An implantable lead for stimulating patient tissue includes a lead body. A jacket is disposed over at least a portion of a length of the lead body. The jacket has an outer surface and an opposing inner surface. At least a portion of the outer surface of the jacket forms at least a portion of an outer surface of the lead. At least a portion of the inner surface of the jacket is open to the lead body. The jacket defines apertures each extending completely through the jacket. Electrodes are disposed along a distal end of the lead body. Terminals are disposed along a proximal end of the lead body. Conductors electrically couple the electrodes to the terminals. Conductor insulation is disposed over each of the conductors. At least a portion of the conductor insulation is in fluid communication with the local environment external to the lead via the apertures.

Various embodiments concern a lead system for anchoring a lead, the lead system comprising a lead and an anchor. The anchor can comprise a ring and a flange extending from the ring. The anchor can be mounted on the lead such that the lead extends through the ring and the flange extends over an electrode of the lead. The lead system can further comprise a tether having a proximal portion and a distal portion. The proximal portion of the tether can attached to the lead while the distal portion of the tether can be attached to a needle. During an implantation procedure, the tether can be cut to remove the needle. The tether can then be attached to the flange. The lead, the anchor, and the tether can form a loop around a section of tissue to anchor the lead to the tissue.

A wireless electrostimulation system can comprise a wireless energy transmission source, and an implantable cardiovascular wireless electrostimulation node. A receiver circuit comprising an inductive antenna can be configured to capture magnetic energy to generate a tissue electrostimulation. A tissue electrostimulation circuit, coupled to the receiver circuit, can be configured to deliver energy captured by the receiver circuit as a tissue electrostimulation waveform. Delivery of tissue electrostimulation can be initiated by a therapy control unit.

Apparatus and methods are described, including apparatus for pacing a heart of a subject. The apparatus includes an implantable pulse generator (IPG) and a coiled lead connected to the IPG. The coiled lead includes a smaller-diameter coiled portion, a lumen of which having a first coil-lumen-diameter, and a larger-diameter coiled portion electrically in series with the smaller-diameter coiled portion, a lumen of the larger-diameter coiled portion having a second coil-lumen-diameter that is larger than the first coil-lumen-diameter. A perpendicular distance from a central longitudinal axis of the smaller-diameter coiled portion to the lumen of the larger-diameter coiled portion is greater than an outer radius of the smaller-diameter coiled portion, when the central longitudinal axis of the smaller-diameter coiled portion is parallel to a central longitudinal axis of the larger-diameter coiled portion. Other applications are also described.

A His bundle-detecting snare catheter according to the present invention detects a myocardial electrical signal and locates the position of a His bundle through the insertion of a snare and an EP catheter into a dual lumen catheter having two lumens, and captures a cerclage wire, which has passed through the His bundle, and safely guides same into a body. The His bundle-detecting snare catheter according to the present invention comprises: a dual lumen catheter having formed therein a first lumen and a second lumen; an electrical signal detection catheter which is inserted into the first lumen or the second lumen and detects a myocardial electrical signal; and a snare which is inserted into the first lumen or the second lumen and has one or more annular wires at a distal portion thereof, wherein the electrical signal detection catheter and the snare are inserted into different lumens.

An implantable extravascular electrode lead, having a proximal end and a distal end, comprises an electrode lead body that extends from the proximal end of the electrode lead to the distal end of the electrode lead, a connecting device arranged at the proximal end of the electrode lead body, and a fixing device arranged in the distal region of the electrode lead body or at the distal end of the electrode lead body. Once the electrode lead has been inserted into an extravascular region of a patient, the fixing device is actively actuatable from outside the body for fixing the electrode lead to patient body tissue.

Systems and methods for implanting a medical device are provided and include an implantable lead comprising a lead body having a distal end and a proximal end. The implantable lead has electrodes positioned at the distal end and has a lead connector positioned at the proximal end. The lead connector includes lead contacts that are communicatively coupled to the electrodes positioned at the distal end. The lead body has a body outer envelope configured to fit within a lumen of an introducer sheath and the lead connector has a connector outer envelope configured to fit within the lumen of the introducer sheath. A pulse generator has a connector cavity. The lead adaptor is configured to interconnect the implantable lead and the pulse generator. The lead adaptor has an insertable connector that includes mating contacts and an adaptor cavity that includes cavity contacts. The cavity contacts are positioned to engage the lead contacts of the lead connector when the lead connector is inserted into the adaptor cavity. The insertable connector is configured to be inserted into the connector cavity of the pulse generator.

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 catheter system comprises an elongate catheter body including a distal end, a cannulation lumen extending through the catheter body and terminating at the distal end of the catheter body, and a steering element extending through the catheter body for steering the distal end. The catheter system also comprises an imaging element secured to a distal end portion of the catheter body and configured to obtain optical images of an area located distally of the distal end of the catheter body. The catheter body includes a ridge extending axially along an outer surface of the distal end portion, wherein a width of the ridge measured about a circumference of the catheter body is less than a length of the ridge measured along the longitudinal axis, and the imaging element is radially aligned with the ridge with at least a portion of the imaging element disposed within the ridge.