DE10252325A1 - Thermal ablation probe for minimal invasive body tissue high frequency thermal treatment has temperature sensor on star shaped flexible arms with adjustable protrusion from insulating sheath - Google Patents

Abstract

A thermal ablation probe (14) has a temperature sensor (28) on the end and metal electrodes (16) for high frequency power application with star shaped flexible arms (26) having a spiral, zigzag or meander central section (M) adjusted and retracted by a flexible adjuster (36) and protruding from an insulating sheath (18). Includes Independent claims for the manufacture of the prove using microslitting of the tube (32).

Description

The present invention relates to an endoluminal probe for high-frequency thermal ablation, also high-frequency Induced thermotherapy called, in the bio-tissue by means of heat generation high-frequency electrical fields and currents can be thermally denatured. The probe, especially in combination with flexible endoscopy technology can be used for minimally invasive thermal influencing of diseased structures in hollow organs (e.g. intestines, bronchi, Trachea, esophagus) or in larger veins or arteries due to radio frequency energy in the frequency range of 300 kHz to 1 mHz.

It is the object of the invention an inexpensive producible endoluminal probe for high-frequency thermal ablation to accomplish.

This task is solved by the features of claim 1 and in particular in that the probe has an insulated tube at the distal end End is provided a metal electrode, the spatial Extension from a cylindrical shape to a star shape variable is. Due to the cylindrical shape of the metal electrode small-lumen navigation of the probe within a biological lumen or about the instrument channel of an endoscope possible. After positioning the electrode in the target area can then be deployed to the star-shaped Shape. In particular through the star-shaped electrode particularly good effects are achieved with thermal ablation, being an additional Advantage of changeable Diameter of the star-shaped electrode is. This allows a locally defined and intraluminal electrical conductive Electrode contact despite anatomically variable biological environment getting produced.

The metal electrode is in accordance with the invention multiple flexible arms formed, the distal and proximal ends are interconnected, the distal and / or the proximal Ends of the arms electrically with a connector for feeding one High frequency current are connected. Form according to the invention hence the flexible arms themselves the electrode, i.e. H. there are not any additional point electrodes or the like is required. This is the one hand, the production simplified the probe. On the other hand, it can be cleaned easily become.

After the therapeutic energy application the unfolding of the metal electrode can be reversed, whereby removal of the probe from the cavity is easily possible.

Advantageous embodiments of the invention are described in the description, the drawing and the subclaims.

According to a first advantageous embodiment can be the shape of an arm approximately in the middle of its shape both ends differ. This is due to the shape of the arm itself a bending behavior specified that the star-shaped design of the metal electrode favored. For example can the outer contour of an arm roughly in the middle, roughly spiral, zigzag, wave or be meandering, being the outer contour is straight at both ends of the arm. Through a Such a central region of an arm can be rigid be adapted to the requirements.

According to a further embodiment of the invention the distal and proximal ends of the arms using one on one proximal area of the hose provided actuator be adjustable relative to each other. This allows the outside diameter the metal electrode vary and the spatial extent of the cylindrical Shape to the star-shaped Change shape.

According to a further embodiment of the invention are the proximal ends of the arms with a flexible cannula connected, which is guided within the hose. This embodiment has the advantage of flushing liquid inside the flexible cannula and / or a further control element for moving the arms can. For example the distal ends of the arms connected with a flexible actuator be guided inside the tube or inside the cannula. That way the outside diameter change the metal electrode, without necessarily moving the hose with it.

According to a further embodiment The invention can be a temperature sensor in the region of the distal ends of the arms be arranged. Such an arrangement additionally enables temperature control or an automatic temperature control via a trained one High-frequency generator.

It can also be advantageous if a proximal end of the probe is provided with a connection for rinsing liquid. This rinsing liquid can be conveyed through the hose or the cannula provided in the hose in the direction of the metal electrode in order to avoid drying out and loss of electrical conductivity in the ablation zone. An electrode for a probe of the type described above can advantageously be produced thereby be that a flat blank or a cylindrical cannula made of electrically conductive material is provided with parallel microcuts, the ends of which do not extend to the edge of the blank or the cannula. In this way, individual webs are formed between the microcuts, which serve as arms of the probe. It can be advantageous here if the microcuts are spiral, meandering, wavy or zigzag in a central section be formed in a zag shape. This creates flexible metal bars in the middle of the arms. In order to make the middle sections of the arms particularly flexible, it can also be advantageous to choose the thickness of the micro sections larger in a middle section and smaller in the end sections.

Below is the present Invention by way of example using an advantageous embodiment and described with reference to the accompanying drawings. Show it:

1 a schematic view of a device for high-frequency thermal ablation;

2 a partially sectioned view of a distal end of a probe in which the metal electrode has a cylindrical shape; and

3 the probe of 2 , wherein the metal electrode is unfolded into a star shape.

1 shows schematically a system for high-frequency thermal ablation with a high-frequency generator 10 , a neutral electrode 12 and an endoluminal probe 14 , at the distal end of a metal electrode shown only schematically 16 is provided. The metal electrode 16 is located at the distal end of an insulating tube 18 , at the proximal end of a handpiece 20 is provided. The handpiece 20 has a connection for a high-frequency cable 22 on that the high frequency generator 10 electrically with the metal electrode 16 combines. The neutral electrode 12 is via a neutral electrode cable 24 with the high frequency generator 10 electrically connected.

2 shows a perspective view of the distal area of the probe 14 , where the metal electrode 16 folded into a cylindrical shape and inside the tube 18 withdrawn. A part of the hose is shown for better illustration 18 shown broken.

3 shows the probe of 2 , but with the metal electrode 16 out of the hose 18 is pushed out and unfolded into a star shape. As in the 2 and 3 you can see the metal electrode 16 with six flexible arms, for example 26 formed the in 2 coaxial to the axis of the hose 18 run, which however in 3 predominantly project radially and in a star shape from the central axis of the probe. All arms 26 are at their distal ends via a pot-like end piece 28 connected with each other. The distal ends of the arms 26 are over a sleeve-shaped end piece 30 also connected to each other. The poor 26 as well as the end pieces 28 and 30 which are all connected to one another in one piece, thus form the metal electrode 16 which, due to its extremely compact design, can be guided through the instrument channel of an endoscope.

As especially in the 2 and 3 you can see that every arm is there 26 from a thin metal strip with a rectangular cross-section, the shape of each arm 26 approximately in the middle M deviates from the shape at the two ends of the arm. The outer contour of each arm 26 is formed wave-shaped approximately in the center M, while a section with a straight outer contour adjoins the wave-shaped area in the center M on both sides. Here, the section with a wavy outer contour has about a third of the total length of the arm 26 on.

Due to the wavy outer contour of the arms 26 in the central area M the arms can be joined to the in 3 bend arrangement shown, in which the wavy portion is U-shaped curved and the arms protrude approximately at right angles from the central axis of the probe. In contrast, the metal electrode 16 in the in 2 illustrated state, in which it is retracted into the interior of the tube, a cylindrical shape in which the individual arms 26 run parallel to each other and rest against each other with only a small distance.

The proximal end piece 30 the metal electrode 16 is with a flexible cannula inside the tube 32 connected with a push handle 34 ( 1 ) of the handpiece 20 communicates. The distal end piece 28 the metal electrode 16 is with a flexible control element 36 connected that inside the cannula 32 is guided and its proximal end with a push handle 38 is connected, which is also on the handpiece 20 is provided. The actuator 36 and the cannula 32 are inside the handpiece 20 mechanically detachable with the push handles 34 and 38 connected, the push handles can be operated with one hand individually and relative to each other. The proximal end of the tube 18 is with the housing of the handle 20 releasably connected. Within the handle, which is not shown, is an electrically conductive connection between the cannula 32 and the metal electrode cable 22 intended.

By moving the push handles relatively 34 and 38 to each other and relative to the handpiece 20 can the metal electrode 16 from the in 2 shown position in which it is completely inside the hose 18 located in the in 3 shown arrangement are moved, in which the metal electrode 16 from the distal end of the tube 18 protrudes and has a star shape.

In the area of the handpiece 20 can also be a connection 40 be provided for rinsing liquid through which, for example, physiological saline solution in the area of the metal electrode 16 can be brought.

The hose 18 the probe 14 consists of flexible, insulating material. The metal electrode 16 and the cannula 32 are made of a super-elastic material that conducts electricity, such as a nickel-titanium alloy. The actuator 36 can be wire-shaped or cannula-shaped be made of flexible metal or plastic. The handle 20 and the push handles 34 . 38 consist of insulating plastic.

The probe 14 Depending on the application, the overall length may vary up to about 200 mm and the probe diameter may be up to about 3 mm. The metal electrode 16 can have a length of about 20 to 35 mm. The outside diameter of the metal electrode 16 can be, for example, 1.8 mm. From the in 2 The configuration shown can be the metal electrode by compression to the in 3 shown, star-shaped arrangement are converted, in which the electrode star has an axial length of about 8 mm and a diameter of up to 30 mm.

The production of the metal electrode according to the invention 16 can be done, for example, by providing a flat blank, for example a thin metal foil, or a cylindrical cannula, each made of electrically conductive material, with microcuts running parallel to one another, the cuts not ending at the ends of the blank or the Extend cannula. If these cuts are evenly distributed over the circumference of the cannula or over the extent of the blank, strip-like material sections are created between the individual cuts, which arms 26 form. These microcuts can be spiral, meandering, zigzag or wavy in a central section (cf. 2 and 3 ) are formed, whereby the above-described middle portions of the arms can be formed. The blank can then be formed into a sleeve.

It can also be beneficial be the thickness of the micro section along its length to vary. For example, the thickness of the micro section in the middle section M larger than in Range of end sections selected be creating an additional Variation in elasticity behavior of the poor possible is.

The method of operation of the probe described above is described below using the example of endoluminal radio frequency thermoablation: After the patient to be treated with an adhesive and large-area neutral electrode 12 is in contact with the skin, which is as short as possible to the metal electrode 16 should take place, the patient is after connecting the neutral electrode cable 24 to the neutral electrode 12 and to the high frequency generator 10 an integral part of the high frequency circuit.

The probe according to the invention is then navigated via the instrument channel of a flexible endoscope - or in the case of interventional therapies under image control (sonography, computer tomography, magnetic resonance tomography) via body cavities or vessels to the target area. Then the metal electrode 16 by operating the push handles 34 and 38 extended and unfolded so that it contacts the biogenic tissue to be treated or pathogenic, for example within the esophagus. A high-frequency current is then activated on the HF generator for a defined time or until a predetermined electrical impedance level or energy level or also temperature level is reached. The high-frequency current flows inside the probe 14 via the star-shaped metal electrode 16 to the contacted biological tissue and via the neutral electrode 12 back to the RF generator 10 , With the square of the RF current and proportional to the current contact impedance of the electrode-bio-tissue as well as proportional to the activation time, localized heat effects arise, whereby at temperatures reached over 50 ° C, preferably in the range 60 ° C to 100 ° C, the bio-tissue is thermally denatured. After exposure to the HF current for a few seconds, bio-tissue shrinkage and drying out are achieved in the narrow contact area of the electrodes. This means that malignant organic tissue (primary tumors, metastases) can also be thermally destroyed, or thermal hemostasis or therapeutic tissue shrinkage with tolerable scar formation can be generated.

10

RF generator

12

neutral electrode

14

probe

16

metal electrode

18

tube

20

handpiece

22

Metal electrode cable

24

Neutral electrode cable

26

poor

28

distal tail

30

proximal tail

32

cannula

34

push handle

36

actuator

38

push handle

40

connection for rinsing liquid

M

middle Area

Claims (11)

Probe ( 14 ) for high-frequency thermal ablation with an insulating tube ( 18 ) with a metal electrode at the distal end ( 16 ) is provided, the spatial extent of which can be changed from a cylindrical shape to a star-shaped shape, the metal electrode ( 16 ) by several flexible arms ( 26 ) is formed, the distal and proximal ends of which are connected to one another, the distal and / or the proximal ends of the arms ( 26 ) are electrically connected to a connection for supplying a high-frequency current. Probe according to claim 1, characterized in that the shape of an arm ( 26 ) about in the middle ( 11 ) deviates from its shape at both ends. Probe according to claim 1, characterized in that the outer contour of an arm ( 26 ) about in the middle ( 11 ) is roughly spiral, zigzag, wavy or meandering and straight at both ends. Probe according to claim 1, characterized in that with the aid of a on a proximal region of the tube ( 18 ) provided actuator ( 34 . 38 ) the distal and proximal ends of the arms ( 26 ) are adjustable relative to each other. Probe according to claim 1, characterized in that the proximal ends of the arms ( 26 ) with a flexible cannula ( 32 ) connected within the hose ( 18 ) is performed. Probe according to claim 1, characterized in that the distal ends of the arms ( 26 ) with a flexible control element ( 36 ) connected within the hose ( 18 ) is performed. Probe according to claim 1, characterized in that in the area ( 28 ) the distal ends of the arms ( 26 ) a temperature sensor is arranged. Probe according to claim 1, characterized in that its proximal end with a connection ( 40 ) is provided for rinsing liquid. Method of making an electrode for a probe according to claim 1, characterized in that in a flat blank or a cylindrical cannula made of electrically conductive material running parallel to each other Micro-cuts are introduced, which are located at their ends, respectively do not extend to the edge of the blank or cannula. A method according to claim 9, characterized in that the microcuts in a middle section are spiral, meandering, wavy or zigzag be formed. A method according to claim 9, characterized in that the thickness of the micro sections in a middle section is larger and chosen lower in end sections becomes.