Abstract: An implantable lead system includes an elongated device slideably engaged within a lumen of a lead body. A distal portion of the elongated device is slidable through a helix tip coupled to a distal end of the lead body by passing through a pierceable fluid-tight seal disposed in proximity to the distal end of the lead body; the seal prevents ingress of bodily fluid into the lumen of the lead body.

Abstract: A medical system incorporating fluid delivery and lead delivery lumens dispense fluid into a volume of tissue. The fluid comprises or contains a pharmacologic, genetic, or biologic agent. The fluid may be dispensed initially during implantation or later using a minimally invasive medical procedure. A hollow tissue-piercing tip portion provides fluid delivery to the volume of tissue at one or more targeted sites. A medical electrical lead may be chronically implanted at the treated tissue site. The system includes a guide catheter having a fluid delivery lumen in communication with an active fixation, fluid dispensing member and a lead delivery lumen for deploying a medical lead. The system includes a medical lead having an active or passive fixation member and a central lumen through which a tip portion is deployed. The system may be used with implantable pulse generators, drug delivery pumps and the like.

Abstract: A bipolar cardiac vein lead and method of assembly is provided wherein the lead includes a flexible coil anode electrode such that the lead may be advanced through a tortuous pathway. The coil electrode is coupled to a conductor using a method of assembly that minimizes or eliminates rigid components, maintaining flexibility of the distal lead end. Multi-polar cardiac vein leads may include multiple flexible coil electrodes to achieve pacing and/or sensing in the left atrium and the left ventricle or at multiple left heart sites.

Abstract: A guide catheter and medical lead are provided wherein the lead may be used as a pull wire to steer the guide catheter. The guide catheter is provided with a flexible distal segment and the lead is provided with a distal engaging member, which may also serve as an electrode. The distal engaging member interacts with the distal catheter end such that traction applied to the proximal lead end causes flexion of the distal segment of the catheter to advance the flexible distal segment between a non-flexed position and a flexed position, allowing the catheter to be steered around obstacles.

Abstract: An improved medical lead assembly and method of use is provided. The lead assembly includes a lead body, and a spring member positioned adjacent to the lead body. The spring member may be deployed a selectable amount to maintain the lead body in a fixed location within a patient's body. The spring member may be an expandable coil, a mesh structure that is similar to a stent, or any other similar device that may be positioned in a low-profile state during a lead implant procedure. After the lead is positioned at a target destination, the spring member may be deployed an amount that is selected based on the characteristics of the surrounding tissue, including vessel size. According to one aspect of the invention, the lead assembly may provide means for facilitating chronic lead extraction.

Abstract: An improved connection system for coupling a device such as a pacemaker, cardioverter, defibrillator, nerve stimulator, muscle stimulator, implantable monitor or other medical device to a medical lead is disclosed. The connection system includes a coupling member designed to couple to the proximal end of the lead. This coupling member, which includes an inner lumen sized to form a press fit around the proximal end of the lead body, may be of a generally tubular construction. This coupling member includes connector means to enable a connector pin at the proximal end of the lead to mechanically and electrically couple to a device. The connector means may further include means for coupling both mechanically and electrically to a ring connector on the proximal end of a multi-polar lead. An insertion member may also be provided to allow the lead to be more easily inserted within the inner lumen of the coupling member.

Abstract: An automated identification and configuration system for use with an implantable medical device (IMD) is disclosed. The system includes a first communication circuit that is attached to, or otherwise carried by, a detachable component associated with the IMD such as a medical lead. The communication circuit stores data such as model numbers, serial numbers, technical data, and/or calibration information that describes the additional component. This information may be transferred by the first communications circuit to a second communications circuit that is external to the additional component. This transferred data can be used to automatically configure the internal circuitry and connection functions of the IMD to properly interface with, and support, the additional component. For example, the data can be used to automatically adjust amplifier gains or other sensor circuitry, or to configure a connector block to properly couple to the component.

Abstract: An implantable medical device that includes a lead body extending from a proximal end to a distal end, a plurality of conductors extending between the proximal end and the distal end of the lead body, and an insulative layer formed of a hydrolytically stable polyimide material surrounding the plurality of conductors. In one embodiment, the hydrolytically stable polyimide material is an SI polyimide material.

Abstract: An electrical medical lead is provided having two or more electrodes, electrically insulated from each other and electrically coupled to individually insulated filars in a multi-filar coiled conductor. When the lead is used with a medical device equipped with a switch matrix, electrodes are selected individually or simultaneously to serve as an anode or cathode in any unipolar, bipolar or multi-polar configuration for delivering stimulation and/or sensing signals in excitable tissue. In one embodiment, a tip electrode array is expandable for improving electrode contact with targeted tissue and stabilizing lead position.

Abstract: An electrical lead includes an elongate body having a proximal end and a fixation member joined to the elongate body and distally disposed from the proximal end of the elongate body, wherein the fixation member is capable of being extended from and retracted toward the elongate body. A method includes advancing an electrical lead into vasculature and extending a fixation member from the body of the electrical lead to fixedly engage the electrical lead within the vasculature. The method may further include retracting the fixation member toward the body of the electrical lead to unengage the electrical lead within the vasculature and retracting the electrical lead from the vasculature.

Abstract: A medical electrical lead, which may be useful in coupling an implantable medical device, is comprised of a first and second lead. The first lead has a first electrode coupled adjacent a distal end portion thereof. The distal end portion of the first lead is anchorable in the coronary sinus of a patient. The second lead is coupled with and moveable along the first lead. The second lead has a second electrode located thereon wherein the position of the first and second electrodes may be varied relative to one another by movement of the second lead along the first lead. A rubber tip holds the relative position of each electrode.

Abstract: A method and apparatus for dynamically fixating and removing a lead in a vasculature of a body. At least one segmenting means such as a collar is disposed at a distal end of the lead forming a deployable actuable segment adapted to dynamically assume an engaging and retracted position. In an engaging position, the actuable segment dynamically and varyingly adapts into a shape or shapes to engage a vessel. In a retracted position the shape or shapes collapse thus maintaining the original geometry of the lead in the vasculature. The actuable segment assumes a deployed or retracted position based on the flexural condition of the segment, respectively.

Abstract: A medical electrical lead, which may be useful in coupling an implantable medical device, is comprised of an elongate body having first and second spaced apart lumens. A conductor and an electrode are associated with the first lumen, and the second lumen is multi-purpose. The second lumen may be used to guide the lead and to introduce various fluids into the venous system. The second lumen may at various times be used to introduce vasodilation solutions, contrast fluids and adhesives into the venous system.

Abstract: A system for implanting a medical electrical lead includes an elongated lead body and a relatively non-compliant lead extension joined to a proximal end of the proximal portion of the lead body. The lead body includes a plurality of connector rings positioned about a proximal portion of the lead body. The lead extension includes a plurality of temporary contact surfaces and a plurality of conductors wherein each conductor joins a temporary contact surface to a corresponding connector ring.

Abstract: An implantable sensing device includes a sensing element and a mounting element. The mounting element has a first end and a second end with a longitudinal axis therethrough. The sensing element is positioned at the first end of the mounting element with the mounting element having a length that is adjustable along the longitudinal axis. The mounting element includes a sleeve having a first open end and a second open end with the longitudinal axis therethrough. The sensing element is positioned in the second open end and includes a lead body connected thereto extending through the second open end. The sleeve includes an outer sleeve member coupled for adjustment along the longitudinal axis with respect to an inner sleeve member. Further, the mounting element may include a flexible element about the first open end extending outwardly relative to the longitudinal axis and a flange element extending outwardly relative to the longitudinal axis from at least a portion of the second end.

Abstract: A medical electrical lead is disclosed having an inner lumen adapted to receive a stiffening member, and which is further adapted to deliver fluoro-visible media while the stiffening member is located within the inner lumen. According to one aspect of the invention, the stiffening member is a guide wire having an inner lumen. The inner lumen of the guide wire is used to deliver the contrast medium while the guide wire is in place within the lumen of the lead. In another embodiment, a stiffening member that is sized to occupy only a portion of the lumen of the lead is utilized. The non-occupied portion of the lumen is sized to be large enough to allow for the passage of fluoro-visible medium from an injection port at the proximal end of the lead to a delivery port at the distal end of the lead. According to one aspect of the invention, the lead includes a sealable member located at the distal end of the lumen of the lead to prevent the ingress of bodily fluids within this lead lumen.

Abstract: A lead connector arrangement includes a non-cylindrically shaped connector pin coupled to a lead conductor and a connector sleeve assembly for receiving the non-cylindrically shaped connector pin. The connector sleeve assembly includes an insert with an axial bore formed therein that complements the shape of the non-cylindrical connector pin. According to one embodiment, the non-cylindrical connector pin may be provided in the form of a triangular, square, rectangular, or hexagonal shape. The axial bore has a complimentary shape to receive the connector pin. When the connector pin is threaded through the connector sleeve assembly using a pull-wire device, the pull-wire device may be unscrewed from the connector pin without causing axial rotation of the lead conductor when the connector pin is fully inserted within the axial bore.

Abstract: An introducer system for introducing a lead or catheter and a method of use. The introducer system includes an elongated introducer sheath which has a luer hub mounted to its proximal end through which a lead or catheter is introduced and a slitter for slitting the luer hub and the introducer sheath. The slittable luer hub takes the form of a conical or cylindrical member carrying a laterally extending tab adapted to engage internal threading on a female luer lock fitting and has a slittable portion angularly displaced from the tab. The slitter includes a blade, a handle carrying the blade, a mechanism for engaging the lead or catheter in the vicinity of the blade and a mechanism for engaging the lead or catheter proximal to the blade, configured such that the lead or catheter body when engaged by the slitter is angled proximal to the blade of the slitter.

Abstract: An electrical connector has a compressible portion that expands to accept an inserted lead and then contracts around the lead to provide both an electrical and a spring-like mechanical connection to the lead. The connector may have a fluted pin that collapses around the lead body when a set screw of the connector port is tightened. Alternatively, a middle segment of a pin may have indentations or slots that collapse around an inserted lead body. The connector can be attached to the lead body after the lead body is implanted in the body of the patient. In lead systems in which the lead body is implanted using a guide catheter, attaching the connector to the lead body after implantation makes removal of the guide catheter much less difficult.

Abstract: The present invention provides a practical, multi-polar, in-line connector system for use in connecting implantable medical devices (IMD) and associated non-standard, low profile medical electrical leads. In addition, the present invention provides a system that uses tool less, frictional, sealed, compressive electrical connections for most or all of the electrical interconnections between an IMD and a low profile lead. A protective sleeve seals the lead connector to the non-standard port to prevent intrusion of body fluids therein. In addition, optional microchip-based circuitry coupled to the sleeve enables wireless communication and remote programming for diverse IMDs. Memory associated with the circuitry can store, update and reprogram a wide variety of information relevant to the IMD, the patient, and the attending physician, among others. For example, the microchip may be used to identify the lead type and characteristics, as well as other useful data.