A catheter system and a recapture assembly for the catheter system which serves to expand the system's functionality to support highly-articulated implant recapture. The recapture assembly comprises: a cinch tube with a centering device provided at the distal end of the cinch tube and a tether located within the cinch tube adapted to be telescoped relative to the cinch tube. Also, a method for retrieval of the implant comprising a hitch-like element at its proximal end by the catheter system is disclosed.

A medical tool includes a rotation mechanism that further includes a warning feature. The warning feature provides an indication when the rotation mechanism has achieved a number of rotations.

A device for delivering an implantable medical device (IMD) includes an elongated member and a deployment bay configured to house the IMD, the deployment bay defining a distal opening for deploying the IMD out of the deployment bay. The device includes a first electrode located inside the deployment bay during intravascular navigation, a second electrode, and impedance detection circuitry configured to deliver an electrical signal to a path between the first electrode and the second electrode through at least one of a fluid or tissue of the patient. The device also includes processing circuitry configured to determine an impedance of the path based on the signal and control a user interface to indicate when an impedance of the path indicates that at least one of the IMD or the distal opening is in a fixation configuration relative to the target site of the patient.

Systems and methods for separating an object such as a pacing lead from a patient tissue involve a flexible and torqueable shaft having an internal lumen sized to receive the object, and a hard separating mechanism for separating the object from the tissue. Typically the shaft and separating mechanism are advanced along or toward the object, and the separating mechanism is contacted with the tissue. The shaft is rotated to effect separation between the object and the tissue. The systems and methods are well suited for use in cardiac pacing or defibrillator lead explant procedures.

Devices and methods can be used for artificial cardiac pacing and/or resynchronization. For example, this document provides improved electrodes for stimulating and sensing electrical activity of the heart, and provides pacing and resynchronization systems incorporating such electrodes. While the devices and methods provided herein are described primarily in the context of pacing, it should be understood that resynchronization can additionally or alternatively be performed in an analogous manner, and that the scope of this disclosure includes such subject matter.

Devices and methods for treating tricuspid regurgitation (TR) are provided. A clasp or clamp is used to anchor a TR-treatment device to an existing lead of a pacemaker or an implantable cardioverter defibrillator (ICD) that passes through the tricuspid valve. The TR-treatment device can be a balloon occluder that is adjustable by filling or withdrawing filler material from the occluder through a proximal port implanted in the skin of the patient.

Various configurations of systems that employ leadless electrodes to provide pacing therapy are provided. In one example, a system that provides multiple sites for pacing of myocardium of a heart includes wireless pacing electrode assemblies that are implantable at sites proximate the myocardium using a percutaneous, transluminal, catheter delivery system. Also disclosed are various configurations of such systems, wireless electrode assemblies, and delivery catheters for delivering and implanting the electrode assemblies.

This accessory comprises a remotely steerable catheter (40) extended by a tip (50) comprising a base (52) to which the catheter (40) connects to and a cylindrical portion (54) defining a volume (56) suitable for housing the capsule (10). A sub-catheter (30) and the capsule are telescopically extendable with respect to the catheter between i) a retracted position and a deployed position wherein the capsule is removed from the connector and is carried by the distal end of the sub-catheter, and the distal end of sub-catheter and the proximal region (18) of the capsule being provided with disconnectable means of attachment (20, 36). The tip presents, between its base (52) and its cylindrical portion (54), a flexible portion (58) providing, between the base and the cylindrical portion, an elastic deformability in bending and compression.

A lead assembly and associated process include a lead and an integrated feature that facilitates extraction of the lead from the associated body passage. The integrated feature in one embodiment is a sheath received between the associated body passage and received over the lead. The sheath has a first portion extending from adjacent the proximal end to adjacent the distal end of the lead, where the first portion has an inner surface facing with the lead outer surface and the first portion having an outer surface facing radially outward from the lead outer surface. A second portion of the sheath extends from adjacent the distal end to adjacent the proximal end of the lead. The second portion has an inner surface received over the outer surface of the first portion, and the second portion further having an outer surface abutting an inner surface of the associated body passage that receives the lead therein. The integrated feature is alternatively a wire, band, or spoke assembly.

A hemostatic tissue anchor (120) is provided that includes an anchor portion (130) supported at a distal end (192) of a generally elongate anchor shaft (132). A hemostatic sealing element (122) is coupled to and surrounds at least an axial portion of the anchor shaft (132), is configured to be disposed at least partially within a cardiac tissue wall (160) at a target site, and includes a self-expanding frame (124) attached to a sealing membrane (126). The hemostatic sealing element (122) includes an expandable portion (128) that assumes an expanded frustoconical configuration (138) that is defined by the self-expanding frame (124) and the sealing membrane (126), and acts as a hemostatic seal of an opening through the cardiac tissue wall (160), through which opening the anchor shaft (132) is disposed. Other embodiments are also described.