An implantable electroacupuncture device (IEAD) treats an erectile dysfunction condition of a patient through application of stimulation pulses applied at a target tissue location underlying, or in the vicinity of, at least one of acupoints BL52, BL23 or GV4. The IEAD includes an IEAD housing having an electrode configuration thereon that includes at least two electrodes, and pulse generation circuitry located within the IEAD housing and electrically coupled to the at least two electrodes. The pulse generation circuitry is adapted to deliver EA stimulation pulses to the patient's body tissue at or near the target tissue location in accordance with a specified stimulation regimen, the stimulation regimen requiring that the stimulation session have a duration of T3 minutes and a rate of occurrence of once every T4 minutes, and wherein a ratio of T3/T4 is no greater than 0.05.

An implantable electroacupuncture device (IEAD) treats a specified medical condition of a patient through application of electroacupuncture (EA) stimulation pulses applied substantially at or near a specified acupoint, its underlying nerves, or other target tissue location. The IEAD includes an IEAD housing having an electrode configuration thereon that includes at least two electrodes, and pulse generation circuitry located within the IEAD housing and electrically coupled to the at least two electrodes. The pulse generation circuitry is adapted to deliver stimulation pulses to the patient's body tissue at or near the target tissue location in accordance with a specified stimulation regimen, the stimulation regimen requiring that the stimulation session have a duration of T3 minutes and a rate of occurrence of once every T4 minutes, and wherein a ratio of T3/T4 is no greater than 0.05.

An exemplary method of treating a chronic low back pain condition in a patient includes 1) generating, by an electroacupuncture device implanted beneath a skin surface of the patient at at least one of acupoints BL22, BL23, BL24, BL25, and BL26 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 and 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 2) applying, by the electroacupuncture device, the stimulation sessions to the target tissue location in accordance with the duty cycle.

Active implantable medical device including a pulsed-voltage generator and a plurality of pocket electrodes for creating relatively high voltage gradients in the corresponding body pocket. In some examples, the voltage gradients are greater than approximately 3 kV/cm and are sufficient for killing infectious bacteria in the body pocket via pulsed field ablation. The active implantable medical device further includes an electronic controller that is wirelessly programmable to appropriately control various parameters of the pulsed-field-ablation procedure, e.g., in a patient- and infection-specific manner. Various examples of the disclosed active implantable medical device can beneficially be used to reduce the adverse effects of infections associated with implantable medical devices.

An implantable device has a hermetically sealed enclosure, an electronic device within the hermetically sealed enclosure, and a plurality of feedthrough conductors in mechanical contact with the hermetically sealed enclosure and exposed outside of the hermetically sealed enclosure. The implantable device also has a flexible substrate with a plurality of therapy contacts, and a plurality of continuously conductive elements extending along the flexible substrate from the array of therapy contacts and terminating at a plurality of connection pads. Each of the continuously conductive element is integral with at least one therapy contact and at least one connection pad to electrically communicate the noted therapy contact(s) and the noted connection pad(s). The thickness of each continuously conductive element may be between about 5 and 190 microns. The implantable device also has a plurality of mechanical welded couplings that each couple at least one of the connection pads.

In some examples, a battery assembly for an implantable medical device. The battery assembly may include an electrode stack comprising a plurality of electrode plates, wherein the plurality of electrode plates comprises a first electrode plate including a first tab extending from the first electrode plate and a second electrode plate including a second tab extending from the second electrode plate; a spacer between the first tab and the second tab; and a rivet extending through the first tab, second tab, and spacer, wherein the rivet is configured to mechanically attach the first tab, second tab, and spacer to each other.

A catheter inner assembly includes a receptacle with an interior contour configured to mate with a head and neck contour of a holding member of an implantable medical device; and a laterally facing opening of the receptacle has a profile matching a longitudinal profile of the head and neck. Thus, the opening allows only a properly oriented passage of the holding member therethrough, the passage being without deformation of holding member or opening. The inner assembly further includes a lock and release member useful for securing the device to the catheter, when the holding member has been passed through the receptacle's opening to mate with the receptacle's interior contour. The lock and release member may include an arcuate sidewall moveable between a first location, at which the sidewall overlays the laterally facing opening, and a second location, at which the sidewall is located proximal to the opening.

This disclosure provides methods and apparatus for wirelessly transferring power. A first aspect of this disclosure is an apparatus for receiving power wirelessly. The apparatus comprises a receive circuit configured to receive wireless communication and charging power. The apparatus also comprises a metallic structure defining a gap extending from a first surface to a second surface, and through the metallic structure, the first surface opposite the second surface. The metallic structure is configured to receive the charging power from a wireless charging field oscillating at a first frequency. The metallic structure is further configured to convey the received power to the receive circuit via first and second connecting feeds. The metallic structure is also further configured to shield the receive circuit from interference at frequencies other than the first frequency.

A device for contacting and/or electrically stimulating biological tissue by means of at least one electrode has at least a first unit, on which the at least one electrode is provided and which is configured for implantation in a human or animal body, a second unit, for supplying the first unit with electrical energy, and at least a first and a second conductive track for the voltage supply of the first unit. The first and second conductive tracks are respectively electrically connected to the first and second units and are at different voltage potentials. Spatially between the first and second conductive tracks, at least a first additional conductive track is arranged that is functionally not involved in the voltage supply of the first unit.

A leadless cardiac pacemaker is provided which can include any number of features. In one embodiment, the pacemaker can include a tip electrode, pacing electronics disposed on a p-type substrate in an electronics housing, the pacing electronics being electrically connected to the tip electrode, an energy source disposed in a cell housing, the energy source comprising a negative terminal electrically connected to the cell housing and a positive terminal electrically connected to the pacing electronics, wherein the pacing electronics are configured to drive the tip electrode negative with respect to the cell housing during a stimulation pulse. The pacemaker advantageously allows p-type pacing electronics to drive a tip electrode negative with respect to the can electrode when the can electrode is directly connected to a negative terminal of the cell. Methods of use are also provided.