A pacemaker fixation system, a leadless pacemaker system and a method of use thereof are disclosed. The leadless pacemaker system includes: a pacemaker fixation system including a leadless pacemaker and an elastic unfoldable element attached thereto, wherein in an unfolded configuration of the elastic unfoldable element, it fixes the leadless pacemaker at a target location in a blood vessel in communication with the heart; a delivery system for delivering the pacemaker fixation system to the target location; and a guide for guiding the delivery system into the blood vessel. According to the present invention, atrial pacing can be achieved by the leadless pacemaker through fixing the leadless pacemaker in the blood vessel in communication with the heart with the elastic unfoldable element.

Apparatus and methods are described, including a stent configured to be placed in a lumen. The stent includes a generally cylindrical stent body comprising a plurality of struts, and a plurality of antenna posts protruding longitudinally from an end of the stent body. Each of the antenna posts includes a proximal and distal portions, each of which is configured to be generally straight in the absence of any force being applied to the antenna post, and a compliant junction disposed between the proximal and distal portions, the proximal and distal portions being configured to flex with respect to one another about the compliant junction. An antenna is disposed annularly on the distal portions of the antenna posts, such that the antenna posts separate the antenna from the end of the stent body. Other applications are also described.

A neuromodulation system includes neuromodulation electrodes on an electrode support that is positionable within a blood vessel for transvascular stimulation of target nerves. Cathode surface area, cathode-to-anode spacing, and other parameters are selected for capture of specific types of nerves (sympathetic, parasympathetic, and/or mixed nerves), nerves located at larger or shorter distances from the vascular wall, and also for proper nerve capture for the targeted types of nerves.

A lead-in-lead system may include a first implantable lead having a first electrode and a second implantable lead having a second electrode guided by the first implantable lead to an implantation site. The second electrode may be implanted in a patient's heart distal to the first electrode at the same implantation site or at a second implantation site. Various methods may be used to deliver the lead-in-lead system to one or more implantation sites including at the triangle of Koch for ventricle-from-atrium (VfA) therapy, at the right ventricular septal wall for dual bundle-branch pacing, or in the coronary vasculature for left side sensing and pacing.

Apparatus and methods are described, including a stent configured to be placed in a lumen. The stent includes a generally cylindrical stent body including a plurality of struts, at least one electrode post protruding from the stent body, and a plurality of antenna posts protruding longitudinally from an end of the stent body. The antenna posts are longitudinally separated from the electrode post. An antenna is disposed annularly on the antenna posts, such that the antenna posts separate the antenna from the end of the stent body, and at least one electrode is coupled to the stent by being placed on the electrode post. Additional embodiments are also described.

Implantation of a cardiac stimulus system using parasternal access to the ITV is provided. Superior access may be achieved using parasternal locations in the upper ribcage to access the ITV. Inferior access may be achieved using parasternal locations in the lower ribcage to access the ITV. Parasternal access may include creating an opening in an intercostal space between two ribs and advancing a needle using ultrasound guidance.

A catheter for delivering an implantable stimulation device in a patient, the catheter including a probe having a plurality of electrodes, wherein the probe is transferrable from a reduced delivery state for movement within a human body to an expanded tissue contacting state, in which at least one electrode of the plurality of electrodes is in contact with tissue; and at least one holder to which an implantable stimulation device is attachable, wherein the at least one holder is positioned proximally to the probe section by a predefined distance d.

The present subject matter includes an implantable medical device with a capture feature at or near the proximal end. In some cases, the capture feature includes a hold that is configured to facilitate a releasable connection with a delivery device that is used to deliver the implantable medical device to a target implant site.

A system applies and senses electrical energy to and from tissue within a patient's body. The system includes a steerable delivery catheter, housing a flexible shaft and an electrical generator disposed on or embedded within the flexible shaft. Electrodes coupled to the shaft self-expand radially from a compressed position to an expanded position once the delivery catheter is withdrawn, thereby contacting a wall of the tissue of the patient's body to conduct electrical or other signals. The system may be inserted into the coronary sinus and tributary vein to provide physiological pacing to the His bundle and left ventricle. Further, the system provides for controlled passive transmission of normal electric impulses from the atria to the His bundle and ventricles without the need for an embedded generator.

Implantation of a cardiac stimulus system into the mediastinum using the ITV. Superior, intercostal, and inferior access methods are discussed and disclosed. Superior access may be performed using the brachiocephalic vein to access the ITV, with access to the brachiocephalic vein achieved using subclavian vein, using standard visualization techniques. Inferior access may be accomplished inferior to the lower rib margin via the superior epigastric vein. Intercostal access may include creating an opening in an intercostal space between two ribs and advancing a needle using ultrasound guidance.