A retention device for use with an implantable medical device (IMD) are disclosed. An illustrative retention device may comprise an elongate body including a configured to receive the lead of the IMD. The retention device may also include securing mechanisms coupled to the elongate body and configured to push against tissue of a patient. The securing mechanisms may also include linking elements coupled to the elongate body and a portion of the securing mechanisms.

A system and method for securing a medical implant within a patient includes disposing an anchor element around the implant, the anchor element including a pair of tabs each including an eyelet, and a flexible intermediate portion between the tabs, by positioning the implant within the intermediate portion and folding the anchor element such that the tabs contact one another. The anchor element is positioned at a desired implantation position with the tabs proximate soft tissue of the patient. The method further includes inserting a distal tip of a fixation element delivery tool through the eyelets and into the soft tissue, the fixation element including at least one tissue anchor and an adjustable suture arrangement coupled to the tissue anchor. The tissue anchor is deployed from the delivery tool and into the soft tissue of the patient. The delivery tool is withdrawn and the adjustable suture arrangement is tightened.

A lead engagement device is configured to be positioned in a lead lumen. The lead engagement device includes a hypotube. The hypotube includes a wall having an inner surface defining an inner lumen and an outer surface. The wall defines a longitudinal axis of the hypotube. A plurality of lead engagement fingers extend outwardly and proximally from the outer surface at acute angles, and planes in which the acute angles are disposed extend diagonally relative to the longitudinal axis. The plurality of lead engagement fingers are configured to translate relative to the lead and permit relative motion between the lead engagement device and the lead when applying a first force to the lead engagement device. The plurality of lead engagement fingers are configured to engage the lead and inhibit relative motion between the lead engagement device and the lead when applying an opposite second force to the lead engagement device.

A valve bypass tool, and a biostimulator transport system having such a valve bypass tool, is described. The valve bypass tool includes an annular seal to seal against a protective sheath of the biostimulator transport system. The valve bypass tool is slidably mounted on the protective sheath and includes a bypass sheath to insert into an access introducer. The valve bypass tool can lock onto the access introducer by mating a locking tab of the valve bypass tool with a locking groove of the access introducer. The locking tab can have a decent that securely fastens the components to resist decoupling when the biostimulator transport system is advanced through the access introducer into a patient anatomy. Other embodiments are also described and claimed.

A leadless pacemaker and a leadless pacemaker system are disclosed. A housing of a pacemaker body of the leadless pacemaker is designed as a curved tubular structure and can be deployed at a site with a limited space in a curved configuration, which allows the curved surface structure to fit more closely myocardial or vascular tissue around the site, resulting in improved pacing or sensing performance and in applicability to a substantially enlarged scope of patients who may benefit from cardiac pacing.

Methods and tool kits for implanting a lead subcutaneously. Examples include tool kits and methods for establishing first and second subcutaneous tunnels at an angle relative to one another to facilitate introduction of a lead to the subcutaneous space. In an example, a tunneling tool and lead assembly are advanced simultaneously into the subcutaneous space. The tunneling tool may include a curved region configured to transition the tool from the first subcutaneous tunnel to the second subcutaneous tunnel with the use of a single incision.

An example fixation component for an implantable medical device (IMD) includes a base and tines extending from the base and being spaced apart from one another. The tines include a penetrator tine and a protector tine. The penetrator tine includes a curved section defining a deformable preset curvature that extends laterally from a proximal section that is fixed to the base, traversing a longitudinal axis of the fixation component, to a distal section that terminates in an incisive distal end that is configured to penetrate a tissue to form a puncture. The protector tine includes a curved section defining a deformable preset curvature that extends from a proximal section that is fixed to the base, outward from the longitudinal axis, to a distal section that terminates in a non-incisive distal end that is configured to pass through the puncture.

A lead engagement device is configured to be positioned in a lead lumen of a lead. The lead engagement device includes a hypotube, and the hypotube includes a wall having an inner surface defining an inner lumen and an outer surface opposite the inner surface. A plurality of lead engagement fingers are coupled to the wall and extend outwardly and proximally from the outer surface. Each of the fingers is disposed adjacent to one of a plurality of apertures that extend through the wall. The fingers are configured to permit relative motion between the lead engagement device and the lead when applying a first force to the lead engagement device. The fingers are also configured to engage the lead and inhibit relative motion between the lead engagement device and the lead when applying an opposite second force to the lead engagement device.

The present invention generally relates to leadless pacemaker devices for facilitating regulation of a patient's heart rate and to methods of implanting and using such devices. In one embodiment, the pacemaker device includes a first and a second expandable structure connected by a neck region. A pacemaker unit is contained within one of the expandable structures and a power source is contained within the other of the expandable structures and is electrically connected to the pacemaker unit.

An implantable medical device includes a device housing, a fixation device, a first prong projecting from a proximal end of the device housing and a second prong projecting from the proximal end of the device housing. The second prong is spaced apart from the first prong. The first prong includes a first flange projecting away from a longitudinal axis of the device housing. The second prong includes a second flange projecting away from the longitudinal axis. The first prong and the second prong are configured to extend to a first flange diameter in a relaxed configuration and to extend to a second flange diameter in an expanded configuration.