NL1026422C2 - Device for creating a locally cold plasma at the location of an object. - Google Patents

Description

Brief indication: Device for creating a locally cold plasma at the location of an object.

DESCRIPTION

The invention relates to a device for creating a locally cold plasma at the location of an object comprising at least a high-frequency power source, a plasma chamber, a plasma-electrically connected to the high-frequency power source and arranged in the plasma chamber. a discharge electrode, as well as a plasma gas supply terminating in the plasma chamber near the plasma discharge electrode.

A device of the aforementioned preamble is known, for example, from U.S. Patent No. 5,977,715. From this patent specification a hand-operated device is known, with which a (cold) plasma can be applied locally at the location of an object. The known device is characterized by a limited manageability and therefore controllability of the created plasma at the location of the object.

The invention therefore has for its object to provide an improved device 20 according to the preamble above which makes it possible to better control the created plasma relative to the object. To this end, the device according to the invention is characterized in that the device is provided with adjusting means which are adapted to automatically orient the plasma discharge electrode relative to the object.

More in particular, according to the invention, the adjusting means comprise at least one sensor for determining the instantaneous orientation of the plasma discharge electrode relative to the object, the adjusting means being adapted to orient the plasma discharge electrode on the basis of the determined current position.

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The at least one sensor can herein be adapted to measure the power recirculated by the created plasma, which recirculated power is a measure of the current orientation of the plasma. > plasma discharge electrode with respect to the object.

The adjusting means are then arranged for orienting the plasma discharge electrode on the basis of the determined instantaneous position, while in a specific measuring principle according to the invention the adjusting means are arranged for orienting the plasma discharge electrode by comparing the recirculated electrode. power with the power supplied to the plasma discharge electrode from the high frequency power source.

With these aspects of the device according to the invention it becomes possible to accurately orient the created plasma with respect to the object with which the plasma is to react.

In a first embodiment, the adjusting means may comprise at least one stepping or DC motor. On the other hand, the adjusting means may comprise at least one memory metal or at least one voice coil.

In a functional embodiment that permits adequate orientation of the plasma with respect to the object, the adjusting means are arranged around the plasma discharge electrode.

According to the invention, a special embodiment of the device comprises a catheter which is composed of an outer casing, a proximal end and a distal end, which catheter can be inserted into the human or animal body with the distal end and wherein at least the plasma discharge electrode is received in the distal end of the catheter.

Furthermore, because the distal end of the catheter forms the plasma chamber, with this embodiment a plasma close to an organ or tissue can be created in the human or animal body very effectively and controllably, which makes the device more versatile for use in, for example, medical treatments in ! 'the body of a human or animal.

. In the embodiment, not being a catheter, the

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A device with the plasma chamber disposed outside the body of a human or animal in close proximity to the skin or external organ, so that this embodiment is very suitable for applying cosmetic treatments (removal of tissue).

In order to bring the created plasma sufficiently close to the object (organ or tissue), the distal end of the catheter is at least partially open.

More specifically, for controlling the plasma discharge electrode, a coaxial transmission line assembled from an inner conductor and an outer conductor 15 arranged coaxially around the inner conductor is included in the catheter, the plasma discharge electrode being via the inner conductor. Each is electrically connected to the high-frequency power source.

For the effective and favorable generation of the plasma near the distal end of the catheter, the supply for the plasma gas can also be included within the outer conductor located in the catheter. More specifically, the outer conductor thereby forms the circumferential sheath of the catheter.

These embodiments are intended to provide a compact construction with sufficiently small outer dimensions, whereby the introduction of the catheter into the human or animal body is not hampered.

In another functional embodiment, the supply for the plasma gas is included outside the outer conductor located in the catheter, the supply for the plasma gas being arranged coaxially around the outer conductor. For the sake of the robustness of this embodiment, one or more spacers can be arranged between the outer jacket and the outer conductor.

Furthermore, in a particular embodiment, the catheter can be a dilatation catheter, which allows treatments in a body lumen, such as treating deposits in a blood vessel.

More specifically, the plasma discharge electrode can be made of a hard metal, for example W or Ti, wherein the plasma discharge electrode can optionally be provided with a fire-lowering layer, for example A1203.

Furthermore, in the device according to the invention, the plasma gas can be a gas mixture composed of He / O2, He / N2 or N20.

The invention will be explained in more detail with reference to a drawing, which drawing successively shows:

Figures 1-7 different embodiments of a device according to the invention.

For a better understanding of the invention, the corresponding parts are indicated by identical reference numerals in the following description of the figures.

In Figure 1, a device for creating a locally cold plasma at the site of an object is disclosed.

The device for creating a local cold plasma is processed here as the shape of a catheter 10 provided with a proximal end 10a and a distal end 10b. The catheter 10 is intended for medical applications since it can be inserted into a lumen in the body of a human or animal. The lumen can be, for example, the windpipe 25, or the anal opening or a blood vessel. In this embodiment, the catheter 10 is inserted with its distal end 10b into a blood lumen 11 (blood vein or artery).

Included in the catheter 10 is a coaxial transmission line 13 composed of an inner conductor 14 and an outer conductor 15 arranged coaxially around this inner conductor 14. The inner conductor 14 electrically connects a plasma discharge electrode 16 to a high-frequency supply source 4. Between a dielectric 13a is included in the inner conductor 14 and outer conductor 15 in order to prevent voltage breakdown between the two conductors 14-15. The device according to the invention is also provided with a supply 5 for a plasma gas, which plasma gas can be supplied via a suitable (not shown) supply line in the direction of a plasma chamber 9, near the plasma discharge electrode 16.

Furthermore, the catheter 10 is designed as a dilatation catheter since the distal end 10b is provided with a dilatation balloon 12 which can be inflated with the aid of a medium by means of suitable means not shown, so that the balloon 12 is supported against the inside of the catheter. wall 11a of 1 hour 11. The wall 11a can for instance be the wall of a blood vessel. The medium for inflating the dilatation balloon 12 is supplied via a supply line 20 in the coaxial transmission line 13 from the supply unit 5 to the balloon 12.

By controlling the plasma discharge electrode 16 via the high-frequency voltage source with suitable supply or voltage pulses via the inner side 14, a plasma 17 is created at the location of the plasma discharge electrode 16 in the gas mixture supplied by the supply unit 5. which reacts locally with or acts upon the object to be treated, in this case the inside of the wall 11a of the lumen 11. With the aid of the energy released from the plasma 17, for example, cancer cells or other disorders can be treated or controlled.

According to the invention, the device is provided with adjusting means 6, which are adapted to orient the plasma discharge electrode 16 relative to the object, here the wall 11a of the lumen 11. More specifically, these adjusting means 6 comprise at least one sensor 7 for determining the instantaneous orientation of the plasma discharge electrode 16 relative to the object. This at least one sensor 7 is preferably placed near the plasma discharge electrode 16 on the distal end 10b of the catheter 10. For a more accurate orientation, several sensors 7 can be used in order to obtain a sensor. obtain a three-dimensional orientation with respect to the object.

The adjusting means 6 are preferably adapted to orient the plasma discharge electrode 16 on the basis of or on the basis of the instantaneous position of the plasma discharge electrode 16 determined by the at least one sensor 7. For this purpose, it is determined by the sensor 7. generated signal representative of the current orientation 10 in the three-dimensional plane of the plasma discharge electrode 16 relative to the object (here the wall 11a of the lumen 11) via a suitable connecting line to the adjusting means 6 where a comparison is made with the desired orientation of the plasma discharge electrode 16.

On the basis of this feedback and the possibly observed deviation between the desired orientation and the current orientation determined by the sensor 7, the adjusting means 6 will be energized such that the plasma discharge electrode 16 is positioned in the desired orientation relative to the object.

In the embodiment as shown in Figure 1, the adjusting means 6 comprise at least one stepper motor or direct current motor (DC motor) which force a translation or rotational movement on the catheter 10 or on the coaxial transmission line 13. The last embodiment in particular, in which the transmission line 13 is rotated or translated relative to the catheter 10 together with the plasma discharge electrode 16, is preferable because the dilatation balloon 12 remains immovably positioned in the lumen 11. Accidental displacement of the catheter 10 with the dilatation balloon 12 would lead to a painful frictional contact between the dilatation balloon 12 and the wall 11a 30 of the lumen 11, which may possibly lead to damage and / or injury.

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Thus, as the translation and rotation arrows in Figure 1 show, the plasma discharge electrode 16 relative to the the treated object (here the wall 11a of the lumen 11) is oriented; (rotated or translated). This makes it possible to continue with

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Image techniques (e.g., ultrasound) in real-time images of the object and the plasma discharge electrode 16 can be obtained on the basis of which the reorientation of the plasma discharge electrode 16 can be checked.

In another embodiment as shown in Figure 2, the adjusting means and 6 'comprise one or more elements 18a, 18b consisting of memory metal, which are connected to the adjusting means 6' by means of suitable control lines 19a-19b. Using the control elements 18a-18b (memory metal) with a suitable voltage or current signal (delivered by the adjusting means 6 '), a suitable orientation of the plasma discharge electrode 16 with respect to the object 11a to be treated can also be achieved. accomplished.

Here too, the instantaneous position or orientation of the plasma discharge electrode 16 relative to the object to be treated is determined on the basis of one or more sensors 7, which emit suitable signals for this purpose to the adjusting means 6 ', on the basis of which a possible deviation is established with respect to the desired orientation. On the basis of this deviation, the adjusting means 6 'will control the driving elements 18a-18b-18c so that a distortion occurs of the distal end 10b of the coaxial transmission line 15 and consequently the plasma discharge electrode 16 and hence the location of the created plasma 17 becomes set.

As Figure 2 also shows, it is preferable to use at least three drive elements 18a-18b-18c which are arranged symmetrically around the plasma discharge electrode 16 on the distal end 10b of the transmission line 13. By the separate control of the different control elements 18a-18c 1026422 8 constructed from memory metal, the distal end 10b and therefore the plasma discharge electrode 16 can be forced into any orientation in the three-dimensional plane relative to the object 11a.

In Figure 3, another additional aspect of the invention is disclosed in which the distal end 10b of the catheter 10 forms the plasma chamber 9. In this embodiment, the outer dimensions of the coaxial transmission line 13 also form the outer dimensions of the catheter 10. By providing the distal end 10b with a plurality of openings 22, it is possible to extend the plasma 17 created in the plasma chamber 9 beyond the distal end 10b of the catheter 10 and can thus assert its influence on the nearby or surrounding object (body tissue).

The outer shell surface 15 of the catheter 10 herein also acts as a grounding for the coaxial transmission line 13. For this purpose, the material designated by reference numeral 13 is a dielectric medium. The outer casing 15 can thereby form an earthing layer for controlling the high-frequency power source 4 (as shown in Figs. 1 and 2).

Figure 4 shows another embodiment of the device according to the invention in which the plasma gas supply 20 as supplied by the gas supply unit 5 (Figures 1 and 2) is arranged coaxially around the coaxial transmission line 13-14-15. For a good supply of the plasma gas from the supply unit 5 in the direction of the plasma chamber 9 at the location of the plasma discharge electrode 16, several spacers 21 are placed between the coaxial outer conductor 15 and the outer casing 10 of the catheter.

Also in this embodiment, the distal end 10b of the catheter forming the plasma chamber 9 is provided with a plurality of openings 22 for the plasma 17 to be operative at the plasma discharge electrode 16 in the direction of the object to be treated .

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And yet another embodiment as shown in Figure 5, the plasma gas supply line 20 from the gas supply unit 5 is included in the dielectric 13a of the: transmission line 13.

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Figure 6 shows the general principle of the device according to the invention. The plasma discharge electrode 16 contained in the plasma chamber 9 generates a plasma and in particular a cold plasma at the location of an object (not shown).

The plasma discharge electrode 16 is driven by a transmission line 13 which electrically connects the plasma discharge electrode 16 to a high-frequency power source 4. The device is also provided with a gas supply unit 5 which carries a plasma gas into the plasma chamber 9 via a supply line 20.

According to the invention, the device for creating a locally cold plasma relative to an object is provided with adjusting means 6, 18a-18c which are adapted to orient the plasma discharge electrode 16 relative to the object (not shown). To this end, the device is provided with at least one sensor 7 which determines the instantaneous orientation of the plasma discharge electrode 16 and sends a related signal via a signal line 7 'to a processing unit 6a which forms part of the adjusting means 6.

The processing unit 6a compares the current position as measured with the sensor 7 of the plasma discharge electrode 16 with a desired position and generates on this basis a control signal 25 with which the adjusting means 6 are controlled in order to correct the observed deviation and the plasma discharge electrode 16 to force a different orientation with respect to the object to be treated with the plasma. The adjusting means 6 can be embodied as discussed hereinbefore in the detailed description.

In another embodiment as shown in Figure 7, the sensor 7 is arranged outside the plasma chamber 9. The sensor 7 is based on measuring the returned (or reflected) power from the plasma chamber 9. This returned power is conducted in the form of an electrical signal via the connection 7 'to the sensor 7 and is a measure of the distance from the plasma 17 to the object to be treated. The sensor 7 conducts the electrical signal (which is a measure of the recirculated power) to the processing unit 6-6a, 18a-18c, where the signal is compared with the control power delivered by the high-frequency power source 4 to the plasma chamber 9.

Thus, the orientation of the plasma discharge electrode 16 (and the plasma 17) relative to the object can be determined in a fast, accurate but above all simple manner and, if necessary, the orientation of the plasma discharge electrode 16 can be corrected.

In all embodiments, the plasma discharge electrode 16 can be made of a hard metal, for example W or Ti, wherein optionally the plasma discharge electrode 16 can be provided with a (not shown) fire-lowering layer, for example A1203.

In another embodiment, not being a catheter, the device with the plasma chamber 9 is arranged outside the body of a human or animal in close proximity to the skin or external organ, so that that embodiment is very suitable for applying cosmetic treatments ( scar tissue removal). In that embodiment, the object to be treated is not body urns but the skin of a person, for example to remove or treat moles or scar tissue. The device according to the invention can also be used for treating caries or dental plaque in the teeth of humans or animals.

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Claims (22)

Device for creating a locally cold plasma at the location of an object comprising at least a high-frequency power source, a plasma chamber, a plasma discharge electrode electrically connected to the high-frequency power source and arranged in the plasma chamber, and a plasma chamber near the plasma discharge electrode 10, supply for a plasma gas, characterized in that the device is provided with adjusting means which are adapted to orient the plasma discharge electrode relative to the object. 2. Device as claimed in claim 1, characterized in that the adjusting means comprise at least one sensor for determining the instantaneous orientation of the plasma discharge electrode relative to the object. 3. Device as claimed in claim 2, characterized in that the at least one sensor is adapted to measure the power recirculated by the created plasma, which recirculated power is a measure of the current orientation of the plasma discharge electrode with respect to the object. Device as claimed in claim 2 or 3, characterized in that the adjusting means are adapted to orient the plasma discharge electrode on the basis of the determined instantaneous position. 5. Device as claimed in claim 4, characterized in that the adjusting means are adapted to orient the plasma discharge electrode by comparing the recirculated power with the power fed to the plasma discharge electrode by the high-frequency power source. Device according to one or more of the preceding claims, characterized in that the adjusting means comprise at least one DC motor 1026422. 7. Device according to one or more of the foregoing! > claims, characterized in that the adjusting means comprise at least one memory metal. Device according to one or more of the preceding claims, characterized in that the adjusting means comprise at least one voice coil (voice coil). 9. Device as claimed in one or more of the foregoing claims, characterized in that the adjusting means are arranged around the plasma discharge electrode. 10. Device as claimed in one or more of the foregoing claims, characterized in that the device comprises a catheter composed of an outer sheath, a proximal end and a distal end, which catheter can be inserted into the human or animal body with the distal end and wherein at least the plasma discharge electrode is included in the distal end of the catheter. Device according to claim 10, characterized in that the distal end of the catheter forms the plasma chamber. 12. Device as claimed in claim 11, characterized in that the distal end of the catheter is at least partially open. Device as claimed in one or more of the claims 10-12, characterized in that a coaxial transmission line composed of an inner conductor and coaxially arranged around the inner conductor is arranged in the catheter and wherein the plasma discharge electrode is electrically connected to the high-frequency power source via the interior. Device according to claim 13, characterized in that the supply for the plasma gas is included within the outer conductor located in the catheter. Device according to claim 14, characterized in that the outer conductor forms the peripheral jacket of the catheter. 1026422 Device according to claim 13, characterized in that the supply for the plasma gas is included outside the outer conductor located in the catheter. 17. Device as claimed in claim 16, characterized in that the supply for the plasma gas is arranged coaxially around the outer conductor. Device as claimed in claim 16 or 16, characterized in that one or more spacers are arranged between the outer jacket and the outer conductor. 19. Device as claimed in one or more of the claims 10-18, characterized in that the catheter is a dilatation catheter. Device according to one or more of the preceding claims, characterized in that the plasma discharge electrode is made of a hard metal, for example W or Ti. 21. Device as claimed in one or more of the foregoing claims, characterized in that the plasma discharge electrode is provided with a fire-lowering layer, for example Al 2 O 3. Device according to one or more of the preceding claims, characterized in that the plasma gas is a gas mixture composed of He / O 2, He / N 2 or N 2 O. 20 1026422