DE3415410A1 - Pacemaker electrode - Google Patents

Abstract

In such an electrode with flexible fixing elements which project outwards at an angle relative to the longitudinal axis of the electrode feed line in a direction opposite to the insertion direction of the electrode and have a cross-section which is larger than the cross-section in the radial direction as related to the tangential direction of the electrode feed line, the flexural strength of the fixing elements decreases with increasing distance from the connecting point to such an extent that, in the event of forces acting upon the fixing elements in the insertion direction, a fairly large portion of the curvature forming over the longitudinal extension of the fixing elements occurs in the vicinity of the region on which the holding force acts.

Description

description

The invention relates to a pacemaker electrode in the preamble of claim 1 specified Art.

Such electrodes are available in various designs - for example from U.S. Patent No. 4,301,815.

The disadvantage here, however, is that the flexural rigidity of the fastening elements is almost constant over its length.

This leads to the fact that the fasteners in the longitudinal direction (parallel to the supply line) acting forces from its proximal end show relatively rigid behavior, as they (depending on the formation of the foot point) behave like a rod clamped more or less flexibly at one of its ends. In the event of a load due to deflection via a transverse component having forces takes place the deflection due to the moment ratios, preferably by elastic deformation in the base. This mechanical characteristic is used in a fastener with an essentially round cross-section most appropriately with the designation ~ bristle " characterized.

The pacemaker electrodes concerned are used for electrical connection between heart muscle and artificial pacemaker for signal transmission in both Directions. The electrode head should be in the ventricle or in the atrium hold, whereby in the first-mentioned part there must be a catch in the trabecular structure and the stimulation area also in those associated with cardiac activity on tensile forces acting on the supply line must ensure a firm anchorage.

In Figure 1 is shown in different steps, how the Above known electrodes behave when they are under tension and pieces of tissue are available for "hooking" in the direction of the supply line have different radial and axial positions.

In the figures la to e it is shown in particular schematically, how a known "bristle" electrode behaves when it is withdrawn, when parts of tissue offer resistance.

In Figure la, the electrode 1 is located between two pieces of tissue 2 and 3, which are on different sides of the electrode lead and its axial Direction are offset by a distance (2 and 3). At the electrode head 4, which contains the stimulation surface, fastening elements 5 and 6 are provided, wherein the fastening element 5 is in engagement with the tissue part 2, while the Fastening element 6 is out of engagement. The spatial shown in Figure la Tissue conditions have the effect that when the electrode lead is pulled the electrode head moves downwards in the drawing. Since with over the longitudinal extent of the fastener of constant flexural rigidity with soft fastening the The fastening element is deflected essentially in the region of its root and the force to be applied to deflect due to the existing moment relationships the further it gets, the smaller it gets Fastener deflected is, the retention effect of the bristle 5 is reduced, the electrode head 4 becomes additionally deflected and the fastening element 6 comes into engagement with the tissue part 3 (figure lb).

While with further retraction of the electrode the fastening element 6 offers the greatest resistance is the holding effect of the fastening element 5 almost completely overcome. It works when the electrode is withdrawn further around 1800 without substantial resistance and continues to withdraw further so there is no longer any holding force against it.

Since now only the fastening element 6 with the fabric part 3 is engaged, the electrode head 4 inclines in FIG the drawing upwards, the fastening element 6 is also deflected and with increasing deflection, a reduced retention force applies (Figure ld). This resistance is also essentially overcome, both fastening elements 5 and 6 are now folded forward and no longer offer any support for the electrode head. Any holding effect of the electrode has been lost and this can almost be done Pull out without resistance, because of the preferred mobility of the fastening elements the fastening elements at the base and the occurrence of other obstacles formed by tissue 5 and 6 cannot return to their original position and thus the way to full electrode retraction is enabled.

The invention, the solution features of which are in the characterizing part of the claim 1 are given, is based on the task of an electrode of the initially specified genus, the fastening elements of which are also used in relation to the In the longitudinal direction of the electrode lead, the electrode can be withdrawn obstructing tissue obstacles allows an improved frictional connection, with in particular the distribution of the tensile force exerted on the supply line over several Fasteners should always be guaranteed.

It is particularly advantageous in the invention that point loads are avoided and, in a preferred embodiment of the electrode, the bearing surfaces the holding means in relation to the tissue obstacles with the occurring load gain weight. The retention effect is particularly important in the case of a "lamellar" The design of the fastening elements is improved, as this is done with increasing bending also increases the width of the adjacent leaflet parts, so that the holding effect is awarded up to the intended border forces.

The invention is based inter alia on the knowledge that when the Flexural stiffness - related to the differential elements of the fastening elements in the longitudinal direction of the electrodes - towards the root of the same becomes larger, each one increasing bending causing greater forces in closer to the root point of the Fastening elements - and thus as a smaller moment - become effective, so that the corresponding moment deflecting the electrode head from the longitudinal direction of the line increases less than the restraint forces to be absorbed.

According to a further preferred embodiment of the invention, the Fastening elements on a profile to increase the longitudinal stiffness, its stiffening effect can be gradually reduced when the fastening elements are bent from the end regions is. This configuration takes place favorably in such a way that the sheet-shaped Fasteners have a curvature about an axis that is substantially parallel is directed to the longitudinal axis of the electrode lead, this curvature being with leveling up the fastening elements and thus their stiffening effect is decreased. In a preferred embodiment of the invention, the Differential change in flexural rigidity is essential in the change the forces necessary to level the curvature, namely when this leveling with an elastic deformation of the relevant wall areas of the fastening elements connected is.

These forces become greater, the greater the relative thickness of the Fasteners is. While the stability through with low material thickness Curvature or fold comparable to that of a correspondingly shaped sheet of paper is what loses all stability when it is leveled and this leveling is possible almost force-free, with greater material thickness for "leveling" Forces necessary with increasing width of the fastener - so too towards its root - also become larger.

Other advantageous developments of the invention are set out in the subclaims marked or are shown in the following illustration together with a preferred embodiment of the invention described in more detail. Show it: figure 2a shows an advantageous embodiment of the invention, FIG. 2b shows a detail of the Embodiment according to Figure 2a, as well as Figures 3a and 3b, two positions of the electrode according to the invention when holding forces occur according to the illustration according to the figures la to f.

In the embodiment shown in Figure 2 is the invention Cardiac pacemaker electrode 10 shown in a schematic representation. The one Electrode head 11 having an electrically conductive contact surface forms the front electrode head Termination of an electrode lead, which is coated with insulating material. The cut The end shows part of the supply coil 13, which is connected to the conductive electrode head 11 is connected. In the area of the electrode head there are holding means 14, 15, 16, etc. another corresponding one arranged on the back and therefore not visible Element provided distributed evenly on the electrode circumference. The electrode 10 is advanced in the direction of arrow 17 through the vein into the right ventricle, to get caught there. The fastening elements 14 to 16 point in one direction which point and form essentially opposite to the direction of insertion - starting from the electrode head - an angle of about 350 to the axis of the electrode lead. The elements have a larger dimension in the tangential direction than in the radial direction Direction, so that accordingly the bending stiffness with respect to acting tangentially Forces is significantly increased.

The bending stiffness in relation to deflection by forces, which act in the direction of arrow 17 on the fastening elements is - based on the longitudinal direction of the fastening elements - variable .. Here is the bending stiffness at the end of the sheet-shaped fastening elements the least, so that when force is applied at the outermost end a folding takes place, as it is in the detailed representation of a single one Fastening element according to Figure 2b can be seen.

While with the known fastening elements of pacemaker electrodes When deflected from the end, the area of maximum bending is in one of the end remote zone is, "rolls" in the arrangement according to the invention, the sheet-shaped Fastening element from the end, so that the force acting here is always applied sufficient resistance regardless of the degree of deflection of the fastener is opposed. This relationship is illustrated in Figures 3a and 3b, where in Figure 3a an electrode 10 with fastening elements 14 and 16 is located schematically illustrated tissue obstacles 2 'and 3' against an opposite one Insertion direction acting force is supported.

Since the torque is introduced by both fastening elements 14 and 16 on the longitudinal supply line - essentially independent of the intensity their deformation - takes place, the direction of the electrode's longitudinal axis remains almost constant, so that in this respect there is also no one-sided shift of the to be applied Forces occurs. In addition, the support areas are not punctiform, what in extreme cases could lead to a puncture of tissue, but that the support area comprises a surface which is to be received with the Force increases because the holding element and the support surface are increasingly curled up is increased. This ensures an effective holding mechanism.

Only when the retraction force is further increased - what with the intentional Pulling out the electrode may be the case - fold the fasteners 14 and 16 completely forward, as can be seen in Figure 3b. This Folding takes place with a relatively small swivel radius, so that as well there is no point-wise stress due to the bristles protruding to the outside, as is the case with the prior art electrodes. The holding effect the electrode is thus guaranteed to be constant up to a constructive level to be specified Maximum force at which a soft yield occurs without force peaks occurring or the electrode head due to undesired lateral deflections at lower levels Retention forces would come free, as can be seen from Figures la to e.

The inventive effect is further supported by the fact that the Fastening elements have a shape which increases the transverse rigidity is changed with the deflection process so that the transverse rigidity is reduced will. This can be seen in Figure 2b, the fastening element shown there 14 has a curvature or bend in cross section, which extends in the area level in front of the bent end so that the Fastener deforming force gradually reduces the transverse rigidity of the fastener 14 effected from its outer end.

In this case, with a relatively greater thickness of the leaflet-shaped fastening elements also the elastic deformation forces required for "leveling" at the root point increasing. In this way it is also ensured that the result of Loads occurring forces generate a deformation, which initially on the outer end portion of the fastener is concentrated, so that the previously described equalizing effect when holding forces occurring and the moments acting on the supply line for the total number of holding elements is enlarged.

The embodiment of the invention is not based on the illustrated embodiment limited, but can be used in a variety of other configurations Find.

Claims (4)

Pacemaker electrode claims with pacemaker electrode at an angle to the longitudinal axis of the electrode lead opposite to the direction of insertion the electrode towards outwardly protruding flexible fastening elements with a cross-section, related to the tangential direction of the electrode lead, greater is than the cross section in the radial direction, d u r c h e k e n n z. e i c h n e t that the flexural rigidity of a fastening element (14, 15, 16) increases with increasing Distance from the connection point decreases in such a way that at one in the insertion direction the holding force acting on a fastening element is the greater part of the over the longitudinal extension of the fastening elements forming curvature in the vicinity of the area of application of force occurs. 2. pacemaker electrode according to claim 1, d a -d u r c h g e it is not indicated that the fasteners are in the tangential direction are tapered leaf-shaped towards their free end. 3. pacemaker electrode according to claim 2, d a -d u r c h g e it is not indicated that the area of the fastening elements which the having the largest dimension in the tangential direction, mechanically with the sheathing (12) of the electrode head or the lead is connected. 4. pacemaker electrode according to one of the preceding claims, d a d u r c h e k e n n n z e i c h -n e t that the flexural rigidity of the fastening elements (14) increasing forces acting in the direction of insertion of the electrode Curvature (Fig. 2) is provided, which is related to the forces exerted by the free At the end, increasing with the bend of the ends about a tangentially directed axis leveled, so that in the leveled area the flexural strength compared to the not arched areas is also reduced.