DE202010016945U1 - Transthoracic AFIB Cardiac Catheter - Google Patents

Abstract

Flexible heart catheter (24), which is placed on the outside of the left atrium of a heart with the aid of two preformed guidewires, has a number of electrical contact points and with the aid of which and application of high-frequency current can be eliminated atrial fibrillation, characterized in that by means of two Preformed guidewires, which are each provided with a distal magnet, a cohesive connection which completely surrounds the left atrium and serves as a tension element for the actual catheter, which is directed as a flat tube in the longitudinal direction of the surface of the heart muscle, openings through which from the inner electrode against an outer indifferent electrode high-frequency current flows, which heats the outer tissue of the heart muscle and by a slow pulling movement of the inner electrode over the entire openings of the catheter lying a thin line of ablated tissue on the ge created velvet forecourt.

Description

The invention

The invention relates to a flexible cardiac catheter placed with two preformed guide wires on the outside of the left atrium in the human heart, having a number of electrical contact points and with the aid of which and the application of high frequency current can be eliminated atrial fibrillation.

How has the problem been solved?

Atrial fibrillation occurs relatively frequently. Overall, atrial fibrillation seems to have increased in recent years, which is explained by an aging patient group. Atrial fibrillation leads to a rapid transfer of the excitation to the ventricles, so that it can lead to acute hemodynamic instability. The ablation of atrial fibrillation by radiofrequency ablation has hitherto been performed by a catheter inserted in the left atrium, which ablates other parts of the left atrium in addition to the pulmonary vein exits according to the so-called "Mace Procedure". It is important that the ablation is not punctiform but in lines. The necessary precise manipulation of the catheter is very difficult and therefore requires a lot of time. In addition, exposure to X-rays is very high for the patient and the doctor.

Walkthrough

It is therefore an object to provide a catheter of the type mentioned, which makes it possible to eliminate the atrial fibrillation in humans easier, faster and with little or no X-ray exposure. To solve this problem, it is provided that by a minimal surgical intervention from the chest side, a catheter is introduced outside the left atrium of the heart and there surrounds the pulmonary veins. The catheter is flat, very flexible, and has a number of electrical contact points that rest upon placement on the tissue of the outer atrium. If a high-frequency current of approximately 500 kHz is applied in each case between two adjacent poles, the tissue is heated and a type of line of ablated tissue is formed, which in turn results in a desired physiological line interruption. As electrodes encircle the entire left atrium, one will eventually reach a "line" around the entire left outer atrium as the RF application continues. With the same or a similar catheter, an additional line of ablated tissue can be created between the pulmonary veins in front of the entrance of the left atrium. The electrical contact points of the catheter may be configured to be realized by a plurality of fixed poles on the catheter surface or formed by one or more poles displaceable on or within the catheter, which may be displaced from contact point to contact point during the ablation procedure. In the case of displaceable poles in the catheter shaft, openings in the catheter shaft must be provided for this purpose at the intended electrical contact points.

Explanation of an Exemplary Catheter Placement

The insertion of the catheter is done by a minimal surgical procedure from the left side of the chest. First, endoscopically access to the outer left atrium. Thereafter, a guiding catheter, which can be controlled by differently shaped stylets depending on the anatomy, is placed above the two pulmonary veins. Another catheter of the same type is placed below the pulmonary veins. The stylets in the two catheters are replaced by guidewires distally provided with a magnet (alternative capture mechanisms are possible). Cleverly manipulating the two guidewires and attracting the magnets, a coupling is achieved so that one of the two guidewires can be pulled completely around the four pulmonary veins. It is now possible to place the aforementioned ablation catheter around the four pulmonary veins. This is done, for example, by fixing the ablation catheter to the end of the guidewire, or by replacing the guidewire with a surgical suture and connecting the catheter to it and pulling it around the atrium. The types of electrodes described herein for generating continuous lines of ablated tissue are not limited to this application but may be applied to other parts of the human body.

advantages

The great advantage of the invention is that with the help of a single conventional RF generator, a continuous "line" can be pulled. If cooling or drug delivery is necessary, this can be done through the open holes in the catheter.

drawings

Further details, features and advantages of the invention can be taken from the following description part in which reference to the drawings and embodiments, the invention is explained in more detail. They show in a schematic representation in

1 , an exemplary representation of guidewires with distal magnets.

2 , an exemplary representation of two guide wires around the left atrium of the heart before the magnetic coupling.

3 , an exemplary representation of the guidewire on the left atrium of the heart after the magnetic coupling and the entire circumference of the four pulmonary veins comprising.

4 , an exemplary representation of the catheter, which is pulled around the atrium with the help of the guide wire.

5 , an exemplary illustration of catheter positions with an inner bipolar electrode and multiple windows in the shaft tube.

6 , an exemplary illustration of catheter positions with an inner unipolar electrode and a window in the shaft tube.

7 , an exemplary view of catheter positions with another inner unipolar electrode and several windows in the shaft tube.

8th , an exemplary view of a catheter with an inner sliding electrode and a slotted shaft tube.

Description of the picture

1 , shows an exemplary representation of guidewires with distal magnets. It is advantageous if the guide wire as a helix ( 1 ) with a magnet ( 2 ) is formed on the distal part, and by a shaped inner stylet ( 3 ) can be controlled.

2 , shows an exemplary representation of two guide wires around the left atrium ( 4 ) of the heart before magnetic coupling ( 5 ).

3 shows how by clever manipulation of the two guide wires and the magnetic attraction of the magnets, a coupling can be achieved so that one of the two guide wires ( 6 ) can be pulled completely around the four pulmonary veins.

4 shows the ablation catheter ( 24 ) as it is placed around the four pulmonary veins. This can be achieved, for example, by placing it at one end of the in 3 fixed guide wire is fixed to then lead by train on the guide wire, the catheter around the atrium. It is also conceivable to replace the guide wire previously by a surgical thread.

5 , shows an exemplary representation of a catheter with an inner bipolar electrode ( 8th ) and holes in the shaft tube ( 9 ). Now, if the bipolar electrode located inside the catheter shaft has the same electrode spacing as the holes in the tube, positioned over two adjacent holes, then the electrical current will pass essentially through the two holes through the underlying tissue. 10 ) flow. After applying a suitable amount of energy, which is measured by a temperature sensor ( 11 ), the inner bipolar electrode is passed over the next two holes ( 12 ) and supplied with electric current. This happens until over the entire circumference of the left atrium, the desired line of ablated tissue ( 25 ) arises. A possibly advantageous cooling can also be applied through holes.

6 , 3 shows a further exemplary illustration of a catheter with an inner unipolar helix electrode (FIG. 13 ) and a window ( 14 ) in the shaft tube. The indifferent electrode ( 15 ) is located either on the outside over a large area on the chest, back of the patient or in the form of a balloon in the esophagus. This achieves a further form of line shaping. Is a high-frequency electric current between inner electrode ( 13 ) in the shaft and an indifferent electrode ( 15 ) and the shaft with the window cutout ( 14 ) are drawn around the entire circumference of the atrium, this also yields the desired line of ablated tissue ( 25 ).

7 , an exemplary representation of catheter positions with an inner unipolar electrode ( 16 ) and several windows ( 17 ) in the shaft tube. The indifferent electrode ( 15 ) is the same as in 6 , shown. Is a high-frequency electric current between inner electrode ( 16 ) in the shaft and an indifferent electrode ( 15 ) and the electrode ( 16 ) in the shaft at the window cutouts ( 17 ) are drawn around the entire circumference of the atrium, this also yields the desired line of ablated tissue ( 25 ). An integrated temperature sensor ( 18 ) in the electrode ( 16 ) provides the selected ablation temperature through the power control in a high-frequency generator (eg HAT 300 from Osypka AG).

8th , shows another exemplary representation of a catheter for creating an ablated line in the tissue ( 25 ) by means of an inner sliding different electrode ( 19 ) and a longitudinally slotted shaft tube ( 20 ). The electrode ( 19 ), which can be moved in the longitudinal direction and a part of which is guided through the longitudinal slot to the outside and thereby touches the tissue of the atrium, forms a pole of the high-frequency current. The indifferent electrode ( 15 ) is z. B. in the esophagus (not shown here). If a high-frequency current (eg 500 kHz) is flowing, it will be switched off with the appropriate speed and temperature monitoring ( 21 ) the electrode is drawn around the entire atrium, this also yields the desired line of ablated tissue ( 25 ).

Literature:

• Grischen R Veldtman, Amanda Hartley, Naheed Visram and Lee N Benson Radiofrequency applications in congenital heart disease. Expert Rev. Cardiovasc. Ther. 2 (1). 117-126 (2004)

Claims (9)

Flexible heart catheter ( 24 ), which is placed on the outside of the left atrium of a heart with the aid of two preformed guidewires, has a number of electrical contact points and with whose help and the application of high frequency current can be eliminated atrial fibrillation, characterized in that by means of two preformed guidewires are each provided with a magnet, a cohesive connection which completely surrounds the left atrium and serves as a tension element for the actual catheter, which is directed as a flat tube in the longitudinal direction of the surface of the heart muscle, openings through which of the inner electrode against an outer indifferent electrode radiofrequency current flows, which heats the outer tissue of the heart muscle and generates a thin line of ablated tissue over the entire atrium by a slow pulling movement of the inner electrode over the entire openings of the lying catheter. Catheter according to claim 1, characterized in that the shaft of the catheter consists of soft plastic material, preferably silicone, Catheter according to Claims 1 to 2, characterized in that the shaft of the catheter has in longitudinal direction a series of openings which have a diameter of at least 0.1 mm and a spacing of at least 0.2 mm. Catheter according to claim 1 to 3, characterized in that the inner electrode relative to the shaft tube is displaceable in both directions and has at least one pole. Catheter according to claim 1 to 4, characterized in that the inner electrode is formed of metal in the form of helix, strand, wire or laser-cut cannula. Catheter according to claim 1 to 5, characterized in that the inner electrode contains a temperature sensor. Catheter according to Claims 1 to 6, characterized in that the outer shaft contains temperature sensors at the openings. Catheter according to claim 1 to 7, characterized in that fluids can be transported between the outer shaft and the inner electrode lead. Catheter according to claim 1 to 8, characterized in that these types of electrodes can also be used for the stimulation of cardiology, neurology or other organs.

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