DE19537579A1 - Ultra light electrode for place selective coupling of electric currents - Google Patents

Abstract

The ultra light electrode consists of a very light and very flexible capillary body type support matrix (2), which can be filled with a liquid or a gel type electrolytic material, and is connected with at least one thin very flexible electric lead (3). The wt. of the ultra light electrode is so small, that it can carry a substance layer (4) of a gel or a cream type substance on the skin. The support matrix has the form of a cloth, which by cutting out or stamping can be formed with the desired shape and geometry.

Description

The invention relates to an ultralight electrode for the locally selective coupling of electri flow and infiltration of active ingredients into human skin and processes for their manufacture.

Such ultralight electrodes can be used in dermatology and cosmetics treatment of skin diseases and for the cosmetic treatment of the skin surface in iontophoretic and electroosmotic ways, in particular also in a location-selective manner rich in fabrication.

It is known that in dermatology electrical currents to the electroosmotic liquid transport and iontophoretic introduction of medication into the skin of Animals and humans are used (see, e.g., C. Carley, S. Wolpert, and J. K-J. Li: AN AUTOREGULATED PULSED-DC MODE IONTOPHORETIC TRANSDERMAL SYSTEM; Proceedings of the Fifteenth Annual Northeast Bioengineering Conference, IEEE, Engineering in Medicine and Biology Soc., New York, 1989, P51-52, and M.J. Pikal, and S. Shah: TRANSPORT MECHAMSMS IN IONTOPHORESIS: 11: ELECTROOSMOTIC FLOW AND TRANSFERENCE NUMBER MEASUREMENTS FOR HAIRLESS MOUSE SKIN; Phamaceutical Reserch, Vol. 7, No.3, 1990, p213-221). In iontophoresis, active ingredients that dissociate into ions are extracted using a electrical voltage introduced into the skin as an ion current. The electric current will generated in the skin between two electrodes attached to the skin.

Electro-osmosis causes an electrical current to flow through the skin Liquid accumulation in the area of the cathode and liquid depletion in the loading area rich the anode.

It is also known to have iontophoretic and electroosmotic effects in cosmetics exploited and equipment for this purpose are offered on the market (cf. e.g. B. Customer information leaflet Apparative Kosmetik "from IONTO-COMED OmbH, Eggenstein-Leo., 1995).  

Ionotophoresis and electroosmosis are usually z. B. in the field of Ge sight skin performed. For this, z. B. electrodes used over the entire surface of the Face or on parts of the skin.

However, it is also known that electroosmotic effects are site-selective for cosmetic loading deep wrinkles can be exploited. One of the electrodes is a thin needle formed, which is introduced directly below the fold in the tissue. Apparative Devices for these processes are available on the market (see, for example, customer information "COSMOMED info, GALVANOTHERM; The iron for the skin", COSMOMED Beauty-Rent GmbH, Wetter, 1995). Methods of this type are e.g. More colorful the term "electroridopuncture" known.

A disadvantage of the prior art is that iontophoresis and electroosmosis are either relatively large area with heavy electrodes or selectively with the help of fine needles be performed invasively. Both the use of heavy large area Electrodes as well as the needle electrodes inserted into the skin tissue mean for the treated person a burden. In addition, it is not possible in addition to the electro Osmotic wrinkle treatment with a needle electrode is also a locally selective treatment perform iontophoretic treatment with the introduction of active substances.

The invention is therefore based on the object of an ultralight electrode for iontophores table and electroosmotic treatment processes that are extremely easy to implement Execution is and optionally a full-surface or very targeted location-selective coupling of electrical current into the skin, e.g. B. in the area of skin folds. In addition, it should be possible to use the ultralight electrode as an inexpensive way train throwing articles.

This object is achieved in that an ultralight electrode consists of egg ner thin and very flexible capillary body-like support matrix 2 , which can be filled with a liquid or gel-like electrolyte material and connected to at least one thin, very flexible electrical lead 3 , and the weight of the ultralight electrode is low, that they can be worn by gel or cream-like agent layers 4 or agent islands 4 on the skin can.

The support matrix 2 can, for example, have the shape of a cloth which is cut or punched out to the desired size and geometry. The support matrix 2 which can be impregnated with an electrolyte material can, for example, consist of thin impregnable paper types, cellulose-containing nonwovens, synthetic fiber nonwovens, textile fabrics, knitted fabrics, polymers or organic and inorganic foam materials. The thickness of the support matrix 2 should be between 0.01 mm and Imm.

The support matrix 2 thus represents a thin cloth-like structure, into which an electrolyte material ria1 can be introduced, which is held in the capillaries of the support matrix.

In order to provide the support matrix 2 with a thin and flexible electrical lead 3 , an electrical lead 3 is applied as an electrically conductive layer, for example, to one of the side surfaces. This can consist, for example, of electrically highly conductive metals such as gold, silver, platinum, copper, aluminum, nickel and can be evaporated or sputtered on in a vacuum using the methods known from thin-layer technology in microelectronics.

It is also possible to use these layers of electrically conductive screen printing paste or Manufacture inks as used in thick-film technology for the production of conductors webs are used in microelectronics and by screen printing or after known dispensing methods are applied.

It is also possible to use electrically conductive sprays which are produced on the basis of metal powder or graphite powder and an adhesive or binder and are available on the market. Such materials can be sprayed onto the support matrix 2 .

The electrical derivative 3 , 3 'can be formed over the entire surface, strip-like or grid.

But it can also be in the form of thin wires made of electrically conductive metals such as Gold, silver, platinum, copper, aluminum and other metals or from electrical conductors the fibers are sewn onto the support matrix in such a way that a grid-shaped course of the Wire or the electrically conductive fiber results.

With fabric-like support matrix materials, such wires or electrically conductive Fibers can also be woven directly instead of weft and warp threads so that everyone second to thousandth weft or warp thread of the fabric through the wires or electrically conductive fibers are replaced.

The support matrix 2 can be impregnated with a liquid, gel-like or cream-like electrolyte material, as is known for iontophoretic treatment methods for moistening the electrodes.

It is also possible to use unimpregnated support matrix materials that are only available from Application, d. H. when applied to skin treated with a gel or cream come into contact with the electrolyte material.

The material for the ultralight electrodes can be produced in long lengths and on Wind up the rolls. Pieces of suitable size and shape can be used for Cut off the example with scissors.  

The advantages achieved by the invention are in particular that for iontophoreti cal or electroosmotic treatments of the skin ultralight electrodes are used those that the treated person perceives as less stressful. Due to the extremely light and flexible design of the electrodes as ultralight elec For the first time, it is possible to apply these electrodes over the entire surface of the skin lay or cantilever on gel or cream-like islands of active ingredients so that the electrical current is only selectively coupled into the area of the skin that is in is in direct contact with the active ingredient islands. Be such active ingredient islands beforehand specifically introduced into skin folds, the electrical current can be locally limited for iontophoretic or electroosmotic treatments can be used.

In addition, it is possible in the same skin area parallel to the iontophoretic or electroosmotic treatment to perform a steam bath or red light treatment, because the ultralight electrodes have only a slight shielding effect.

In Figs. 1 to 6 show exemplary embodiments of the invention.

Fig. 1 shows in section an ultralight electrode consisting of a support matrix 2 and egg ner electrical lead 3 , which is on a skin surface 1 'with an active ingredient layer 4 .

In Fig. 2, an ultralight electrode according to Fig. 1 is shown in plan view a) and in section b), the electrical lead 3 of which is replaced by a rastered electrical lead 3 '.

Fig. 3 shows in plan view a) and in section b) an ultralight electrode according to Fig. 1, the z. B. has been brought to the desired shape by cutting or punching.

In Fig. 4, an ultralight electrode according to Fig. 1 is shown in section, which is carried by islands of active substance 4 ', which are found on the skin 1 in depressions of skin folds 1 ''be.

Fig. 5 shows a spatial representation of an ultralight electrode according to Fig. 4, which is carried by active ingredient islands 4 , which are on the skin 1 in the wells of skin folds 1 ''.

In Fig. 6, an ultralight electrode according to Fig. 4 is shown in section, which is attached in the vicinity of the outer edge 2 '' of the support matrix with the aid of a fixing patch 5 on the skin surface 1 '.

1 shows a first exemplary embodiment of the invention . It shows in section an ultralight electrode consisting of a support matrix 2 and an electrical lead 3 which is located on a skin surface 1 with an active substance layer 4 .

The ultralight electrode consists of a thin and very flexible capillary body-like support matrix 2 made of a thin soakable paper type or a cellulose-containing fleece and is soaked with an electrolyte material as is known for iontophoretic or electro-osmotic treatment processes. The thickness of the support matrix 2 is 0.1 mm in this example.

This support matrix is connected to a thin, very flexible electrical lead 3 . This consists, for example, of an electrically highly conductive metal such as gold, silver, copper, aluminum, nickel and is vacuum-deposited or sputtered on using a method known from thin-film technology in microelectronics.

In the example according to FIG. 1, the skin 1 is provided on its surface 1 with a layer 4 of one or more active substances, such as are known for iontophoretic or electroosmotic treatment methods in the field of dermatology and cosmetics. Here, the entire support matrix 2 is in contact with the active ingredient layer 4 on the skin surface 1 '. A location-selective treatment of the skin is achieved here by a limited expansion of the ultralight electrode. The geometric shape of this ultra light electrode can also be enlarged by overlapping placement of several partial electrodes.

The second electrode necessary for iontophoretic or electroosmotic treatments can be designed as a conventional large-area electrode, as it is according to the prior art Technology is known and in another place on the skin of the person to be treated is applied.

A second exemplary embodiment of an ultralight electrode is shown in FIG. 2 in plan view a) and in section b). In contrast to Fig. 1, the electrical derivative 3 is replaced by a rastered electrical derivative 3 '. This will lead from electrically well to produce the screen printing pastes or inks, such as those used in thick-film technology for the production of conductor tracks in microelectronics and applied locally by screen printing processes or by known dispensing processes. In this example, the support matrix 2 consists of a synthetic fiber fleece.

FIG. 3 shows a third exemplary embodiment in top view a) and in section b) of an ultralight electrode according to FIG. 1, which has been cut or punched to the desired shape. In this example, the support matrix 2 consists of a textile fabric. The electrical derivative 3 '' was produced by spraying an electrically conductive "conductive lacquer" as it is commercially available.

A fourth embodiment of the invention is shown in FIG. 4 in section. Here, an ultralight electrode according to Fig. 1 of active ingredient islands 4 ', which are located on the skin 1 in depressions of skin folds 1 ''. These active ingredient islands 4 'are specifically introduced, for example with a syringe, into the skin folds before the application of the ultralight electrode.

The electrical current for the iontophoretic or electroosmotic treatments is thereby selectively and location-selectively coupled into the area of the skin folds in that the extremely light and flexible ultralight electrode is carried self-supporting on the gel- or cream-like active substance islands 4 'and is in direct contact with the active substance islands .

It is possible to use an electrolyte-filled support matrix material. It is also possible to dispense with this electrolyte filling, since the thin support matrix 2 is in direct contact with the active ingredient islands 4 'and, due to their moisture content, is moistened in the area of the contact point between the support matrix and active ingredient islands and thus becomes electrically conductive.

A spatial representation of this example is shown in FIG. 6.

A sixth embodiment is shown in FIG. 6. Here, an ultra-light electrode according to FIG. 4 is shown in section, which is fastened in the vicinity of the outer edge 2 '' of the support matrix with the aid of at least one fixing spot 5 on the skin surface 1 '. This fixing spot is intimately connected to the support matrix 2 , for example with the aid of an adhesive. On the surface opposite the support matrix, this fixation spot is provided with a skin-compatible adhesive, as is known from medical tape technology. With the help of this fixation spot, the ultralight electrode is fixed on the skin surface in a non-slip manner. At the end of the support matrix 2 '', the electrically conductive contact layer 3 '''is, for example, electrically connected to the iontophoresis or electro-osmosis device with the aid of a small crocodile clip. (Not shown in FIG. 6.) The connecting cable between the iontophoresis or electroosmosis device and the alligator clip can, for example, additionally be attached to a headband or another band which is placed around the body in order to relieve strain to reach.

A seventh embodiment (not shown) results from the fact that the electrical contact layer 3 , 3 'or 3 ''is coated with a thin plastic film which prevents the electrolyte material or the active substance from drying out. All thin and flexible plastic materials with thicknesses between 1 µm and 0.1 mm are suitable for this, which can be applied by spraying or lamination.

Claims (12)

1. Ultralight electrode for the location-selective coupling of electrical currents and infiltration of active substances into human skin, characterized in that the ultralight electrode consists of a thin and very flexible capillary body-like support matrix ( 2 ) which can be filled with a liquid or gel-like electrolyte material and with at least one thin one very flexible electrical derivation ( 3 ) is connected, and the weight of the ultralight electrode is so low that it can be worn on the skin by gel or cream-like active substance layers ( 4 ) or active substance islands ( 4 ' ). 2. Ultralight electrode for the location-selective coupling of electrical currents and introduction of active substances into human skin according to claim 1, characterized in that the support matrix ( 2 ) has the shape of a cloth which is cut or punched out to the desired size and geometry, and further the support matrix ( 2 ) which can be impregnated with an electrolyte material consists of thin impregnable paper types, cellulose-containing nonwovens, synthetic fiber nonwovens, textile fabrics, knitted fabrics, polymers or organic and inorganic foam materials, and the thickness of the support matrix ( 2 ) is between 0.01 mm and Imm . 3. Ultralight electrode for the location-selective coupling of electrical currents and introduction of active substances into human skin according to claims 1 and 2, characterized in that the support matrix ( 2 ) with a thin and flexible electrical derivative ( 3 , 3 ', 3 '') is provided, which is applied to one of the side surfaces as an electrically conductive layer and consists of electrically highly conductive metals such as gold, silver, platinum, copper, aluminum, nickel. 4. Ultralight electrode for the location-selective coupling of electrical currents and infiltration of active substances into human skin according to claims 1 to 3, characterized in that the electrical derivative ( 3 , 3 ', 3 '') is formed over the entire surface, strip-like or grid or in Form of thin wires made of electrically highly conductive metals such as gold, silver, platinum, copper, aluminum and other metals or of electrically conductive fibers is sewn onto the support matrix in such a way that a grid-shaped course of the wire or the electrically conductive fiber results, or at fabric-like support matrix materials such wires or electrically conductive fibers are woven directly instead of weft and warp threads so that every second to thousandth weft or warp thread of the fabric is replaced by the wires or electrically conductive fibers. 5. Ultralight electrode for the location-selective coupling of electrical currents and infiltration of active substances into human skin according to claims 1 to 4, characterized in that the support matrix ( 2 ) is soaked with a liquid, gel-like or cream-like electrolyte material, as is the case for iontophoretic treatment processes Moistening of the electrodes is known. 6. Ultralight electrode for the locally selective coupling of electric currents and Introducing active substances into human skin according to claims 1 to 5, characterized in that the geometric shape of the ultralight electrode by Overlap of several partial electrodes can be increased. 7. ultralight electrode for the location-selective coupling of electrical currents and infiltration of active substances into human skin according to claims 1 to 6, characterized in that the ultralight electrode in the vicinity of the outer edge ( 2 '') of the support matrix with the aid of at least one fixing spot ( 5 ) on the skin surface ( 1 ') can be fixed, and the fixation patch is intimately connected to the support matrix ( 2 ) with the aid of an adhesive, and on the surface opposite the support matrix this fixation patch is provided with a skin-compatible adhesive, as used in medical dressing technology is known. 8. Ultralight electrode for the location-selective coupling of electrical currents and infiltration of active substances into human skin according to claims 1 to 7, characterized in that the electrical contact layer ( 3 , 3 ') or ( 3 '') coated with a thin plastic film is, which prevents the electrolyte material or the active ingredient from drying out, and the thickness of this plastic film is between 1 μm and 0.1 mm. 9. A method for producing an ultralight electrode according to claims 1 to 8, characterized in that the electrical derivative ( 3 , 3 ', 3 '') according to the known from thin-film technology of microelectronics in a vacuum or sputtered or from electrically good conductive Screen printing pastes or inks are produced by the screen printing processes known in thick-film technology for the production of conductor tracks in microelectronics or by known dispensing processes. 10. A method for producing an ultralight electrode according to claims 1 to 8, characterized in that the electrical derivative ( 3 , 3 ', 3 '') with electrically conductive sprays made of metal or graphite powder and an adhesive or binder on the support matrix is checked. 11. A method for producing an ultralight electrode according to claims 1 to 10, characterized in that the material for the ultralight electrodes in long webs Manufactured and wound on rolls and of suitable size for use and shape, for example, is cut off with scissors. 12. A method for producing an ultralight electrode according to claims 1 to 11, characterized in that the electrical derivative ( 3 , 3 ', 3 '') with a thin and flexible plastic layer with a thickness between 1 µm and 0.1 mm is coated by spraying or lamination.