperser adapted to disperse an odor; at lease one detector adapted to detect a physiological characteristic of a user; a controller configured for controlling respiration of the user by instructing the odor dispenser to disperse an odor responsive to detections by the at least one detector.

Abstract: A method of receiving input from a user, comprising measuring a nasal air parameter and generating an instruction for one or both of a device and controller based on said measurement.