DE4219083C1 - Fluid dispensing electrode for cardiology, neurology or gynaecology - has anchoring element provided by hollow helix allowing storage of dispensed medicament - Google Patents

Abstract

The electrode includes an anchoring element in the form of a hollow helix (7) used to supply the fluid from a store at the distal end of the electrode which can be provided by the helix itself, using a capillary effect. Pref. the helix has a vent opening (9) adjacent its point of attachment to the electrode head (4), the latter pref. incorporating at least one microsphere layer (37) applied to part of its surface, for storing the fluid. USE - For supplying medicament via implanted electrode, for cardiology, neurology or gynaecology.

Description

The invention relates to an implantable electrode for cardiology, neurology and gynecology, with an anchoring element and with one with the help of Capillary effect with a liquid fillable food cher, which is arranged at its distal end.

Pacemaker electrodes have been around for many Years of use for intra- and epicardial electro stimulation of the heart, with designs with screw ben-shaped electrode tips and barb-like Formations come into use. To tissue reactions due to the implanted foreign body, posh at the tip of the electrode to minimize - this Tissue reactions affect electrical Properties in stimulating the heart and the Perception of the heart signals - Pacemaker electrodes with pharmaceutical reservoirs equip.

Such an electrode mentioned at the outset is from DE 37 39 826 A1 and has at its distal end over a porous substrate, which over the capillary effect can be filled with a liquid. she tries to solve the problem that according to the prior art the electrodes are both porous and conductive must be designed. The various, listed there th electrodes have the disadvantage that they Because of the union of the characteristics of the conductivity and the porosity in the electrode in two different bodies that are firmly connected to each other  are medically necessary and desirable. At the same time, their manual filling is complex.

DE 37 35 137 A1 describes another arrangement for dispensing medication to an implantable medical device, in its near-surface area hollow cones which can be filled with medicaments are arranged. These are designed as blind holes that can be filled from the outside that forms over the entire surface of a heart pacemaker as well as in the area of the electrode head brought fastening arrangements such as collars or bristles are distributed.

An electrode tip is known from US Pat. No. 4,917,106, which has a permeable membrane through which through one provided inside the electrode Diffuse liquid or a suitable gel through it can dieren. The drug is dispensed Osmosis used.

US 4,819,662 teaches a pacemaker electronics trode, which has an inner container, which can be filled manually in different ways. However, there is always one to dispense with medication-filled cylinder in the cavity inserted in the electrode, which then with the Electrode tip is closed in hemisphere shaped configuration a packed wire made of a platinum alloy. The drug is then released via this porous electrode tip.

US 4,953,564 describes a so-called MCRD (monolithic controlled release device), d. H. a mono lithic device for controlled material delivery, at which the device delivering the medication internally half of the cylin enclosed by the helix is arranged. Here is the schwammar term polymer material inside a cartridge-shaped Arranged sleeve that has an expansion volume for  the porous monolithic device and one of them closing plug.

DE 82 02 881 U1 describes an electrode tip known to reduce over microsphere layers of the electrical power loss.

The US 5,002,067 describes an electrode that has a solid material helix along which one Groove runs. This groove is in the electro with an MCRD connected to the head, which dispenses a drug by the groove runs along the helix flowing into the tissue.

Another electrode with an MCRD is e.g. B. from the US 4,972,848 known. The one from the electrode head protruding screw spiral that is inserted into the tissue screwed ends in the screw head in one cylindrical cavity with a tubular Design of said monolithic device is lined. Thus, the z. B. anti-inflammato drug from the sponge-like Device exit into the cavity in which it is with the body tissue material held by the helix comes into contact. The cavity also serves as Expansion volume for the delivery of the Medications in volume increasing monolithic Facility.

US 5,009,229 describes how a cardiac electro de a polymer can be used as a drug carrier can.

Finally, in DE 91 04 976 U1 pharmaceuticals using a special cannula a medication chamber of the electrode in front of the implant tion of the same in the body of a patient splashes. Due to the necessary sealing jacket  the storage in the form of an insulating layer, through which the syringe is inserted into the reservoir, the head of such an electrode does not enlarge insignificant. The liquid then passes over one Cannula, their diameter or their outlet opening through a provided on the electrode head Screw closure is adjustable.

In all devices where a drug is used Reduction in tissue response will be administered primarily cortisone preparations such as steroids (Dexametha special derivatives) or the like, in a kind of sponge made of poly material in the manufacturing process of the electrode in the Electrode tip introduced. Phar bound in this way Makas then become after the implantation of the electrode through elution processes over appropriate membranes released the tissue.

The handling of these electrodes therefore requires one elaborate preparation of the same and the electrodes themselves are larger than medically necessary and desirable worth it.

The Erfin is based on this state of the art dung the task, a device of a to create the kind mentioned above that treat it the doctor when implanting electrodes in simp allowed a medi selected by him to give cament in the dosage that he Which slowly and during the implantation in the surrounding tissue is released, with the electrodes mechanically simple and small.

According to the invention, this object is achieved for an electrode solved according to the preamble of claim 1, that the anchoring element is a hollow spiral, the forms the capillary reservoir.  

The fact that the capillary effect to fill the Spei chers is exploited, the hollow The coil itself forms the reservoir. Are there Operator errors excluded and the filling with a drug is based on physical law moderation always uniform and uniform ten.

At the same time, the build-up of the liquid will give off Electrode considerably simplified. This leads to the cost-effective production for a safe function on.

Furthermore, in another embodiment Microsphere layers on the tip of the electrode head be provided so that the initial transition resists stood between the electrode and the surrounding tissue can be effectively reduced in size.

Further advantageous embodiments of the invention are characterized in the subclaims. Below are two embodiments of the invention based on the drawings explained in more detail by way of example. It shows gene:

Fig. 1 is a cross sectional view of the tip of an electrode according to a first Ausführungsbei game of the invention,

Fig. 2 is a plan view of the electrode head of FIG. 1, and

Fig. 3 is a cross-sectional view of the tip of an electrode according to a second embodiment of the invention.

Fig. 1 shows a cross-sectional view of an electrode head for a screw electrode 1 according to a first embodiment of the invention.

The liquid-absorbing coil is at the top of a z. B. transvenous insertable implantable or epicardial pacemaker electrode 1 , the lines one or more electrical leads 2 can have a single or multi-pole arrangement. In the illustration of corresponding leads and connectors etc. was largely dispensed with, since the execution of the same with implantable electrodes 1 is largely known.

The electrodes 1 to be used can also be other electrophysiological electrodes which are applied in the body of a living being, human or animal.

The electrodes 1 mentioned are surrounded by a physiologically inert insulation 3 . The hohlzylindri cal insulation 3 surrounds the electrode head 4 , which here has an end ring 5 and a hollow cylindrical body 6 . There are of course other Ausgestaltun conditions and geometries of the electrode head 4 possible, in particular with stepped multi-pole connecting flanges.

In the embodiment shown in FIG. 1, the electrode 1 the screw end is a 8 fixed to the electrode head 4 helix 7 as voltage Kapillaröff, wherein in one or more of these Belüftungsaus savings 9 may be provided. This, here a ventilation recess 9, is introduced into the hollow coil 7 close to the attachment of the coil 7 to the electrode ring 5 . With the choice of the arrangement of the ventilation recess 9 , a maximum filling of the coil 7 is essentially specified at the same time. After the physician has the coil 7 of the electrode 1 is filled, which is provided with the electric supply pharmaceuticals is implanted in the usual manner de. 1

The drug contained in or forming the liquid is dispensed after the implantation of the electrode 1 in the tissue by diffusion and osmosis into the surrounding body fluid and tissue.

Fig. 2 shows a plan view of the device of FIG. 1. Here, the helical coil 7 with its opening 8 and within the coil 7 of the end ring 5 can be seen. A sealing body 10 seals off the interior of the electrode head from the surroundings.

The diameter of the electrode head can e.g. B. 2 millimeters. The screw coil 7 can have an outer ren material diameter of z. B. 0.2 to 0.3 millimeters ter. The inner cross sections of the lumen of the helix 7 can then be adjusted from just under 0.15 to 0.25 millimeters. In order to achieve the capillary effect of a wetting liquid, this diameter should be small compared to the length of the capillary.

Suitable materials for designing the screw 7 are z. B. platinum, titanium, Elgiloy. The Elektro denkopf 4 is preferably made of Elgiloy, platinum, platinum-iridium, cerium, titanium or some titanium compounds or coated with the above materials.

FIG. 3 shows a cross-sectional view of a screw 1 according to a second Ausführungsbei game of the invention.

The hollow helix 7 is filled with this when immersed in a liquid, ie it rises in its inner cavity. In the embodiment shown in FIG. 3, the electrode head 4 is additionally coated with a multiple layer of microsphere layers 37 . The two layers of microsphere layers 37 indicated in FIG. 3 can be selected between one and five or more layers in other configurations. In this case, the effect of the surface tension of liquids on small spherical surfaces 37 also comes into play for filling the capillary reservoir 7 and for later delivery of the pharmaceuticals. The microsphere layers 37 shown are accumulations of spheres made of platinum-iridium with an approximate diameter of z. B. 20 to 40 microns. This creates cavities and passages between the individual balls, in which a liquid rises due to the capillary effect.

The arrangement of a capillary reservoir network with micro spherical layers 37 allows to effectively reduce the contact resistance between the electrode head 4 and the patient's surrounding tissue, with a screw fixation according to FIG. 3, the traumatic side effects when inserting the coil 7 is reduced in the patient's tissue by the medication stored in the hollow helix 7 .

When the electrode tip is immersed in a corresponding pharmaceutical suspension, the capillary reservoir described in FIGS . 1 to 3 fills by the capillary effect. The amount of liquid that can be absorbed is determined by the length and diameter of the capillary and its arrangement. With a simple capillary of diameter d and if there is a wetting liquid with surface tension σ _o and the density of the liquid δ with a gravitational acceleration of g, the capillary increase h with h = 4 · σ _o / (d · δ · g ) can be specified.

It is thus possible to use different coils 7 with 2.B. to indicate different wall thicknesses or different outer diameters, depending on the type of medication, adjusted dosages which are automatically drawn up by simply immersing the electrode tip in the medicament. This naturally also applies analogously to the absorption capacity of the microsphere layers 37 .

The drug to be administered is dispensed after implantation over time by diffusion, Osmosis or elution from the filled capillary voir.

Claims (3)

1. implantable electrode ( 1 ) for cardiology, neurology and gynecology, with an anchoring element ( 7 ) and with the help of the capillary effect with a liquid fillable memory ( 7 , 37 ), which is arranged at its distal end ( 4 ) is characterized in that the anchoring element is a hollow helix ( 7 ) which forms the capillary memory ( 7 ). 2. Electrode according to claim 1, characterized in that the hollow coil ( 7 ) in the vicinity of its BEFE stigungspunkt on the electrode head ( 4 ) has at least one ventilation opening ( 9 ). 3. Electrode according to claim 1 or claim 2, characterized in that at least part of the surface of the electrode head ( 4 ) is covered with one or more layers of microsphere layers ( 37 ) serving as a memory.