DE2604165A1 - ELECTRODE ARRANGEMENT - Google Patents

Description

The invention relates to an electrode arrangement with a low stimulus threshold for permanent implantation in the living body, without inducing fibrous tissue development.

In the field of biomedical devices, various Types of implantable stimulators used. An example of such a stimulator is the pacemaker. at Pacemakers are generally used with epicardial or epicardial pacemakers endocardial electrode arrangements worked, via which stimulus pulses are supplied to the heart of the patient. Myocardial Leads have electrodes that are attached directly to the myocardium, usually through the epicardial one Surface through. Endocardial leads are inserted intravenously into the heart; the electrode tip becomes placed in the apex of the right ventricle.

With the progressive development of improved myoccrdial and endocardial electrodes, the various parameters

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ter, such as physical size, shape, mechanical and electrical properties, taken into account and their influence on the safety, the long-term reliability and the corrosion resistance of the electrodes examined so that their contribution to the Working behavior of the electrode is essentially understood.

In addition to the above-mentioned parameters, another property that has not yet been fully clarified was also studied, known as the stimulus threshold. The stimulus threshold is the smallest stimulus level (smallest pacemaker pulse energy) defined, which is required to induce an effective heart contraction each time the stimulus is applied will. When studying the changes in the stimulus threshold of different implanted electrodes over a period of time Following the implantation, it was found that the stimulus threshold typically increases from a certain threshold value to Time of implantation rises steadily up to a peak value and then from the peak value to a chronic one The stimulus threshold decreases, which ultimately remains essentially constant. The full process of this unusual time dependency the pacing threshold caused by electrodes that are used for cardiac stimulation purposes could not be fully understood will.

The electrodes currently used to stimulate the heart

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are made from a material that is considered proportionate can be termed thrombogenic and fibrotic. That This means that the contact of the blood with the electrode and line material triggers a series of events, which eventually lead to the formation of a thrombus or blood clot over the part of the electrode in contact with the blood to lead. The physiological trauma attributed to the incision when implanting an endocardial electrode and that occurs at the stimulation site results in the production of tissue thromboplastin, a thrombogenic Material. The presence of thromboplastin near the electrode causes a thrombus or thrombus to form Fibrin lattice on the electrode through the polymerisation of fibrinogen in the blood.

It is known that most materials control the clotting or clumping mechanism at the interface between Set blood and material in motion. The one made of platinum or one Platinum alloy conductors and the silicone rubber encapsulation or insulation typical of known electrodes trigger the clumping mechanism; fibrin builds up, initially on the surface. Following the initial build-up, fibrinolysis or dissolution of the clot occurs. Before eliminating of the thrombus through fibrinolysis, collagen arrives at the location of the thrombus and forms a stable plug, as is the case with

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for example also occurs in constricted blood vessels.

The presence of an object, such as an electrode, in the bloodstream disrupts the blood flow field. Step static flow conditions or flow conditions that cause blood to circulate, clots form. In areas of rapid or turbulent flow, such as is the case within the heart, the The likelihood of such stagnation is very low. That this general process is also applicable to cardiac electrodes is confirmed by the observation that a fibrous on cardiac electrode leads generally near the electrode and also in areas where the flow occurs is obstructed, for example adjacent to the part of an endocardial electrode arrangement that extends through the heart valve, and not along the rest of the silicone rubber encapsulation, by means of which, in known arrangements, the lines are enclosed and insulated. This observation is noteworthy because silicone rubber is known to be thrombogenic to some extent and is therefore believed to be could induce a thrombus if the other necessary conditions are met.

It was found that those occurring with an implant Changes in the stimulus threshold are consistent with the processes explained above. First, the stimulus threshold increases while the fibrin lattice forms. Then

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the stimulus threshold decreases due to the fibrinolysis of the fibrin lattice. This is followed by stabilization to a chronic stimulus threshold, which is significantly above the initial one The stimulus threshold is when the collagen stabilizes the plug. Since both the original fibrin grid and the resulting collagen plugs of non-excitable heart tissue represent the apparent electrode surface enlarged; the current density with which the stimulable tissue is applied decreases; it's an extra energy required in order to stimulate the stimulable heart tissue through the layer of non-excitable tissue to feed.

So far it was generally accepted the development of the fibrous layer-was necessary as it was a dislocation or loosening prevent the electrode. It turned out, however, that it is not necessary to focus on the formation of a fibrous Leave shift to keep the electrode in place and that it is convenient to use the chronic threshold significantly lowering the heart electrode and temporarily increasing the stimulus threshold to a peak value, a phenomenon that has so far occurred when the stimulus threshold changes over time from the original value to the chronic one Value changed, kept to a minimum or avoided entirely. The electrode obtained in this way can with lower Energy extraction from the stimulus pulse generator can be operated.

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This either reduces the required battery power and / or extends the life of the pacemaker without affecting the performance of the battery or power source needs to be improved.

With the invention, the disadvantages of known solutions are eliminated, by building up thrombus-like material on the Stimulus electrode is prevented that both for the Electrode itself as well as for those in connection with the electrode intended insulating materials, non-thrombogenic materials can be used. Implantable electrodes made from non-thrombogenic materials, if at all, only minimal fibrous tissue; as a result, they have low Pacing thresholds, thereby reducing the output energy requirements of the pacemaker is diminished for effective irritation. It is possible in this way for a longer lifespan too without requiring any change in the storage capacity of the power sources used. Another benefit of using non-thrombogenic and thus non-fibrotic material is achieved, is that the electrode is lightweight due to avoiding the build-up of a fibrous layer surrounding the electrode can be taken out and replaced when the stimulation pulse generator is replaced periodically.

The invention is therefore based on the object of providing an implantable Create a stimulus electrode that has a low initial stimulus

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threshold that is not noticeable after implantation elevated. The stimulation electrode should be easily removed because of the lack of a fibrous layer build-up on the electrode can be.

This object is achieved in that a Non-thrombogenic conductive electrode provided in connection with a non-thrombogenic encapsulation or insulation material will.

The invention is shown below on the basis of a preferred exemplary embodiment explained in more detail. In the accompanying drawings shows:

1 shows an embodiment of one constructed according to the invention Stimulus electrode and

Fig. 2 is a graphical representation of the stimulus threshold as Function of time.

The embodiment according to FIG. 1 is an electrode arrangement in the form of a bipolar endocardial stimulus conduction, as it is normally introduced into the right ventricle via a vein. The overall design of the cardiac electrode according to FIG. 1 is similar in appearance to that of known electrodes. The stimulation electrode has an encapsulation or

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Isolation 1, the two helical spring-like conductors 2 and 3 encloses, which in turn are connected to an electrically conductive ring electrode 4 and an electrically conductive tip electrode 5 are connected. The free ends of the helical spring-like Conductors 2 and 3 are connected to a dedicated pulse generator, not shown, which is connected to the conductors Applies stimulation impulses. Structure and use of electrodes similar to that of FIG. 1 emerge in detail from FIG U.S. Patent 3,348,548.

Conventionally, the encapsulation or insulation 1
a silicone rubber is provided, a material such as that marketed, for example, by Dow Corning Corporation under the trade name "Silastic". Although this material is essentially inert and well tissue-compatible, it proves to be relatively thrombogenic and fibrotic.

The material most frequently used for the conductive ring electrode and the conductive tip electrode in known arrangements is either pure platinum or a platinum alloy consisting, for example, of 90% platinum and 10 % iridium. Both materials, like the silicone rubber insulation, are relatively thrombogenic and fibrotic.

In the case of the stimulation electrode according to the invention, a layer of non-stimulable tissue is built up around the electrode

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kept as small as possible or essentially prevented, by both for the electrode contacts 4 and 5 as well as for the encapsulation material 1, which is provided around the conductors to isolate and separate the electrodes from each other, non-thrombogenic Materials are used. Although the build-up of the fibrous layer is usually near the electrode contacts it was found that the use of only one non-thrombogenic electrode eliminates the problem of fibrous build-up can not completely eradicate, although this contributed to ' for a low threshold during the Implantation immediately following period of time. Obviously, for the build-up of fibrous tissue, this is proportionate thrombogenic and fibrotic encapsulation material responsible, the causes that on the surface of the encapsulation material fibrous envelope is formed. This fibrous sheath then grows over the conductive electrode even if a non-thrombogenic electrode is provided. The determined Data indicate that the use of a non-thrombogenic electrode in conjunction with a relatively thrombogenic Encapsulation, such as silicone rubber, usually causes a significant increase in the stimulus threshold after the implantation Electrode leads, although a peak value for the stimulus threshold is avoided.

In the case of the electrode arrangement explained here, a non-thrombogenic conductor for the ring electrode 4 and the tip

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Zen electrode 5 is provided. It turned out to be a very tough one Pyrolytic carbon coating on a platinum alloy or other suitable electrode Metal completely covering all exposed surfaces can be applied to obtain a suitable stimulation electrode that can be used in conjunction with a non-thrombogenic Encapsulation material has non-thrombogenic properties. It is also possible to have the entire electrode made of pyrolytic Form carbon, which is applied to a graphite substrate. Pyrolytic carbon with for that Properties suitable for this purpose are manufactured by General Atomic Company, San Diego, California, USA and marketed under the trade name "LTI Pyrolite Carbon". A method of making pyrolytic carbon is known from US Pat. No. 3,399,969.

It was also found that a non-thrombogenic encapsulation or insulation material 1 can be obtained by placing a polysiloxane-polyurethane block copolymer on a hose made of extruded polyether urethane is applied, for example, by Avco Corporation, Cincinnati, Ohio, USA manufactured and marketed under the trade name "Avocothane". The manufacture of such a coated Materials is known from U.S. Patent 3,562,352. Not only is Avcothane non-thrombogenic, but it is a good insulator; its elastomeric properties are those of silicone rubber, which is normally used for encapsulation or insulation

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lotion material used, superior. An example of a useful extrudable polyether urethane for manufacture of the hose is that manufactured by B. F. Goodrich Co. Material "Estane 5714F1".

Since when using non-thrombogenic materials for both the electrode and the insulator, the structure of fibrous material around the electrode tip is avoided or kept to a minimum, it is advisable to use the stimulus electrode with a flange or a prong or other bracket 6, which supports the retention of the electrode tip in the trabeculae of the right ventricle.

Fig. 2 shows the change in the stimulus threshold as a function of recognize the time. The solid line 20 shows the formation of a peak value of the stimulus threshold, as it is in conventional Electrodes typically occurs within a short period of time. It can also be seen that the stimulus threshold eventually decreases to a somewhat lower and essentially constant chronic value. The dashed Line 3Ό shows the gradual increase in the stimulus threshold for an electrode made of a non-fibrotic material, for example pyrolytic carbon for the electrically conductive Part, when using a conventional encapsulation material. Peaking is avoided; the stimulus threshold rises to a chronic value similar to that of one

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- 12 corresponds to the value encountered with conventional lines.

While the invention with reference to a specific embodiment has been explained, it goes without saying that numerous modifications are possible within the scope of the invention. For example the described stimulation electrodes are also suitable for stimulation due to their non-fibrotic properties of other than cardiac muscles as well as nerves in various application cases where it is desired to be a relative To have a low stimulus threshold available, which does not deteriorate significantly after implantation of the stimulus electrode. In addition, the electrode explained can be used with advantage wherever the fibrous structure on the Electrode should be kept to a minimum so that the stimulation electrode can later be removed again relatively easily can.

Instead of the electrodes made of conventional alloys, on which a non-thrombogenic, hard, pyrolytic carbon coating is applied, or of graphitic carbon substrates On which pyrolytic carbon has been deposited, it is also possible to manufacture the electrodes entirely to manufacture from pyrolytic carbon.

Instead of non-thrombogenic insulating material in the form of a Polysiloxane-polyurethane block copolymers are also available to others

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non-thrombogenic insulating materials are available. For example is silicone rubber with embedded powdery tungsten also a non-thrombogenic isolator. This insulation material is known from US Pat. No. 3,829,903.

It turned out to be to provide a redundant protective layer as expedient, one constructed in the manner described here Electrode to be coated with serum albumin to cover the non-fibrotic electrode to form a non-fibrotic coating.

For the electrode and the insulation, within the scope of the invention other non-thrombogenic materials can also be used.

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Claims (5)

7604165 - 14 claims 1.J Electrode arrangement with a low stimulus threshold for permanent, no development of fibrous tissue-inducing implantation in the living body, characterized by at least an electrode made of conductive material, with at least the surface exposed to the body tissue is made of a non-thrombogenic material, an electrically conductive one connected to each of the electrodes Line and an encapsulation formed by a non-thrombogenic and non-fibrotic insulating material that holds the line and covering the connection thereof to the electrode, but covering part of the outer surface of each electrode for one Contact with the body tissue to be irritated. 2. Electrode arrangement according to claim 1, characterized in that that the encapsulation is provided with a mechanical holder that holds the electrode assembly after implantation holds in place. 3. Electrode arrangement according to claim 1 or 2, characterized in that that the electrode consists of a conductive material with a non-thrombogenic hard pyrolytic Is coated with carbon. 609834/0696 4. Electrode arrangement according to claim 1 or 2, characterized in that that the electrode is made of non-thrombogenic hard pyrolytic carbon. 5. Electrode according to one of the preceding claims, characterized characterized in that the encapsulation consists of a non-thrombogenic polysiloxane-polyurethane block copolymer. 609834/0696 e e rs e 11 e