DE102011001416A1 - Plasma treatment device for treating surfaces e.g. wounds of skin i.e. forearm skin, of patient outside of hospitals, has oxygen reducing layer detachably secured on outer side of electrode, where outer side is turned away from surface - Google Patents

Abstract

The device (1) has two flexible surface electrodes (2, 3) insulated and arranged adjacent to one another on a surface to be treated, where suitable alternating voltage and alternating potential difference are producible between the electrodes. Each electrode includes electrically insulated conductors. A wound contact layer (5) is detachably secured on an outer side of the electrodes facing the surface. An active oxygen reducing layer (7) is detachably secured on another outer side of the electrodes, where the latter outer side is turned away from the surface. An independent claim is also included for a method for operating a plasma treatment device.

Description

The invention relates to a plasma treatment device for treating surfaces, in particular wounds or diseased parts of the skin, with a non-thermal plasma, wherein the plasma treatment device has two flexible surface electrodes which can be isolated and arranged adjacent to each other on a surface and between which with a suitable alternating voltage an alternating Potential difference can be generated.

It has long been known that a plasma can reduce harmful bacteria and germs and that treatment of a wound surface with a plasma promotes healing. Non-thermal plasmas which can be produced, for example, by dielectrically impeded discharge are particularly suitable for the wound treatment of living beings and in particular humans.

Out EP 1 765 044 A1 For example, a plasma source is known in which a gas is ionized in an ionization chamber, which then can emerge from the ionization chamber and flow onto the wound. It is however perceived as a disadvantage that such a plasma treatment device is comparatively heavy and cumbersome and only permits punctual or small-area wound treatment. To mitigate these disadvantages, it is proposed that the plasma treatment device be fixed to a movable frame and manually guided over a larger treatment area.

Out WO 2010/034451 For example, a plasma treatment device is known in which a flexible and gas impermeable seal is adhered to the skin around the wound and confines a cavity over the wound in which a plasma can be generated by means of surface electrodes. Via connecting lines, a gas which promotes plasma generation is conveyed into the cavity. By applied to the skin of the patient flexible and gas-impermeable seal the gas introduced is prevented with the plasma generated therein from flowing out of the cavity. The need for a substantially gas-tight covering of a cavity above the wound makes it inconvenient and unpleasant for the patient to carry out a plasma treatment with such a plasma treatment device. In addition, large-scale treatments with such a plasma treatment device are not easy to carry out, since a gastight coverage of the treatment surface is required.

It is therefore regarded as an object of the present invention to design a plasma treatment device of the type mentioned at the outset in such a way that the treatment of wounds or diseased areas of the skin which is as large as possible in the simplest possible manner possible.

The object is achieved in that the two surface electrodes each consist of at least one electrically insulated conductor and the conductors are interwoven, that on one of the surface to be treated facing outside of the surface electrodes, a wound contact layer is releasably secured, and that on one of the treated Surface facing away from the surface electrode, an ozone-reducing layer is releasably attached. The two interwoven surface electrodes form a flexible plasma electrode arrangement, with which very efficiently causes a dielectrically impeded discharge and a non-thermal plasma can be generated. For this purpose, a suitable electrical voltage is applied to the two surface electrodes. The two surface electrodes can be placed directly on a wound or a diseased skin area with the outside covered with the wound contact layer.

On the one hand, the wound contact layer prevents germs or bacteria from entering the wound from the plasma treatment device and, on the other hand, prevents the plasma treatment device from being contaminated by the wound or the diseased skin areas. The wound contact layer is releasably attached and can be replaced after each treatment.

In order to avoid that larger amounts of ozone leak, which are generated by the non-thermal plasma in the air, an ozone-reducing layer is disposed on the outside of the surface to be treated facing away from the surface electrodes. The ozone generated during treatment by the plasma in the immediate vicinity of the two surface electrodes is collected in the ozone-depleting layer and decomposed or bound.

The dimension of the flexible surface electrodes can be chosen and set almost arbitrarily large as well as the adapted dimensions of the wound contact layer and the ozone-reducing layer, so that a large-area treatment of wounds or diseased skin areas is possible. Since the flexible surface electrodes only need to be placed on the surface to be treated and no additional gas-tight cover and no other equipment such as Ionisierungsbehälter are required, a Plasma treatment can be performed after a short preparation time and without major impairment of the patient. By means of the surface electrodes resting directly on the skin or optionally separated from the skin by a thin and permeable wound contact layer, a plasma suitable for the treatment can be generated in an appropriate manner in the immediate vicinity of the diseased skin surface to be treated and at the periphery of the diseased skin surface become.

According to one embodiment of the inventive concept, it is provided that a spacer element is arranged between the surface electrodes and the wound contact layer. The spacing element can be, for example, a woven fabric or a mesh made of a material that is as ozone-resistant as possible. A suitable material is, for example, an ozone-resistant plastic material such as polytetrafluoroethylene (PTFE) or perfluoro rubber. The spacer element can either be permanently or detachably connected to the surface electrodes. It is also conceivable that the spacer is released and replaced together with the wound contact layer after each application of the surface electrodes. The spacing element can be used to specify a treatment-advantageous distance between the two surface electrodes and the surface to be treated.

It is preferably provided that the wound contact layer and the ozone-reducing layer laterally protrude beyond the surface electrodes and can be connected to one another. Both the wound contact layer and the ozone-reducing layer may each comprise, for example, a textile carrier material, in or on which active substances or additional materials are arranged, which support the respective function.

The wound contact layer and the ozone-reducing layer may, for example, be joined together along a peripheral edge and together form a closeable pocket in which the surface electrodes are arranged. In this way, the surface electrodes are coated on both sides and protected from contamination during a treatment.

According to an advantageous embodiment of the inventive concept it is provided that the wound contact layer consists of an antiseptic treated textile material. The material may also be gauze or gauze. If necessary, the wound contact layer can be sprayed with a disinfectant before each treatment or treated with suitable active ingredients or medicaments or care products.

It is preferably provided that the ozone-reducing layer is an activated carbon-containing fabric, knitted fabric or fleece. The activated carbon binds or decomposes the ozone generated during the plasma treatment.

In order to enable a plasma treatment with the plasma treatment device also outside of hospitals or designated treatment rooms, it is provided according to the invention that the plasma treatment device has a transportable controllable energy supply device. The power supply device may, for example, comprise a transformer which can be connected to the electrical supply network and generates a suitable alternating voltage with an amplitude of a few kV, for example from 1 kV to 5 kV. Such transformers are commercially available and have a low weight and a small space requirement.

By using a transportable power supply device, it is possible to store and transport the plasma treatment device including the power supply device in a case. If no electrical supply network is available, it is likewise conceivable to operate the energy supply device of the plasma treatment device with suitable powerful batteries or accumulators.

The invention also relates to a method for operating the plasma treatment device described above. According to the invention, an amplitude and / or a frequency of an alternating voltage generated between the two surface electrodes can be predetermined depending on the desired treatment depth and the treatment strength in the treatment of a wound or a diseased skin surface. It has been shown that depending on the amplitude and the frequency of the alternating voltage applied to the surface electrodes, the treatment intensity or depth of action can be predetermined. In addition, at certain predeterminable amplitudes and frequencies of the alternating voltage, bacteria and germs of essentially the same kind are selectively killed.

It is also conceivable that a pulsed AC voltage with variable pulse characteristics can be predetermined for the generation of the non-thermal plasma. For example, with commercially available components, the pulse shape or the pulse rate can be changed and adapted to the properties required in each case for the treatment. For example, the pulsed AC voltage may be one frequency variable, pulse width modulated square wave AC act.

Hereinafter, an embodiment of the inventive concept will be explained in more detail, which is shown in the drawing. It shows:

1 a schematic representation of a plasma treatment device,

2 a sectional view of the in the 1 shown plasma treatment device along the line II-II in 1 .

3 a schematic representation of an application example for a treatment of a wound on a forearm of a patient with in the 1 and 2 illustrated plasma treatment device.

One in the 1 to 3 illustrated plasma treatment device 1 has two surface electrodes 2 . 3 on, which are interwoven. Each surface electrode 2 . 3 consists of an electrical conductor, which has a double insulation from a low carbon material such as silicone in terms of health regulations. The electrical conductor is preferably a strand consisting of many individual wires, so that the surface electrodes consisting of a double sheathed with silicone strand 2 . 3 form an extremely flexible and easily adaptable to various surfaces plasma electrode assembly.

The two interwoven surface electrodes 2 . 3 are on one of the surface to be treated facing the outside 4 with a wound contact layer 5 covered. The wound contact layer 5 consists of a saturated with a disinfectant gauze or mullet layer. The wound contact layer 5 protrudes laterally over the two surface electrodes 2 . 3 out. Along a peripheral edge is the wound contact layer 5 via a Velcro fastener 6 detachable with an ozone reducing layer 7 connected. The ozone depleting layer 7 consists of an activated carbon containing tissue.

The wound contact layer 5 and the over the velcro 6 connected ozone depleting layer 7 form a pocket-shaped space 8th in which the interwoven surface electrodes 2 . 3 are arranged.

The two surface electrodes 2 . 3 are electrically conductive via a supply cable 9 with two outputs 10 a controllable transformer 11 connected. The transformer 11 has a knob 12 on, with either the amplitude and / or the frequency of the transformer 11 generated and at the outputs 10 applied AC voltage can be changed.

At the in 3 Application example shown are the two interwoven surface electrodes 2 . 3 with that of the wound contact layer 5 covered outside 4 on a forearm 13 of a patient placed on which one of the surface electrodes 2 . 3 completely covered large wound is located. The two surface electrodes 2 . 3 are via the supply cable 9 with the transformer 11 connected. The ozone created during a treatment is absorbed by the outer ozone depleting layer 7 collected.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 1765044 A1 [0003]
• WO 2010/034451 [0004]

Claims (8)

Plasma treatment device for treating surfaces, in particular wounds or diseased skin, with a non-thermal plasma, wherein the plasma treatment device has two flexible surface electrodes which can be isolated and arranged adjacent to one another on a surface and between which an alternating potential difference can be generated with a suitable alternating voltage, characterized in that the two surface electrodes ( 2 . 3 ) each consist of at least one electrically insulated conductor and the conductors are woven together, that on one of the surface to be treated facing outside ( 4 ) of the surface electrodes ( 2 . 3 ) a wound contact layer ( 5 ) is releasably secured, and that on one of the surface to be treated facing away from the surface electrodes ( 2 . 3 ) an ozone reducing layer ( 7 ) is releasably attachable. Plasma treatment device according to claim 1, characterized in that between the surface electrodes ( 2 . 3 ) and the wound contact layer ( 5 ) A spacer element is arranged. Plasma treatment device according to claim 1 or claim 2, characterized in that the wound contact layer ( 5 ) and the ozone reducing layer ( 7 ) laterally across the surface electrodes ( 2 . 3 ) protrude and connect to each other. Plasma treatment device according to one of the preceding claims, characterized in that the wound contact layer ( 5 ) consists of an antiseptic treated textile material. Plasma treatment device according to one of the preceding claims, characterized in that the ozone-reducing layer ( 7 ) is an activated carbon containing woven, knitted or nonwoven fabric. Plasma treatment device according to one of the preceding claims, characterized in that the plasma treatment device ( 1 ) has a transportable controllable power supply device. Method for operating the plasma treatment device according to one of claims 1 to 6, characterized in that depending on the desired treatment depth and the treatment strength, an amplitude and / or a frequency of a between the two surface electrodes ( 2 . 3 ) generated AC voltage is predetermined. A method according to claim 7, characterized in that a pulsed AC voltage with variable pulse characteristics can be predetermined.

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