An electrode device for recording electrophysiological neurosignals in nervous tissue of a living being includes a bundle of insulated electrical cables, where each cable has an electrical wire made of electrically conductive material and an insulation layer which covers and insulates the electrical wire. An electrical connector connects the electrical wires to a recording device. A free end of the bundle of insulated electrical cables distant from the electrical connector includes an implantation section for implantation in the nervous tissue of the living being. An electrophysiological recording system will have at least one such electrode device and a computer program arranged for execution on a computer.

Methods to generate elongated wires having a metallic substrate thereon and devices comprising the same. In a method of generating a device, the method comprises the steps of applying a first nonconductive coating upon an elongated core body of the device; applying a first conductive coating upon the first nonconductive coating; applying a photoresist coating upon the first conductive coating; directing a laser/light from a laser/light source upon portions of the photoresist coating to cause said portions of the photoresist coating to harden; applying a first chemical to the photoresist coating to remove the photoresist coating that was not hardened by the laser/light; and applying a second chemical to the hardened photoresist coating to expose portions of the first conductive coating previously positioned below the hardened photoresist coating.

Proposed is an electric wire array including: a substrate portion; and a plurality of electric line units being arranged on top of the substrate portion and being stacked on top of each other in a thickness direction, wherein the plurality of electric wire units each comprise: a plurality of electric wires being arranged on top of the substrate portion in such a manner to extend in a length direction; and a plurality of electrode holes being positioned in respective first end portions, respectively, of the plurality of electric wires, and being exposed, wherein the plurality of electrode holes are arranged in such a manner as to be positioned a distance apart from each other along the length direction and being sequentially arranged in a successive manner along the thickness direction, and wherein the thickness direction is a direction from the substrate portion to the electric wire unit, and the length direction is a direction vertical to the thickness direction.

The presently disclosed embodiments relate to insufflation and irrigation conduits for vessel harvesting systems and methods of their use. In particular, the present disclosure relates to a system having a combined cabling for providing gases, liquids, and/or electrical power to an attached medical device and method of use.

A lead may comprise a multiple filar wire comprising an inner core, an inner layer and an outer layer, where a portion of the inner layer is wound in a first orientation and the inner layer comprises a first number of filars of wire and where a portion of the outer layer is wound in a second orientation opposite the first orientation and the outer layer comprises a second number of filars of wire, the second number of filars of wire being greater than the first number of filars of wire. The lead may also comprise insulation covering a portion of the multiple filar wire, the portion of the multiple filar wire and the insulation comprising a helical coil structure wound in the first orientation and an anchor formed by the inner core, inner layer and outer layer extending away from the portion of the multiple filar wire, wherein the anchor comprises no helical coil structure.

The present disclosure provides systems and methods for a conductor assembly for an implantable lead cable. The conductor assembly includes a conductive element extending over an axial length from a proximal end to a distal end. The conductor assembly includes an inner dielectric layer coaxially covering the conductive element over the axial length. The conductor assembly includes an inner conductive layer coaxially covering the inner dielectric layer over the axial length, the inner conductive layer comprising a contiguous metal coating having a thickness in a range of 1 to 50 microns.

An electrical cable assembly amenable to implantation into a body includes a flexible cable. The flexible cable includes a dielectric substrate, a conductor lead for conducting an electrical signal, a conductive barrier layer, and an overmold layer. The conductor lead is embedded within and surrounded by the dielectric substrate. The conductive barrier layer surrounds the dielectric substrate and encases the dielectric substrate and conductor lead in a cavity. The conductive barrier layer is a continuous material layer that is neither braided nor spiral wrapped and provides a hermetic barrier formed of a metallic or inorganic material. The overmold layer provides one or more of mechanical protection or strain relief to the conductive barrier layer.

One aspect is a bi- or multipolar lead for a medical device including: a) a cable comprising an outer insulation having at least two first openings near a distal end of the cable; an inner lumen, wherein the inner lumen is arranged coaxially to the outer insulation and extends in a longitudinal direction from a proximal end to the distal end of the cable; at least two conducting channels, wherein the at least two conducting channels are arranged between the outer insulation and the inner lumen of the cable, wherein each one of the at least two conducting channels is formed by at least one insulated conductor comprising a conductor and an insulation layer, and wherein the insulation layer of the at least one insulated conductor of each one of the at least two conducting channels comprises a second opening, which is aligned with one of the at least two first openings; b) at least two ring electrodes, wherein each one of the at least two ring electrodes surrounds the cable at a position of one of the at least two aligned first and second openings of the cable, and wherein each one of the at least two ring electrodes is selectively connected to the conductor of the at least one insulated conductor of one of the at least two conducting channels through one of the at least two aligned first and second openings.

One aspect is a bi- or multipolar lead for a medical device including: a) a cable comprising an outer insulation having at least two first openings near a distal end of the cable; an inner lumen, wherein the inner lumen is arranged coaxially to the outer insulation and extends in a longitudinal direction from a proximal end to the distal end of the cable; at least two conducting channels, wherein the at least two conducting channels are arranged between the outer insulation and the inner lumen of the cable, wherein each one of the at least two conducting channels is formed by at least one insulated conductor comprising a conductor and an insulation layer, and wherein the insulation layer of the at least one insulated conductor of each one of the at least two conducting channels comprises a second opening, which is aligned with one of the at least two first openings; b) at least two ring electrodes, wherein each one of the at least two ring electrodes surrounds the cable at a position of one of the at least two aligned first and second openings of the cable, and wherein each one of the at least two ring electrodes is selectively connected to the conductor of the at least one insulated conductor of one of the at least two conducting channels through one of the at least two aligned first and second openings.

A percutaneous lead assembly for an active implantable device, the lead assembly comprising a sheath with a plurality of wires extending from a proximal end to a distal end. The wires being adapted to power the active implantable device; the distal end having at least one electrode fixed thereon. The electrodes being in communication with sensor electronics and wherein at least one electrode is on the outer layer of the lead assembly in which the electrode is used to detect at least one of acceleration and electrical signals of an organ.