Systems and methods of reducing pain after surgery in the thoracic or abdominal region and managing chronic nerve pain in the thoracic or abdominal region are provided. Such methods involve an electrode assembly that has a proximal portion and a distal portion with the distal portion including a plurality of electrodes. At least one electrode of the plurality of electrodes is placed over each of a plurality of intercostal nerve bundles in the patient's body. The proximal portion of the electrode assembly is connected to a pulse generator. An electromagnetic field is applied to the plurality of intercostal nerve bundles. The plurality of electrodes is removed from the patient's body after an intercostal nerve block sufficient to alleviate the patient's pain has been achieved.

An illustrative anchoring mechanism is provided for attachment to an implantable subcutaneous lead to facilitate anchoring at the distal tip of the lead. The anchoring mechanism is attached to an opening in a distal portion of a subcutaneous lead prior to implantation. The anchoring mechanism may be designed to avoid covering the sensing electrode of the subcutaneous lead, to prevent interference with sensing. Use of such an apparatus may reduce the number of incisions needed to perform implantation.

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.

An implantable antibacterial barrier device for an elongated medical device, the elongated medical device configured to extend from a first site, through a second site, to a third site. The implantable antibacterial barrier device includes a housing configured to be disposed at the first site, a working electrode configured to be disposed at the second site, and a reference electrode configured to be disposed at the first site. The housing includes barrier circuitry. The working electrode electrically is coupled to the barrier circuitry. The reference electrode is electrically coupled to the barrier circuitry. The barrier circuitry is configured to selectively maintain the working electrode at a negative electrical potential relative to the reference electrode to form an antibacterial barrier.

In an example, an apparatus is described that includes an implantable housing, a heart signal sensing circuit configured to sense intrinsic electrical heart signals, a ventricular tachyarrhythmia (VT) detector circuit, operatively coupled to the heart signal sensing circuit, the detector circuit operable to detect a VT based on the sensed heart signals, a processor configured to control delivery of an anti-tachyarrhythmia pacing (ATP) therapy based on the detected VT, and an energy delivery circuit configured to deliver the ATP therapy in response to the detected VT, wherein the apparatus does not include a shock circuit capable of delivering a therapeutically-effective cardioverting or defibrillating shock.

Flexible implantable subcutaneous heart device (HD) structure, including a flexible device body, at least one flexible lead and at least one respective transition unit, the transition unit for respectively coupling each flexible lead to the flexible device body, the flexible device body including a plurality of inner components and a respective plurality of hollow outer units, the hollow outer units for encasing and protecting the inner components, each one of the hollow outer units including at least one hollow rigid element and a hollow flexible element, the hollow flexible element coupled with the hollow rigid element for enabling the outer unit a degree of flexibility, wherein the hollow flexible element is covered with a covering and wherein the flexible device body is covered with a polymer.

A pacemaker has a housing and a therapy delivery circuit enclosed by the housing for generating pacing pulses for delivery to a patient's heart. An electrically insulative distal member is coupled directly to the housing and at least one non-tissue piercing cathode electrode is coupled directly to the insulative distal member. A tissue piercing electrode extends away from the housing.

A device and means to decrease the pain associated with cancer biopsies procedures The device uses anesthetic injections and electrical currents of both positive or negative polarity, or alternating current. The device can be incorporated into existing biopsiy devices. Application on breast cancer biopsies and other types of biopsies.

A method of treating osteoarthritis includes an implantable stimulator generating stimulation sessions at a duty cycle that is less than 0.05 and applying the stimulation sessions by way of the central electrode and the annular electrode to a location within a patient that includes at least one of an acupoint labeled ST35, an acupoint labeled EX-LE-4, or a location on a line that intersects the acupoints labeled ST35 and EX-LE-4.

An implantable medical device performs a method that includes detecting a cardiac event interval that is greater than a P-wave oversensing threshold interval. In response to detecting the cardiac event interval greater than the P-wave oversensing threshold interval, the device determines the amplitude of the sensed cardiac signal and withholds restarting a pacing interval in response to the amplitude satisfying P-wave oversensing criteria. A pacing pulse may be generated in response to the pacing interval expiring without sensing an intrinsic cardiac electrical event that is not detected as a P-wave oversensing event.