DE7413253U - Electrode for polarographic measurements in physiological media - Google Patents

Description

Electrode for polarographic measurements in physiological media

The invention relates to an electrode for polarographic measurements in physiological media, in particular an oxygen electrode for measuring the partial pressure of oxygen in the human or animal body, which has an insulating _; Comprises fabric-coated noble metal cathode, which at the distal end with a connection for an electrical supply so-; such as display and / or processing unit, and coated at the proximal end with an oxygen-permeable, conductive membrane and conductively connected to an anode via the physiological medium {in contrast to the so-called Clark electrodes, where noble metal cathode and anode are in one joint Electrolyte space, which is separated from the physiological medium by an oxygen-permeable, electrically insulating membrane).

7413253 28.87.77

DüL-dii dan article "ThG Measurement of Oxygen Tension in Tissues" by IASilver, from Symposion on Oxygen Measurement in Blood and Tissues and their Significance Churchill Ltd., London, 1966, p. 135, are already electrodes for oxygen pa: - tial pressure measurements (pOp measurements) in the brain, muscles and other body tissues previously known, in which a short platinum or gold wire fused in a glass capillary is used as the cathode, which leads to a tip of a few μm (3 × 10 μm) in diameter in a separate Operation is pulled out. The tip can be covered with an oxygen-permeable membrane. The counter electrode, usually chlorinated silver wire, is placed separately from the measuring electrode in the tissue.

Furthermore, by "the article" is theter-Mounted Oxygen Electrode for Monitoring Oxygen Tension "by S. Shinmaru et. al. in Cardiovascular Research Center Bulletin, April-June 1972, especially page 112, another electrode of this type previously known, in which the cathode is formed by a tiny piece of gold attached to the tip of a steel wire is formed. Steel wire and gold are cast in an insulating material (epoxy cement), the potting compound is additionally coated with a further insulating layer made of biocompatible material (Teflon). The proximal The end of this electrode (gold tip) is oxygen-permeable Membrane covered.

The disadvantage is that these known electrodes are relatively complicated and, in the case of glass electrodes, also have a fragile structural design. The complicated structural design brings because of the large number and complexity the necessary individual assembly steps when assembling the electrodes, considerable manufacturing difficulties, which make the electrodes more expensive overall and prevent cheap and simple mass production.

The object of the invention is to provide an electrode of the type mentioned at the outset which has a much simpler structure is better than the known electrodes and therefore better than those for problem-free and cheap mass production with good reproducibility of the electrode properties. The electrode is said to be particularly suitable for the trouble-free long-term monitoring of the oxygen partial pressure let use in the organism.

The object is achieved according to the invention in that the noble metal cathode has the shape of a line cable section at least one continuous noble metal wire, preferably gold wire, embedded in the insulating material, as a conductor wire having.

In the case of the electrode according to the invention, the base material is accordingly for the noble metal cathode a noble metal wire insulation cable that is easy to manufacture (continuously by the meter) used, of which the cathode is cut off piece by piece, for example by cutting. The ones won in this way Cable cut pieces then only need to be coated proximally with the oxygen-permeable membrane and distally with the electrical connection cables for the electrical supply as well as Display and / or processing unit soldered or z, B. by means of pushed over. Sleeve are jammed. The result is an electrode that can be assembled in a few simple steps, which is also cheap and is particularly suitable for mass production (with good reproducibility of the electrode properties). Inexpensive electrodes can be used as single-use items and thrown away after use will.

In a preferred embodiment of the invention, the noble metal cathode should be a piece of noble metal wire coated with an insulating varnish, preferably a polyurethane. Should the Pre-insulated noble metal cathode must also be coated with a body-compatible insulating material, so offers in addition to the previously usual overmoulding with body-compatible Plastic a sheathing in the way. that the noble metal cathode between at least two foils from the additional Insulating material is embedded, which foils are then intimately connected to one another by thermal welding and then by thermoplastic deformation or the like. e.g. be pressed into a round shape. This kind of additional insulation, too only requires a simple additional work step, and thus also promotes the desired goal of the simple and cheap mass production of the electrodes.

Before attaching the oxygen-permeable membrane to the proximal The end of the noble metal cathode should preferably have this end beforehand for the purpose of achieving a defined gold surface to be etched. It is advisable to carry out the etching process so far that the noble metal wire is at the proximal end of the The cathode is set back from the insulating material, i.e. there is a precious metal recess opposite the insulating material results at the proximal end. This metal recess should then be filled with an electrolyte and only then the recess be covered with the membrane. The introduction of an electrolyte into the recess brings particularly suitable Pulse operation of the electrode has the advantage that the occurring during the measurement phase. polarographic currents less of the momentary diffusion properties of the membrane are dependent. If the electrodes are stored for a long time in saline solution, the electrolyte can also diffuse through the porous The membrane can be filled with physiological Na Cl solution. A pre-filling of the recess with electrolyte solution prior to attachment the membrane is then superfluous.

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The application of the electrode according to the invention in body tissue can be done, for example, with an injection cannula into which the noble metal cathode can be inserted and through the cannula piston injectable into body tissues. When measuring oxygen directly in blood vessels (veins), on the other hand, it is advisable to use the Form the electrode as a catheter and by pushing the catheter into the corresponding blood vessel, the catheter measuring tip ■ then to be placed at the desired measuring location .. · '· ...:. The counter electrode (Anode) can be applied either to the body surface or in the physiological medium with both options will.

Further advantages and details of the invention emerge from the following description of exemplary embodiments based on the drawing in conjunction with the subclaims.

Show it:

Fig. 1 to 4 four different embodiments of a monopolar electrode according to the invention

Fig. 5 shows the sheathing of an electrode according to the invention with an additional, body-compatible insulating material in the main work steps,

Fig. 6a to 9c the formation of an electrode according to the

Invention as a catheter, with the respective counter electrode either separate from the catheter is to be placed in the blood or on the skin surface in the vicinity of the measuring point or is arranged together with the cathode on the catheter.

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In the electrodes according to FIGS. 1 to 4, the base material for the noble metal cathode is in each case a piece of round cable made of a gold wire i and an insulating lacquer coating 2, e.g. made of a polyurethane. The gold wire 1 has a diameter of the order of 10 to 100 μm, preferably 60 μm. The partial gap of the cathode base material are cut pieces of a longer, continuously manufactured gold wire solar cable (sold by the meter).

In the exemplary embodiment according to FIG. 1, the basic cable piece is 1, 2 with an additional insulating compound 3 from body-compatible Insulating material, e.g. Teflon, coated. The proximal end of the electrode is etched off and on one level an oxygen-permeable membrane 4 on the etched plane upset. The membrane material used here is preferably hydrophilic and only for small molecules and ions, but not for macromolecules such as protein, permeable substances such as cross-linked polymethacrylates, polystyrenes or cellulose acetates, in question. At the distal end of the gold wire 1 is also the electrical connection line 1 'between wire 1 and a (Not shown!) Supply and display and / or processing unit for specifying the electrode potential on the one hand and for measuring and displaying or processing the polarographic currents on the other hand soldered or by means of Clamped sleeve. This type of connection between Slgnalleitui: j ]. ' and gold wire 1 applies to all further exemplary embodiments corresponding.

In contrast to the embodiment according to FIG. 1, in the embodiment according to FIG. 2, a recess 5 is made at the proximal end of the cathode by subsequent etching out of gold opposite the insulating material, in which the membrane 4 is inserted directly. The exemplary embodiments according to FIGS. Z and 4 have corresponding recesses 5.

7413253 07/28/77

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In comparison to the embodiment according to FIG. 2, however, contains the embodiment of FIG. 3 in the recess 5 between Gold wire 1 and the membrane 4 also have an electrolyte space 6. A corresponding electrolyte space 6 is also in the design provided according to FIG. In contrast to the other embodiments, however, the membrane 4 is not shown in FIG the recess 5 is inserted, but according to the exemplary embodiment according to FIG. 1, it again covers the entire distal End of the electrode. According to the embodiments according to FIGS. 1 to 3 can of course also the cathodes according to Figs. 2 and 4 are also sheathed with an additional biocompatible insulating material, for example Teflon be.

5 again shows a section of the Electrode base material with the gold wire 1 and the insulating varnish 2. The wire cable piece 1, 2 is here between plastic films 7 and 8, e.g. made of Teflon, inserted. With a width of approximately 500 μm, the foils have a thickness of approximately 50 / um on. The two foils 7 * 8 are on the contact surfaces intimately thermally welded to one another. After being welded brought them into a round shape by heating and pressing. The additional, body-compatible, pressed into the round shape Insulating material then corresponds to the additional plastic sheathing shown in FIGS. 1 and 3.

In the catheter designs according to FIGS. 6a to 9c (catheter tips in longitudinal and cross-section!) Are gold wire, insulating varnish as well as additional insulating material (which also forms the catheter material here) of the electrode again with the code numbers 1, 2 and 3 provided. Correspondingly, the membrane and, if appropriate, the electrolyte are again designated by 4 and 6, respectively.

7413253 07/28/77

All of these designs also have openings in the catheter material a passage channel 9 (lumen), which in particular for the additional collection of blood or tissue samples or how e.g. also in the catheter design according to Figures 9a to 9c for rinsing the proximal end of the oxygen electrode with a Rinsing medium, in particular Na Cl solution, is used. In the embodiment according to FIGS. 6a, b and 8a, b it opens the passage channel 9 in each case directly on the catheter tip next to the monopolar electrode 1, 2, in the embodiments according to FIGS. Va, b and 9a to c, however, since? borrowed from the actual catheter tip. All catheters according to FIGS. 7a to 9c also have to reinforce the Tensile strength still a textile core 10 (textile thread).

The electrodes of the catheter according to FIGS. 6a to 7b and 9a, b together with a counter-electrode to be placed e.g. on the main surface, especially Ag / Ag Cl-electrode (the e.g. can also be used at the same time to take other physiological measured variables, such as EKG or the like), a simple one unipolar measuring system for the oxygen partial pressure.

A correspondingly simple bipolar measuring system is obtained by attaching the counter electrode directly to the catheter. In the embodiment according to FIGS. 8a, b, for example, the counter electrode consists of a silver sleeve 11. The supply line to this counter electrode is e.g. a copper or steel wire 12 with insulation 13 - for contacting in this case, the wire 12 is exposed in front of the catheter tip, bent out and then the silver sleeve 11 over the exposed Wire end pushed over and pressed tight. The contact at the distal end can be made by soldering or attaching a corresponding plug-in part. By bending the wire between the counter electrode and the catheter tip resulting cavity 14 is sealed with plastic.

Claims (1)

1. Electrode for polarographic measurements in physiological Media, especially oxygen electrode for measuring the partial pressure of oxygen in humans or animals Body comprising a noble metal cathode coated with insulating material, which at the distal end has a connection for a electrical supply and display and / or processing unit provided and covered at the proximal end with an oxygen-permeable, conductive membrane and over da-> physiological medium is conductively connected to an anode, aaüurch characterized in that the Edelmetallka; hode (1, 2) in the form of a line cable section with at least one continuous section embedded in the insulating material (2) Noble metal wire (1), preferably gold wire, as a conductor wire. 2. Electrode according to claim 1, characterized in that the noble metal cathode (l, 2) as a cut piece of a noble metal wire insulation cable, preferably round cable is formed. 3 »Electrode according to claim 1 or 2, characterized in that that the noble metal cathode (1, 2) is a piece of noble metal wire coated with an insulating varnish, preferably a polyurethane is. 4. Electrode according to one of claims 1 to 3, in which the already isolated noble metal cathode is additionally coated with a biocompatible insulating material, characterized in that the noble metal cathode (l, 2) between at least two foils (7 -, 8) from the additional Insulating material is embedded, which foils by thermal _ -.10 - 7413253 07/28/77 Welding intimately connectable to one another and by thermoplastic Deformation, e.g. in a round shape (j5), can be pressed. 5. Electrode according to one of claims 1 to 4, characterized in that the noble metal wire (l) has a diameter in the order of 10 to 100 μm, preferably 60 μm, having. 6. Electrode according to claim 5, characterized in that that the cathode diameter (1,2) taking additional insulating layers (e.g. 5) into account is of the order of magnitude is from 150 to 250 µm. 7. Electrode according to one of claims 1 to 6, characterized in that the noble metal wire (1) on the proximal The end of the cathode is set back from the insulating material (2), e.g. by subsequent etching or the like (precious metal recess compared to insulating material). 8. Electrode according to claim J, characterized in that the oxygen-permeable membrane (4) is used in the Edelmet'allausschnitt (5). 9. Electrode according to claim 8, characterized in that that between the electrode wire (1) and membrane (4) an electrolyte (δ) * e.g. Na Cl solution is embedded. 10. Electrode according to one of claims 1 to 9 »characterized in that the noble metal wire (l) at the distal end is provided directly with electrical connection lines (l ¹ ) for the supply and display and / or processing unit, for example the lines on the noble metal wire soldered or clamped. - 11 - 7413253 07/28/77 11. Electrode according to one of claims l to 10, characterized through an injection cannula assigned to the noble metal cathode (1, 2), into which the cathode can be inserted and through the Cannula plunger is injectable into the body tissue. 12. Electrode according to one of claims 1 to 10, characterized characterized in that the noble metal cathode (1, 2) is arranged on a catheter for introduction directly into the bloodstream is or forms part of a catheter. 15. Electrode according to claim 4 and 12, characterized in that that the additional insulating material (3) forms the catheter material. 14. Electrode according to claim 12 or 13, characterized in that the catheter has a through channel (9) (lumen) has, which is used in particular to take blood samples and / or to rinse the proximal cathode surface, with to For irrigation purposes the proximal end (9 ') of the channel (9) at the Cathode surface to be rinsed past the side of the catheter is led out. 15. Electrode according to one of claims 12 to 14, characterized in that the catheter has a tensile textile core (10) having. 16. Electrode according to one of claims 12 to 15 * thereby characterized in that the catheter in addition to the noble metal cathode (l) has at least one further metal core (I2), which is used as a supply line to an anode (ll) arranged directly on the catheter, e.g. silver sleeve, is used. 17. Electrode according to one of claims 12 to l6, characterized in that for the central guidance of the noble metal cathode (l, 2) in the blood vessel near the proximal end of the catheter one over an additional lumen of inflatable balloon, e.g. made of rubber, is attached is. 7413253 2aO7.77