DE4231236A1 - Dual-surface impedance-monitoring electrode for high-frequency surgery - comprises interdigitated inner and outer sections of esp. neutral electrode mutually isolated by nonconductive meander region - Google Patents

Abstract

The monitoring electrode uses a rectangular flexible mat (1), e.g. of silicone is rendered conductive by embedded C particles and divided into inner and outer sections (3,4) by a meandering isolation region (2), e.g. 2 to 5 mm wide with right-angle bends. Electrical connections (10,11) are made to both sections at a common corner. The sections are of equal surface area and the outer electrode surface (4) is formed as a continuous strip (12) with projections (8) at intervals into recesses (7) in the inner section (3). ADVANTAGE - More sensitive monitoring is possible with very long linear isolation region between electrode surfaces.

Description

The invention relates to a flat electrode, in particular re neutral electrode, for high-frequency surgery with two electrically separated electrode surfaces, which with a resistance monitoring circuit for over Checking the complete installation of the electrode surfaces on Bodies are connected.

In high frequency surgery it is necessary to treat the patient ten with a flat neutral electrode that must lie on the patient over large areas in order to prevent burns in the Avoid transition area. To ensure safe and full The proper placement of the electrode on the patient must be monitored various monitoring circuits known, in which For example, it is monitored whether the elec If a constant current flows, d. H. it the symmetry of the loading of partial areas of the elec trode monitors. To improve control options it is known to increase the electrode area in larger numbers to subdivide areas (DE 37 18 585 A1, DE 37 29 516 A1, EP 0 416 159 A1).

This results in one relatively complicated structure of the electrode with a larger one Number of connections. Because of different Connection lengths and therefore different capacities  Problems can arise between the individual electrodes occur due to complicated evaluation circuits need to be wounded. In addition, such symmetry Monitoring circuits only provide information about un full contact of the electrode with the body when the detachment solution of the individual electrode sub-areas in different chem measurements.

It is also possible not to use the monitoring circuit as Training symmetry circuit, but as a resistance Monitoring circuit. When using two electric A measuring current can be measured per electrode over the first Electrode in the body and from there via the second elec trode back. The size of the current is determined by the Contact resistance between the electrode surfaces and the Body affected, so that any detachment of the electrode surface che from the body itself in an increase in resistance reflects. In this way it is easy to monitor if any part of the surface is not completely flat on the body is present.

It is an object of the invention to provide a generic electrode, which in the manner described by means of a resistance Monitoring circuit on full-area system monitored should be improved so that increased sensitivity monitoring is enabled.

This task is the one with a flat electrode gangs described type solved according to the invention in that the electrode surfaces through a linear isolation zone are electrically separated from each other, which are common direction changes essentially evenly over the extends over the entire area of the electrode.  

It has surprisingly been found that due to this special arrangement a very long line Formed isolation zone and that just this dimension decrease the sensitivity of the resistance monitoring improves. This is particularly because the cons level measurement in addition to the contact resistance between the Electrode surfaces and the body also the resistance of the Measuring current in the body between the two transition points is measured, and this resistance in the body is dependent on the distance of the current path in the body. In the field of line-shaped isolation zone, this current path is ge ring, d. H. the contribution of body resistance to the total resistance is relatively low, so that the measurement in the we considerably through the contact resistance between the Electrode areas and the body is determined. The longer the isolation zone, the greater the proportion of the measurement stromes, the human over a very short distance Chen penetrated body, d. H. overall, this allows increase the sensitivity of resistance monitoring. On the other hand, the isolation zone must of course not be that long be that the effective electrode area down too much is set, the major part of the electrode should continue to be formed by the electrode surfaces and not from the electrical isolation zone.

Characterized in that the isolation zone essentially over the The entire surface of the electrode is also secure represents that this in all areas of the electrode level monitoring with increased sensitivity can, so that detachments in all electrode areas with approximately similar sensitivity can be found can.  

In a preferred embodiment it is provided that the isolation zone is meandering.

It is advantageous if the two electrode surfaces are the same are great.

In a preferred embodiment it is provided that on at least one pair of opposite edges of the Electrode parts of the same electrode surface each other opposite. If you put the flat electrode around one The body part wraps around an arm, for example butting opposite edges of the electrode. If according to the preferred embodiment on opposite Edges of the electrode each have parts of the same electrode surface opposed to each other, only encounter diesel here ben electrode surfaces together, so that short conclusions can be avoided. It is possible that the same electrode areas over the entire edges length, but it is also with a modification possible that each electrode only over part of the Edges extend in areas directly opposite However, the edges are always the same Electrode, so that during normal winding and juxtaposition continue to ensure that only the same Touch the electrode surfaces to each other.

In a preferred embodiment it is provided that a first electrode area from a second one Chen is surrounded on all sides and that the two electrodes surfaces complementary interlocking, by the Iso lierzone separate projections and recesses in  Have direction to the other electrode surface. This will remove the entire electrode from the two electrical covered in substantially the same way, nevertheless there is a very long dividing line between between the two surfaces, along which the resistance Monitoring can be particularly sensitive.

In a further preferred embodiment, it is preseeded hen that the two electrode surfaces each on a screen te the electrode are arranged and that the two elec tread surfaces complementary, through which Isolation zone separate projections and recesses in Have direction to the other electrode surface.

It is beneficial if the projections and recesses extend over a predominant part of the electrode, so that the two comb-shaped electrode surfaces interlock.

The following description of preferred embodiments the invention serves in connection with the drawing of the detailed explanation. Show it:

Fig. 1 is a plan view of a first preferred exemplary embodiment from an electrode with two electrode surfaces and

Fig. 2 is a plan view of a second preferred embodiment of an electrode with two electrode surfaces.

The electrode 1 shown in the drawing has the shape of a flexible mat which is formed, for example, from silicone. This mat has a rectangular cross section. Conductive particles, for example carbon particles, are embedded in the silicone material, so that the material as a whole becomes electrically conductive.

A line-shaped isolation region 2, for example, has a width of 2 mm to 5 mm, with multiple right angle direction deflection so over the entire FLAE surface of the electrode 1 out that by this electrical isolation 2 two mutually completely separate Elek trodenflächen 3, are defined 4 . In the area of Iso lierzone 2 kei ne electrically conductive particles are embedded in the silicone material of the mat, so that the se isolation zone 2 is not electrically conductive and thereby electrically separates the two electrode surfaces 3 and 4 from each other.

In the embodiment of Fig. 1, the isolation zone 2 is arranged so that an inner electrode surface 3 is surrounded by egg ner outer electrode surface 4 . The inner electrode surface 3 has to the longitudinal edges 5 of the electrode 1 alternately projections 6 and recesses 7 , which complement complementary in corresponding recesses ge 9 or projections 8 of the outer electrode surface 4 , that is, one receives a meandering end in this area Isolation zone 2 .

Both electrode surfaces 3 and 4 open into terminal lugs 10 , 11 , which are connected to the poles of a resistance monitoring circuit in a manner not shown in the drawing, which is also not shown in the drawing.

The electrode areas 3 and 4 have the same area, the meandering course of the insulating zone 2 results in a long length of the contact zone between the two electrode areas 3 and 4 , so that the sensitivity of the resistance measurement is considerably increased. The insulation zone 2 extends in a substantially uniform manner across the entire area of the electrode 1 . The outer electrode surface 4 has a continuous strip 12 along all edges of the electrode 1 , from which the projections 8 emerge in the region of the longitudinal edges 5 . This ensures that when the electrode 1 is rolled up, even if the edges meet, only touches occur between the same electrode surface, the inner electrode surface 3 cannot come into contact with the outer electrode surface 4 when rolling together, although under certain circumstances abut the edges of the electrode 1 .

In the embodiment of FIG. 2, a first electrode surface 13 extends along a longitudinal edge 15 of the electrode 1 , the other electrode surface 14 along the opposite longitudinal edge 15 of the electrode 1 . Both elec trode surfaces form a continuous strip 16 along the longitudinal edge 15, protrude from the finger-like projections 17 which plunge between recesses 18 of the other electrode surface. The projections and recesses extend over most of the electrode width, so that the meandering isolating zone 2 extends between the two strips 16 essentially over the entire width of the electrode 1 . Here, too, the electrode areas 13 and 14 are of the same size and open into terminal lugs 19 and 20 , which are connected in the same way to the resistance monitoring circuit as in the exemplary embodiment in FIG. 1.

In the embodiment of FIG. 2, the same electrode surfaces are again opposite one another at the narrow edges, although both electrode surfaces occur along the narrow edges. It is essential, however, that the same electrode area is provided on opposite edges at the same height, so that when rolling together, when the edges meet, only the same electrode areas come into contact with one another.

Claims (7)

1. Flat electrode, in particular neutral electrode, for high-frequency surgery with two electrically separate electrode surfaces, which are connected to a resistance monitoring circuit for checking the complete contact of the electrode surfaces on the body, characterized in that the electrode surfaces ( 3 , 4 ; 13 , 14 ) are electrically separated from one another by a linear insulation zone ( 2 ) which, with frequent changes of direction, extends substantially uniformly over the entire area of the electrode ( 1 ). 2. Electrode according to claim 1, characterized in that the insulating zone ( 2 ) is meandering. 3. Electrode according to claim 1 or 2, characterized in that the two electrode surfaces ( 3 , 4 ; 13 , 14 ) are the same size. 4. Electrode according to one of the preceding claims, characterized in that on at least one pair of opposite edges ( 5 ) of the electrode ( 1 ) each have parts of the same electrode surface ( 3 , 4 ; 13 , 14 ) opposite each other. 5. Electrode according to one of the preceding claims, characterized in that a first electrode surface ( 3 ) by a second electrode surface ( 4 ) is surrounded on all sides and that the two electrode surfaces ( 3 , 4 ) complementary one another, through the isolation zone ( 2 ) separate projections and recesses ( 6 , 7 ; 8 , 9 ) in the direction of the other electrode surface ( 4 , 3 ). 6. Electrode according to one of claims 1 to 4, characterized in that the two electrode surfaces ( 13 , 14 ) are each arranged on one side ( 15 ) of the electrode ( 1 ) and that the two electrode surfaces ( 13 , 14 ) complement each other , by the insulating zone ( 2 ) separate projections and returns ( 17 , 18 ) in the direction of the other electrode surface ( 14 , 13 ). 7. Electrode according to claim 6, characterized in that the projections and recesses ( 17 , 18 ) extend over a predominant part of the electrode ( 1 ).