CA2098718A1

CA2098718A1 - Implantable electrode for location within a blood vessel

Info

Publication number: CA2098718A1
Application number: CA002098718A
Authority: CA
Inventors: Rahul Mehra
Original assignee: Individual
Current assignee: Medtronic Inc
Priority date: 1991-01-07
Filing date: 1991-11-13
Publication date: 1992-07-08
Also published as: US5170802A; WO1992011898A1; EP0566652A1; AU645875B2; EP0566652B1; DE69102709T2; EP0566652B2; AU9166791A; DE69102709T3; DE69102709D1

Abstract

An expandable electrode for location within a blood vessel or other tubular organ. The electrode takes the form of a hollow, tubular metal structure, expanded into contact with the inner walls of the tubular structure in which the electrode is to be located.
Expansion of the electrode may take place by means of plastic deformation of the electrode, or the electrode may be fabricated such that it resiliently expands. The electrode is particularly adapted for location within arteries and veins, and in particular for use in the coronary sinus and great vein of the human heart.

Description

WO 92/11898 ~ ~ 9 ~ 718 PCT/US91/08474 IMPI.~TA.BLE ELECT~ODE FOR LOCATION
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BACKGROUND OF THE INVENTION
This invention relates to implantable electrodes generally and to implantable defibrillation electrodes more particularly.
Over the past 20 years there has been substantial work toward development of a practical, implantable defibrillator. Early conceptions of implantable de~ibrillators, such as disclosed in Reissue Patent No.
27,652 by Mirowski et al, envision a system employing a ventricular endocardial electrode and a plate electrode mounted directly to the heart, subcutaneously, or to the skin. However, it was recognized early on that a totally transvenous system would be desirable in or~er to simplify the use of implantable defibrillators. One such system is suggested in U.S. Patent No. 3,942,536 by Mirowski et al, which discloses a transvenous lead having electrodes intended for location in the rlght ventricular apex and superior vena cava. Such systems were eventually tested in human beings, with some success. However, currently available commercial versions of implantable defi~rillators typically employ epicardial patch electrodes alone or in conjunction with transvenous electrodes.
While systems employing transvenous endocardial electrodes in combination with epicardial patch electrodes are workable, a thoracotomy is still required in order to apply the epicardial electrode. It is generally believed that it would be highly desirable to produce an implantable de~ibrillator system which would entirely avoid the n~cessity `of a thoracotomy, and there has been subs~antial work directed towards such systems, as disclosed in U.S.
Patent No. 4,727,877 issued to Kallo~ and in U.S. Patent No.
4,708,145 issued to Tacker et al. Both the Tacker et al and Xallok patents disclose the use of a transvenous, two b 5,~5~ E 5~

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electrode lead in combinatio~ with a subcutaneous patch electrode.
Transvenous ventricular defibrillation electrodes are shown in the above cited Mirowski patents and in the Tacker and Kallok patents cited aboveO Other endocardial defibrillation electrodes are disclosed in U.S. Patent No.
4,481,953 issued to Gold et al, U.S. Patent No. 4,161,952 issued to Kinney et al and U.S. Patent Mo. 4,641,656 issued to Smits. The Kinney, Smits, and Kallok patents also disclose transvenous defibrillation electrodes intended for use in or adjacent to the coronary sinus.
Electrode systems comprising only transvenously applied electrodes, or electrodes applied transvenously in conjunction with subcutaneous electrodes are also disclosed in U.S. Patent No. 4,932,407 issued to Williams on June 12, 1990. This patent is incorporated herein by reference in its entirety and discloses elongated coronary sinus electrodes intended for insertion in the coronary sinus and great vein, for use in conjunction with right ventricular defibrillation electrodes, superior vena cava defibrillation electrodes and/or subcutaneous patch electrodes.

SUMMARY OF ~HE I~ TTION
The coronary sinus electrode leads illustrated in Smits and Williams, like prior leads for location in the coronary sinus, have taken the general form of an elongated insulated lead body which carries one or more electrodes located on or exposed to the exterior of the lead body. When such electrode leads are inserted into blood vessels, there is a diminution in the cross sectional area available for blood flow. It is felt that an electrode design which allows for normal blood flow through the blood vessel in which it is implanted would be desirable, particularly in the context of long-term implant of defibrillation electrode leads in the coronary, venous and arterial systems.
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WO92111898 2 0 ~ 8 7 1 8 PCT/US91/08474 The present invention provides an electrode which takes the form of an expandable, hollow, cylindrical conductive body inserted into the ~essel in which the electrode is to be located and which is expanded into contact with the interior surface of the blood vessel, in a fashion similar to a class of devices known as endovascular stents. The electrode may take the form of a bent wire electrode located around the expandable portion of a delivery catheter, and expanded by the catheter into contact ~ith the interior of the blood vessel, much is disclosed in U.S. Patent No.
4,886,062 issued to Wiktor on December 12, 1989, incorporated herein by reference in its entirety.
Alternatively, the electrode may take the form of a generally tubular, resilient conductive member compressed into a catheter ~or introduction on removal from the catheter, the electrode may expand against the sides of the blood vessel, much as illustrated in U.S. Patent No.
4,830,003 issued to Wolff et al on May 6, 1989, also incorporated herein by reference in its entirety.
Generally is required that the electrode be expandable from a first configuration in which the outer diameter of the electrode is less than the inner diameter o~ the vessel to a second configuration having an increased outer diameter and having an inner lumen extending therethrough, which has an inner diameter approximately equal to the inner diameter of the vessel.
Regardless of what form the electrode takes, it is coupled to an elongated insulated conductor, extending from the electrode, and provided with an electrical connector to couple the electrode to an implantable electrical stimulator. In general, it is preferable that the elongated conductor be as small in diameter as is feasible. The lead may comprise only a single expandable or resilient element or may include a plurality of resilient or expandable elements, coupled to individual conductors or coupled to a 1TUT S~E:~

WO92/11898 PCT/US91/084 ~
20~87:~3 common conductor. Similarly, more than one Plec~rode lead can be used in the same blood vessel, with electrodes located adjacent to or spaced from one another, depending on the particular application.
Electrodes of this general type are believed to be applicable to all types of stimulation wherein location of the electrode in a tubular structure within the body is desirable. Such other applications may, for example, include muscle stimulation, nerve stimulation, cardias pacing, cardioversion and defibrillationO In all applications, the electrode has the advantage that flow through the tubular structure (e.g. blood flow through a vein or artery) is still possible with the electrode in place. Further, problems associated with dislodgement of the electrodes should be minimal or non-existent, due to the engagement of the electrode with the surrounding tissue.

BRIEF DESCRIPTION OF THE DRAWINGS
Figure l is a cutaway view of a human heart, illustrating the location of an electrode lead according to the present invention wherein the electrode is located in the coronary sinus.
Figure 2 shows the insertion of an electrode lead according to the present invention having an expandable electrode into a blood vessel.
Figure 3 shows the expansion of the electrode into contact with the wall of the blood vessel.
Figure 4 shows the electrode lead, as implanted in the blood vessel.
Figure 5 shows insertion of a lead employing a resilient electrode according to the present invention into a blood vessel.
Figure 6 shows expansion of the resilient electrode into contact with the wall o. the blood vessel.

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DETAILED DESCRIPTION OF T~E PREFERRED EMBODIMENT
Figure 1 shows a posterior view of the heart with the external wall of the coronary sinus 12 cut away to show the electrode portion 14 of a lead according to the present invention, as installed. The electrode 14 is coupled to an elongated insulated conductor 16 which passes through the right atrium 18 and exits the heart through the superior vena cava 20.
Electrode 14 as illustrated takes the form of an expandable cylindrical electrode corresponding in external configuration generally to the intravascular stent illustrated in U.S. Patent No. 4,886,062 issued to Wiktor, et al herein by reference in its entirety. Alternatively, electrode 14 may take the form of any generally cylindrical expandable or resilient metal member configured such that when expanded, a central lumen through the cylindrical structure is defined to allow for blood flow. Alternate embodiments of an appropriate electrode for use in conjunction wlth the lead according to the present invention are illustrated in Figures 2-4 and 5-6.
Figures 2-4 illustrate the installation of a lead according to the present invention employing an expandable hollow cylindrical metal member. The configuration of the electrode 14 is such that the wire of which it is formed is initially preformed into a two-dimensional zigzag form, and subsequently wrapped around a suitable mandrel to provide a hollow cylindrical structure having an external diameter less than the internal diameter of the blood vessel 22 in which it is intended to be implanted. The electrode 14 is coupled to an elongated insulated conductor 16. Electrode 14 is mounted around the expandable portion 24 of a balloon catheter 25, delivered by means of a guide catheter 26.
Upon the guide catheter 26 reaching a position adjacent the desired location of the electrode 14, the balloon catheter is advanced out of the distal end of the guide catheter 5~sTtTuTE SH~

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~0~7i8 until the expandable balloon portion 24 of the balloon catheter is located at the desired location of electrode 14.
As illustrated in Figure 3, following proper location of electrode 14, the expandable balloon portion 24 of the balloon catheter is expanded to urg~ the electrode 14 into contact with the inner wall of blood vessel 22. Expansion of the electrode 14 causes some permanent deformation of the electrode by straightening of the zigzag bends, which allows the electrode 14 to remain in contact with the interior of blood vessel 22 after deflation of the expandable portion 24 of the balloon catheter. After deflation of the balloon catheter 25, it is withdrawn, leaving the electrode l4 in place, as illustrated in Figure 4. The electrode 14 now provides an elongated conductive surface taking the general form of a hollow cylinder, having an internal lumen corresponding in internal diameter generally to the internal diameter of the blood vessel 22 in which it is implanted.
This allows for the implantation of a large surface area electrode, of the type generally appropriate for defibrillation, cardioversion or other stimulation, without substantially impeding the flow of blood through the blood vessel.
Figures 5 and 6 illustrate the installation of a lead employing a resilient electrode. This electrode takes the general physical configuration of the intravascular stent illustrated in U.S. Patent No. 4,830,003 issued to Wolff et al, also incorporated herein by referen~_e in its entirety.
In this embodiment of the invention, the electrode lO0 takes the form of a hollo~- tubular structure formed either by bending metal wires into a zigzag form or by welding short segments of wire into a tubular, zigzag formation as illustrated in the Wolff et al patent. In this case, the stent is formed so that in its relaxed state it displays an outer diamete- somewhat in excess OL the inne~ diameter of the blood vessel in which it is to be ~ planted. Thus, when ~B~ 5~OE~

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~ WO92/11898 PCT/US91/08474 2 ~; 9 8 7, 1 8 allowed to expand, it will urge itself against the inner wall of the blood vessel, anchoring the electrode in place.
Figure 5 shows the electrode 100, coupled to an elongated insulated conductor ''0, mounted within a delivery system, and located within a blood vessel 128. The delivery system comprises an outer catheter 116 and an inner catheter 120, mounted within a guide catheter 121. The inner and outer catheters are passed through the guide catheter until the distal end of the outer catheter 116 is located in the location desired for installation of the electrode 100~ At this point, the outer catheter 116 is pulled proximately, with the inner catheter 120 holding the electrode 100 in place. When outer catheter 116 is pulled back even with inner catheter 120, electrode 100 expands into contact with the inner surface of blood vessel 12~, defining a hollow cylindrical electrode with a cylindrical passage there through which corresponds generally in diameter to the inner diameter of the blood vessel 128. This provides an electrode which does not substantially impede flow of blood through the blood vessel 128. After location of the electrode 100, the delivery system is withdrawn, and the insulated conductor 110 is coupled to an implantable pulse generator such as an implantable defibrillator, cardio~erter, pacemaker or other stimulator.
The electrodes illustrated in the two embodiments shown should be fabricated of conductive, biocompatible metals having a low resistivity. For resilient or expandable electrodes of the sort illustrated in Figures 2-6, either tartalum or, a stainless steel type alloy such as P~. 35N
will be appropriate. While both embodiments illustrate the use o a single cylindrical electrode in conjunction with a lead according to the present invention, it is within the scope of the invention to either provide a single insulated conductor coupled to a plurality of expandable cylindrical electrodes, or to install a plurality of expandable 5;11BSTIl~l'E SWEE~

WO92/11898 PCT/US91/0847~
209871g electrodes, each with its o~n insulated conductor, so that the individual electrodes located within the blood vessel may be activated sequentially or such that a stimulation pulse may be delivered between two e~ectrodes located within the same vessel.
Further, while specific embodiments are provided with regard to an expandable and a resilien~ electrode, other similar structures are believed to be appropriate for use in conjunction with a lead accordlng to the present invention.
For example, expandable electrodes taking the form of expandable tubular metal meshes, expandable spirals and so forth are also believed workable in conjunction with the present invention. As such, the embodiments illustrated should be considered exemplary, rather than limiting with respect to the following claims.

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Claims

AMENDED CLAIMS
[received by the International Bureau on 7 August 1992 (07.08.92);
original claims 1-10 replaced by amended claims 1-5 (2 pages)]

1. An implantable lead of the type comprising an elongated insulated conductor having a proximal end and a distal end and an expandable electrode mounted to said conductor, characterized in that:
said expandable electrode comprises an electrode which in an undeformed condition takes the form of a hollow cylinder, fabricated of a conductive material and having a central lumen extending therethrough, said electrode deformable from a first cylindrical configuration, displaying a first outer diameter to a second, cylindrical configuration displaying a different outer diameter.

2. A lead according to claim 1 wherein said electrode is adapted to permanently deformed by expansion from said first diameter to said second diameter.

3. An lead according to claim 2 further comprising a delivery catheter having an expandable portion located thereon, wherein said lead is removably mounted to said delivery catheter such that said electrode is mounted around said expandable portion of said catheter.

4. A lead according to claim 1 wherein said electrode is resiliently compressible from said first diameter to said second diameter.

5. A lead according to claim 4 further comprising a delivery catheter, wherein said electrode lead is removably mounted to said delivery catheter and wherein said delivery catheter comprises means for retaining said electrode resiliently compressed to display said second outer diameter.