An adapter system connects to implantable electrode leads. The adapter system has the pulse generator configured to generate electrical stimulation pulses and has a first connector member. The adapter has a housing containing two receptacles. Each receptacle receives an end portion of an electrode lead to establish an electrical connection between the adapter and the electrode lead. The adapter contains a second connector member configured to engage with the first connector member to establish a mechanical connection between the housing and the pulse generator and an electrical connection between the pulse generator and the electrode lead. A test cable electrically connects the pulse generator to the electrode leads for testing the electrode leads. The test cable contains a first connector member configured to engage with the second connector member to establish an electrical connection. The test cable contains a second connector member configured to engage with the first connector member.

A wireless charger system for inductively charging a rechargeable battery of an implantable pulse generator (IPG) implanted in a human body is provided. A charging coil in the charger is wirelessly coupled to a receiving coil of the IPG to charge the rechargeable battery. An end-of-charge (EOC) circuit continuously monitors the reflected impedance from a reflected impedance sensor and determines the end of charge when a predetermined pattern of the reflected impedance corresponding to an EOC signal from the IPG is received. Advantageously, receiving the EOC signal through the charging coil eliminates the need to provide a separate communication circuit in the IPG that communicates with the charger.

A cardiac defibrillation system that includes a pulse generator to generate therapeutic electrical pulses and at least one lead inserted through an intercostal space in the region of a cardiac notch of the left lung of a patient, the lead having a distal end configured to transmit the therapeutic electrical pulses generated by the pulse generator to defibrillate the heart of the patient.

A bore plug for an implantable medical device. The bore plug includes an elongate body having a proximal portion, a distal portion, and defining a major longitudinal axis therethrough, the distal portion being sized and configured to be received within a bore of the implantable medical device. The distal portion includes a lubricating element configured to lubricate the bore when the distal portion is at least one from the group consisting of inserted within and withdrawn from the bore.

A electrical contact for coupling a contact of a medical lead with electronics of a medical device including a contact member having a ring shaped wall defined by a ring inner diameter and ring outer diameter, a housing having a ring shape defining an opening therein, the opening configured to receive the medical lead therein, wherein the housing is defined in part by a housing longitudinal axis and a housing inner diameter, the contact member having at least one deflectable finger extending from the ring shaped wall into a contact opening defined by the ring inner diameter of the ring shaped wall, wherein the finger extends to a distal end and has side edges, the side edges of the finger disposed at respective angles relative to the housing longitudinal axis.

An implantable medical device includes an electrode and an insulative material secured to the electrode via an adhesive. The electrode includes a metal substrate and a metal coating. The metal substrate includes a connection segment and an active segment along a length of the metal substrate. The metal coating is disposed on an outer surface of the metal substrate along the connection segment and the active segment. The insulative material surrounds the connection segment of the metal substrate without surrounding the active segment, and the adhesive adheres to the metal coating on the connection segment.

The invention is a head part of an implantable device, method of production thereof and a plug which can be fitted into the head part. The head part comprises a housing which has at least one blind hole plug contact socket with a socket opening as well as a socket base axially opposite the socket opening, along which at least one electrically conductive contact ring element and an electrically insulating, elastically deformable sealing ring, which are enclosed by a solidified casting compound, are joined together coaxially axially. Arranged within the head part is at least one second blind hole plug contact socket with a socket opening as a socket base axially opposite the socket opening, along which at least one electrically conductive contact ring element and an electrically insulating, elastically deformable sealing ring is located, which are enclosed by the solidified casting compound, are joined together in a coaxial arrangement and in an axially serial sequence.

Systems and methods involving implants positioned within implant pockets through minimally invasive entrance incisions, along with related implants. In some implementations, implants may be folded, rolled, or otherwise compressed to fit within subcutaneous implant pockets, after which they may be decompressed to fit within an implant pocket having one or more dimensions substantially larger than the entrance incision. Such implants may be used for a variety of purposes, including generating electrical energy for various other implants located throughout the body.

Systems and methods involving implants positioned within implant pockets through minimally invasive entrance incisions, along with related neurostimulatory implants. In some implementations, implants may be folded, rolled, or otherwise compressed to fit within subcutaneous implant pockets, after which they may be decompressed to fit within an implant pocket having one or more dimensions substantially larger than the entrance incision. Such implants may be used for a variety of purposes, including generating electrical energy for various other implants, including neurostimulatory implants located throughout the body.

An implantable pulse generator (IPG) including a case containing an energy storage device and one or more electrode leads. A header is coupled to the case. The header includes a cassette, an antenna coupled to the cassette and electrically coupled to the case, the case configured as a part of the antenna for receiving and transmitting electromagnetic signals, and an electrode attachment structure configured to couple with the cassette and configured to couple with the one or more electrode leads.