Systems and methods for cardiac pacing are provided, where a pacing lead is placed at or near the bundle of His. A method for pacing a heart of a patient comprises: introducing a sheath to vasculature of the patient; steering the sheath within a coronary sinus in the heart to lodge a distal end of the sheath to a target location proximal to the bundle of His above a septum separating a left ventricle and a right ventricle of the heart; advancing a pacing lead through a lumen of the sheath to the target location; coupling the pacing lead to cardiac tissue at the target location; removing the sheath; and electrically pacing the bundle of His using the pacing lead.

An electrode fixing sleeve for fixing an electrode lead to biological tissue, the electrode fixing sleeve including a distal sleeve section and a proximal sleeve section, at least one distal electrode guiding region on the distal sleeve section and at least one proximal electrode guiding region on the proximal sleeve section, the distal electrode guiding region and proximal electrode guiding region having a common longitudinal axis. The distal and proximal sleeve sections are adjustable relative to one another along the common longitudinal axis. The electrode fixing sleeve additionally includes at least one electrode fixing element at least parts of which have elastic properties, the electrode fixing element being mounted on both the distal and proximal sleeve sections, and being designed so that at least parts of it move along the common longitudinal axis if a tensile force acts on the electrode fixing element along the common longitudinal axis.

A composite electrode intracardiac defibrillation catheter includes a first electrode group including at least two first electrodes for detecting an electrophysiological electrical signal of a site or a cell group in a heart chamber, and a second electrode group including at least one second electrode located between an adjacent pair of the at least two first electrodes for causing an electric current by a high-voltage defibrillation electric shock for defibrillation to flow in a contact site in the heart chamber or a contact site in a vein, and a conductive length of a surface of the at least one second electrode in a longitudinal direction of the composite electrode intracardiac defibrillation catheter is longer than a conductive length of each of the at least two first electrodes.

A system for treating cardiac arrhythmias comprising a generator including: a sensing circuitry configured to evaluate one or more identified signals representative of electrical activity of the heart and detect an arrhythmia, a control circuitry that is configured to control delivery of a therapy in response to the detected arrhythmia, the therapy including a first stage of electrical pulses delivered via at least a first electrode, wherein the first set of electrical pulses is configured to destabilize and/or terminate a reentry associated with the arrhythmia, and a first lead coupled to the generator, wherein the first lead includes the first electrode.

The present invention relates to an electrode assembly system for treatment of internal organ oedema by electro-osmosis and/or electrophoresis by delivering an electric field, the system comprising a first electrode, a second electrode, and a control unit, wherein the first electrode and second electrode are electrically connected to the control unit, the control unit being adapted to charge the first electrode negatively and the second electrode positively, and to directly control a strength of an electric field induced by the first electrode and the second electrode to a preset value for generating a treatment-specific electric flux. The present invention also relates to the use of such system, as well as a process of treatment of internal organ oedema using such system.

A medical apparatus includes an electrically conductive lead for a medical device, the lead having an internal bore terminating at a distal lead opening, and a lead delivery device for delivering the distal end of the lead to a blood vessel during implantation of the lead. The lead delivery device includes a removably anchorable guidewire, and a fixator attached to a distal portion of the guidewire for anchoring the guidewire. The fixator is movable between a compact configuration and an expanded configuration. The fixator is capable of passing through the distal lead opening of the lead in the compact configuration. The fixator is capable of exerting a holding force in the range of about 0.89 to 4.45 N in the lumen of the blood vessel in the expanded configuration.

A system implantable in the coronary venous system, including a pacing lead with an anchoring screw is disclosed. The system includes a stimulation lead (10) for stimulating a left heart cavity of a patient, and a removable catheter (26) for implanting the lead. The lead (10) has at least one stimulation electrode having an anchoring screw (14) that penetrates into the epicardial tissue of the patient. The catheter tube (26) is a pre-shaped tube with two curvatures in the absence of stress. The two curvatures are inscribed in two separate surfaces (38, 40) for self-orientating the distal end of the catheter tube into the target vein and maintaining the axis of the anchoring screw towards the epicardial wall during the screwing of the lead head.

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.

A medical electrical lead and methods of implanting medical electrical leads in lumens. Leads in accordance with the invention employ preformed biases to stabilize the lead within a lumen or lumen and to provide feedback to lead implanters.

A microlead includes a conductive cable formed by a strand of microcables, each microcable being formed of a strand of individual metallic wires. The microlead also includes an insulation layer sheathing the cable. The microlead further includes at least one exposed area formed in the insulation layer so as to form a corresponding electrode of the microlead. The microlead further includes a pharmacologically active agent (e.g., an anti-inflammatory agent) configured to gradually be released into the environment of the microlead after implantation of the microlead. The pharmacologically active agent may be a soluble material. An interstitial space, delimited by the inner wall of the insulation layer and existing in the remainder between the wires of each microcable, is filled with the pharmacologically active agent.