The present disclosure relates to an explantation assembly for retrieving an intracorporeal capsule implanted in a tissue of a patient comprising a first tube and a second tube. The first tube comprises a snare and a tissue. The second tube is configured to interact with the snare of the first tube and configured to be attached to the tissue of the patient.

A transport system for delivery or retrieval of a biostimulator, such as a leadless cardiac pacemaker, is described. The biostimulator transport system includes a docking cap supported by a bearing within a bearing housing. The bearing allows relative rotation between a torque shaft connected to the docking cap and an outer catheter connected to the bearing housing. The bearing housing and the docking cap include respective bearing retainers that constrain the bearing within the bearing housing without a weld attachment. The weldless retainers of the biostimulator transport system provide a robust mechanical securement of the bearing that is not vulnerable to corrosion. Other embodiments are also described and claimed.

Methods and systems for separating an object, such as a lead, from formed tissue are provided. Specifically, a tissue slitting device is configured to engage patient formed tissue at a slitting engagement point. While the object is subjected to a first traction force, the tissue slitting device is caused to move further into the engaged tissue and slit the tissue past the point of engagement. The slitting device causes the tissue to separate along an axial direction of the length of the formed tissue and releases at least some of the force containing the object. The methods and systems are well suited for use in cardiac pacing or defibrillator lead explant procedures.

A lead extraction tool includes a lever for enhanced mechanical advantage. A belt of the tool which causes rotation of a cutter on an end of a sheath can be driven both when a trigger of the handheld tool is squeezed and when the trigger is relaxed. A pair of winged engagers are carried upon a pedestal which moves with the trigger, with a driver coupled to a portion of the trigger causing a rear winged engager or a front winged engager to engage the belt, both when squeezing the trigger and when relaxing the trigger.

The present disclosure relates generally to medical devices and the use of medical devices for the treatment of vascular conditions. Particularly, the present disclosure provides devices and methods for using a snaring system to remove an implanted lead from the vasculature. A snaring system comprises an outer sheath (710) having a lumen; an inner sheath (705); a pusher (745) disposed within the lumen of the sheath, wherein the pusher comprises a longitudinal axis; a closed loop (720) having an opening, wherein the closed loop comprises a proximal extended portion, an S-curve portion and a distal extended portion, wherein the proximal extended portion of the closed loop is coupled to the pusher, wherein the proximal extended portion is substantially parallel to the longitudinal axis to the pusher, wherein the pusher and the closed loop are slidable relative to the inner sheath, whereupon being in a deployed configuration, the closed loop is disposed distally of the sheath and the S-curve portion is disposed substantially perpendicular to the proximal extended portion, wherein the S-curve portion comprises a first radius and a second radius, wherein the first radius is closer to the proximal extended portion relative to the distal extended portion, wherein the second radius is closer to the distal extended portion relative to the proximal extended portion, wherein the first radius is greater than the second radius; and a threader (725) fixedly coupled to the inner sheath, whereupon the closed loop being pulled proximally, the closed loop collapses over the threader and the threader is disposed within the opening of the closed loop. In one embodiment, two opposing closed loops are provided.

A medical device may include an introducer sheath, having a distal and a proximal end and a lumen extending from the distal end to the proximal end. The introducer sheath may also include a tab formed at the distal end and extending distal to the lumen, and a frangible portion extending between the distal end and the proximal end.

An electrode that includes an elongate lead body and a nerve cuff. The nerve cuff may include a biologically compatible, elastic, electrically insulative cuff body configured to be circumferentially disposed around a nerve, first and second relatively wide electrically conductive contacts carried by the cuff body that are spaced from one another in the length direction and that extend in the width direction to such an extent that they extend completely around the cuff body inner lumen when the cuff body is in the pre-set furled shape, and a plurality of relatively narrow electrically conductive contacts carried by the cuff body that are spaced from one another in the width direction and are located between the first and second relatively wide electrically conductive contacts.

A temporary pacing lead has an atraumatic curled distal region with multiple cathodes and distal pressure measurement to allow positioning and repositioning within the heart chamber without fluoroscopic or echo guidance. The curled distal region provides definite contact with two opposing walls of the ventricular chamber to ensure electrical signal capture without trauma to the endocardial surface. A stylet located in the pacing lead lumen assists in introducing, placing, and removing the pacing lead from the heart. The flexible distal region provides safe removal of the temporary lead following completion of use.

The present disclosure provides a lead locking device that is configured to be inserted into a lumen of a lead of a cardiac implantable electronic device (CIED), such as a lead of a pacemaker, and being locked at a selected position along the lumen for being retained there for allowing extraction of the lead and/or applying vibrations to the selected position. The lead locking device includes a deformable element that may deform by application of force thereon and the deformation thereof results in radial expansion thereof such that if it is disposed within a lumen of a lead, it presses against the walls of the lumen and applies force that retains the lead locking device in position. The deformable element may be configured for reversible deformation, namely that upon removal of the force that is applied thereon, it is reversed to a contracted, non-engaging state where its radial dimension is lower than the dimension of the lumen. The deformable element may be in the form of a metallic braid, a flexible rod or a wire, an inflatable member, a spring, a structural weakening portion in a body member, such as cuts or holes, allowing a portion of the body to expand, etc.

A lead removal system includes a lead removal device comprising a sheath. The sheath includes a distal separating member configured to separate an implanted lead from adjacent tissue. The sheath also includes a sheath lumen configured to receive a lead engagement device and the implanted lead. A traction applying device is coupled to the lead removal device. The traction applying device is configured to be secured to the lead engagement device and apply traction to the lead engagement device and the implanted lead as the distal separating member of the sheath separates the implanted lead from adjacent tissue.