The embodiment discloses an electrode array including a housing; a plurality of first contact electrodes exposed to an outside of the housing; a plurality of second contact electrodes exposed to the outside of the housing; a first wire group disposed inside the housing and electrically connected to the first contact electrodes; and a second wire group disposed inside the housing and electrically connected to the second contact electrodes, the plurality of first contact electrodes and the first wire group being disposed on different planes within the housing.

An example includes a capacitor case sealed to retain electrolyte, at least one anode disposed in the capacitor case, the at least one anode comprising a sintered portion disposed on a substrate, an anode conductor coupled to the substrate in electrical communication with the sintered portion, the anode conductor sealingly extending through the capacitor case to an anode terminal disposed on the exterior of the capacitor case with the anode terminal in electrical communication with the sintered portion, a second electrode disposed in the capacitor case, a separator disposed between the second electrode and the anode and a second electrode terminal disposed on an exterior of the capacitor case and in electrical communication with the second electrode, with the anode terminal and the second electrode terminal electrically isolated from one another.

Aspects of the present disclosure are directed toward a medical device having a a core assembly. The core assembly includes a core circuit assembly and a core assembly housing configured to enclose the core circuit assembly. The core assembly housing includes a first portion, and a second portion configured to be coupled to the first portion along a weld seam. The second portion includes at least one weld joint feature, which includes a thinned section of the second portion.

A medical device includes a hybrid circuitry assembly and a core circuitry support structure. The core circuitry support structure includes a frame defining a cavity configured to receive at least a portion of the hybrid circuitry assembly. An outer surface of the frame is shaped to correspond to an inside surface of a core assembly housing configured to enclose the hybrid circuitry assembly and the core circuitry support structure.

This document discusses, among other things, systems and methods to fabricate and operate an implantable medical device. The implantable medical device can include a housing portion defining an interior chamber. The implantable medical device can include a circuit in the interior chamber. The implantable medical device can include a first electronic component that is not in the interior chamber. The implantable medical device can include a substrate coupled to the housing, the substrate including a first via extending through the substrate, the first via electrically coupling the first electronic component to the circuit.

An antenna for a medical implant device is described. The antenna has a magnetic field radiator portion and an electric field radiator portion coupled to the magnetic field radiator portion. The magnetic and electric field radiators are arranged to result in generation, by the antenna, of at least one of a transverse electric leaky wave and a transverse magnetic leaky wave in lossy body tissue of a human or animal body such that the lossy body tissue acts as a waveguide for the transverse electric leaky wave or transverse magnetic leaky wave, whereby to optimize at least one of the efficiency of the antenna and the far field gain of the antenna.

A method of treating hypertension in a patient includes 1) generating, by an electroacupuncture device implanted beneath a skin surface of the patient at an acupoint corresponding to a target tissue location within the patient, stimulation sessions at a duty cycle that is less than 0.05, wherein the duty cycle is a ratio of T3 to T4, each stimulation session included in the stimulation sessions has a duration of T3 minutes and occurs at a rate of once every T4 minutes, and the electroacupuncture device comprises a central electrode of a first polarity and an annular electrode of a second polarity and that is spaced apart from the central electrode; and 2) applying, by the electroacupuncture device, the stimulation sessions to the target tissue location by way of the central electrode and the annular electrode in accordance with the duty cycle.

Implantable medical devices include an enclosure that is constructed by machining of a material rather than by forming or stamping. The machining produces one or more internal features within the enclosure. These internal features may include shelves that may act as a stiffener and create separate compartments within the enclosure. These internal features may include contoured edges along the shelves to accommodate conductors and other structures that extend from one compartment to another. These features may include slots that are present in one or more locations, such as on a surface of one of the shelves. These internal features may also include standoffs that establish a gap between an internal component and the external wall of the enclosure. These internal features may also include different thicknesses in different areas of the enclosure, such as one wall thickness in one compartment and a different wall thickness in another compartment.

Process and equipment for muscular performance recovery in patients in general, specifically, ones practicing physical activity and athletes, the process providing the serial application of electrical pulses, transcutaneously, following stimulation steps: vasodilation, recovery and untightening phases. Equipment includes an electronic module containing monolithic cabinet having a body with two halves containing a mounted printed circuit board carrying the electronic circuit and the microcontroller, a power supply having a battery, whose external lower face houses a main electrode, and, with two electric conductor cables with satellite electrodes extending from a distal side, the electrodes having self-adhesive gel plates. An adjustable strip secures the equipment around a user's limb. A control panel has a power button and two intensity selection buttons. Additional internal components provided include: power source, step-up regulator, micro controller, power supply seal, boost source, intensity regulation, H-bridge, and electrode output modules.

A convertible implantable stimulator that provides electrical stimulation therapy during an extended trial stimulation period (or permanently, if desired) in a fully implanted solution is disclosed. The convertible implantable stimulator preferably does not include an internal power supply and is therefore continuously powered by an external charger, such as a powering patch, in a first mode of operation. If the convertible implantable stimulator is determined to be effective and a patient desires more traditional stimulation therapy, a separate power supply module can subsequently be implanted and connected to the convertible implantable stimulator to provide power to the stimulator in a second mode of operation.