EP0218694A1 - Transparent multi-oxygen sensor array - Google Patents

Abstract

A transparent electrochemical oxygen sensor making it possible to simultaneously determine the concentration of oxygen in different places of a biological surface can be positioned above the region that one seeks to measure, and comprises a network of electrodes sensitive to independently operating oxygen, a counter electrode, and a reference electrode.

Description

TRANSPARENT HOLTI-OXYGEN SENSOR ARRAY

FIELD OF THE INVENTION

This invention relates to an electrochemical device for determining oxygen concentration on biological surfaces.

BACKGROUND OF THE INVENTION

This invention was made with Government support under Grant No. HL 17421 awarded by National Institutes of Health. The Government has certain rights in this invention. There exist several electrochemical devices for determining the concentration of various biologically important gases on biological surfaces. Because of the critical role that oxygen plays in physiological events, most of these instruments primarily monitor oxygen, and particularly are employed to monitor oxygen concentrations in patients suffering from disease. The principle on which the instruments operate is that of the common oxygen electrode as described by L.C. Clark, Jr., in Transactions ftmecican Society artificial Internal Ox-S^ns (1956, 2:41) . While there exist a number of oxygen sensors suitable for monitoring oxygen at or on such biological surfaces as tissues, organs, blood vessels, etc., none are capable of accurately determining oxygen at different specific locations on the surface. The reasons are two-fold: First, the sensors have not been satisfactorily designed with multiple independent sensing capacity capable of close physical contact with the surface. The latter is required for determining oxygen across nonuniform shaped surfaces. Second, it is difficult to precisely position existing sensors over the diminutive biological structures, particularly superficial blood vessels where it is often desirable to determine the oxygen contour profile across the vessel surface because it is difficult to visually ascertain where on the surface the electrodes are located. SUMMARY OF THE INVENTION

This invention describes a transparent array of multiple oxygen sensors capable of determining oxygen concetration on a biological surface. The devise is constructed using semiconductor fabrication techniques and includes multiple independently operated oxygen-sensing electrodes sufficient in number to measure gradients across thee biological surface. The ■ electrodes are situated on a transparent and flexible base, which enables the user to accurately position the sensor over a specific region on the surface under consideration, and, moreover, insures uniform working contact of the sensors with irregularly shaped biological surfaces such as organs, tissues, blood vessels, leaves, etc. BRIEF DESCRIPTION OF THE DRAWINGS FIGURE 1 is a top plan view of a transparent multi-oxygen sensor;

FIGURE 2 is an enlargement of the sensor array encircled in broken line in FIGURE 1; and

FIGURE 3 is an enlarged sectional view taken on line 3-3 of FIGURE 2.

DETAILED DESCRIPTION OF THE SPECIFIC EMBODIMENT

The transparent multi-oxygen sensor array is fabricated on a suitable transparent substrate that will form the support base on which the electrodes are deposited. The size of the support base is dictated by the area over which an oxygen gradient is sought to be measured, and not by electrochemical considerations. A variety of transparent materials can be used as a support base. Particularly useful are glass or clear plastic, an example of suitable plastic being certain polymers of chlorinated hydrocarbons such as polyvinylidine chloride. Flexible plastic is preferred in those instances where the sensor is utilized to measure oxygen gradients across the surface of irregularly shaped tissues or organs to insure contact of the sensor with the surfaces under consideration.

i. Preparation ΩL iia≤ Ssnssi B se Electrode

Deposition.

In order to assure attachment of metals suitable for use as electrodes, it is desirable to clean the surface of the base on which the metals will be deposited. Cleaning of either glass or plastic surfaces can be carried out by various methods, which those skilled in the art will be aware of. A commonly used method is to immerse the base in a sonic bath and subject the base to sonication for an empirically predetermined period of time to remove contaminants from the surface. The base is subsequently rinsed in distilled water.

A second step is required preparatory to depositing metals on glass to insure sufficient bonding of the metals to a glass base. In order to provide a suitable adhesive substratum, it is desirable to etch the surface of the glass base. Several methods are available to etch glass, particularly useful is exposure of glass to a mild acid solution. Illustrative of suitable acids are hydrochloric acid or acetic acid. After etching, the base is rinsed in distilled water and dried under an inert atmosphere such as nitrogen.

ii. Deposition Q£ Electrodes.

Techniques routinely used to construct integrated circuits are employed to construct the sensor pattern. The techniques are well described by H.S. DeForest in Photoresist Ma erials ≤n EES£≤s_s≤s_ (McGraw-Hill, 1975) and numerous other texts, and the nonessential details necessary to construct the sensor are hereby incorporated by reference.

Fabrication of the sensor array is accomplished by depositing, onto one side of the base, under vacuum, noble metals such as platinum or gold routinely used to construct an oxygen sensor. Generally, the multi-oxygen sensor array will have at a minimum three types of electrodes. These are oxygen-sensitive electrodes made of a noble metal, a counter electrode also composed of a noble metal, and a reference silver-silver chloride electrode. It is sometimes convenient to combine the counter and reference electrodes into a single electrode. When the sensor base support is made of glass, it is desirable to deposit an adhesion layer of another metal before depositing the electrode metal, platinum or gold, so as to enhance the binding of the noble metal to the base. Illustrative of a glass-binding metal is chromium. Examples of such deposition techniques are vapor deposition, or sputtering. Next, a layer of noble metal about 100 to about 800 angstroms thick is similarly deposited on top of the layer of chromium, and the materials heated between 250°C to 300°C for 4 to 5 hours to anneal the layers.

Photolithographic procedures are then employed to establish the electrode pattern. The base is coated using procedures well-known in the art with positive photoresist material on the side containing the metal layers, and soft- baked at 90°C for 25 minutes. Illustrative of positive photoresist material is polyphenolformaldehyde resin, commercially known as novolak resin (e.g., Shipley 1350). The material is coated over the metal layers by spin coating. Next, a lithographic mask suitable for forming the desired number of platinum electrodes in a particular array, and of a particular diameter, and with sufficient distance between the electrodes is positioned over the base and the plate exposed to ultraviolet light for 25 seconds. The mask is removed and the base is exposed to developer for 40 minutes followed by hard-baking at 120°C for 30 minutes. The oxygen electrodes are then formed by etching away the platinum and chromium layers. This can be achieved by contacting the base with a dilute mixture of hydrochloric and nitric acids (aqua regia) to etch platinum, followed by a solution of nitric acid and ceric ammonium nitrate to etch chromium.

While there is no one combination of either electrode number, electrode diameter, or distance between electrodes that is optimally preferred for adequate performance of the sensor array, it is anticipated that more than a dozen platinum electrodes with diameters of 20>u to lO i, and 40u to 200/1 separation distance will often be employed. It is anticipated that these parameters will be a function of the type of surface and the distance over which an oxygen gradient is sought to be measured.

The procedures used to form the platinum oxygen-sensing measuring electrodes are also employed to form the silver- silver chloride reference electrode. A second deposition of chromium is done using a physical mask to define the area of the intended reference electrode, followed by deposition of silver. Silver is deposited by vapor deposition, sputtering, or other suitable techniques. The layers are annealed by heating at 170°C for 2 hours. In an alternative method the base is again covered with a positive photoresist layer, and soft-baked at 90°C for 25 minutes. Next, a lithographic mask having a negative image of the silver electrode is placed over the base and the base exposed to ultraviolet light for 25 seconds. The mask is removed and the base contacted with developer for 40 seconds followed by hard-baking at 120°C for 30 minutes. Next, silver is vapor deposited and the photoresist layer is dissolved, leaving the silver electrode pattern. Lastly, the silver is chlorided by electrochemical deposition of chloride from a solution of potassium chloride.

Adequate performance of the sensor requires that the silver reference electrode and counter electrode occupy a particular position on the sensor base. The silver reference electrode must be located between the oxygen sensing electrode array and the counter electrode, preferably closer to the oxygen sensing electrodes. If a combination counter/reference electrode is used, the common electrode may be a silver-silver chloride electrode.

in. connection &£ i_ m ££Q£££ £G Instrumentation.

The platinum sensing electrode, the silver reference electrode, and the platinum counter electrode communicate with recording instrumentation through electrical connectors by way of platinum bonding pads, which were formed during the initial deposition of platinum. The bonding pads are situated at the edge of the plate with each electrode being connected to a separate pad, and the pads, in turn, are connected to electrical connectors. The size of the bonding pad can be varied without affecting sensor performance. A satisfactory size is approximately 200 ι square. The electrical connectors can be composed of a variety of metals well-known to the those in the art; particularly useful are platinum or gold. The electrical connectors can be bonded to the bonding pads by several techniques, including ultrasonic bonding, or by applying electrically conductive epoxy to the pads.

iv. insulation ££ .tbs. Electrodes. The base and all electrodes and connectors contained thereon are coated with photoresist material. This layer acts as an insulator to prevent oxygen from contacting metal surfaces other than those required to detect the presence of oxygen. While photoresist material is a convenient insulator, a variety of other insulating materials can also -8-

perform satisfactorily. A thickness of lu of insulating layer performs satisfactorily. Application of the photoresist material is achieved by covering the base containing thereon electrodes and electrical connectors with a lithographic mask to define the active electrode areas. The base is then exposed to ultraviolet light for 25 seconds, and contacted with developer to expose the areas of the electrodes that are used to detect oxygen. Lastly, the electrical connectors are connected to more substantial lead wires that connect into a multichannel recording instrument.

V. Oxygen-Permeable flSfflkEanfi.

A transparent multi-oxygen sensor array determines oxygen present at the surface of biological surfaces by diffusion of oxygen present through a thin layer of physiological fluids that bathe the surface. Because the sensor electrodes must be in contact with an electrolytic solution to function, and since physiological fluids are high in electrolytes, the sensor can function with the electrodes in direct contact with the fluid. However, in those instances where it is necessary, or desirable, to monitor oxygen concentration over a long period of time, it is sometimes seen that prolonged contact of the electrodes with substances present in bodily fluids may poison the - electrodes and adversely affect their performance. Thus, to minimize this the surface of the array can be covered with a membrane. For a membrane to be usable in this capacity, it should be permeable to oxygen, impermeable to higher molecular weight substances found in bodily fluids, and have relatively good optical properties. At a minimum, it should be partially transparent. Illustrative of materials with these properties is poly(dimethylsiloxane-carbonate) copolymer, which is sold under the trade name of MEM 213 by General Electric. The membrane can be attached to the sensor by a variety of methods well-known to those in the art. Particularly suitable for attachment is cyanoacrylate glue. The membrane must be placed over the array in such a fashion that a small quantity of conductive electrolyte is present between the membrane and the electrodes to make electrical contact.

The following example is provided to illustrate the invention. However, it should be understood that it is not intended to limit the scope of the invention.

EXAMPLE

The transparent multi-oxygen sensor array shown in Figure 1 was tested for its ability to detect varying levels of oxygen in solution. The sensor was immersed in phosphate buffer, pH 7.3, at 37°C that had previously been equilibrated with atmospheric oxygen, and the resulting currents noted. About 50 nanoamps of current was produced for an oxygen sensor of 150/1 diameter; 30 nanoamps for a sensor 75jn diameter; and 15 nanoamps for a sensor of 25μ diameter. On transferring the sensor to a solution containing no oxygen, the sensor displayed a current of 1-2 nanoamps. We claim:

Claims

-10-CLAIHS

1. A transparent electrochemical sensor for determining the concentration of a gaseous specie⁵ at or near biological surfaces comprising: a transparent support base and situated on one side thereof, a plurality of functionally independent sensing electrodes, a reference electrode, and a counter electrode, said electrodes being in contact with an electrolytic solution, and said functionally independent sensing electrodes being capable of detecting said gaseous specie < concentration present at different regions of said biological surface.

2. A transparent electrochemical sensor as described in Claim 1 wherein said gaseous specie is oxygen.

3. A transparent electrochemical sensor as described in Claim 1 wherein said transparent support base is made of glass.

4. A transparent electrochemical sensor as described in Claim 1 wherein said transparent support base is a flexible or rigid halogenated hydrocarbon polymer film.

5. A transparent electrochemical sensor as described in Claim 1 wherein said sensing electrodes are made of a noble metal.

6. A transparent electrochemical sensor as described in Claim 1 wherein said sensing electrodes are situated on said support base in a two-dimensional array.

7. A transparent electrochemical sensor as described in Claim 6 wherein said two-dimensional array comprises between eight (8) to thirty-two (32) sensing electrodes.

8. A transparent electrochemical sensor as described in Claim 7 wherein said sensing electrodes are between 2 ϋ to 100_/U in diameter.

9. A transparent electrochemical sensor as described in Claim 8 wherein said sensing electrodes are spaced AQμ to 200α apart.

10. A transparent electrochemical sensor as described in Claim 9 wherein said sensing electrodes are coated with insulating material.

11. A transparent electrochemical sensor as described in Claim 1 wherein said sensor is covered with a porous oxygen- permeable material.

12. A transparent electrochemical sensor as described in Claim 11 wherein said porous oxygen-permeable material is transparent.

13. A transparent electrochemical sensor as described in Claim 12 wherein said porous oxygen-permeable material is drawn from the group consisting of polymers of poly(dimethylsiloxane-carbonate) , polyethylene, or tetrafluoroethylene.

14. A transparent electrochemical sensor as described in Claim 13 wherein said porous oxygen-permeable material encloses an electrolytic solution.

15. A transparent electrochemical sensor as described in Claim 1 wherein said reference electrode is composed of chloride silver.

16. A transparent electrochemical sensor as described in Claim 15 wherein said reference electrode is situated between said sensing electrodes and said counter electrode.

17. A transparent electrochemical sensor as described in Claim 1 wherein said counter electrode is composed of a noble metal.

18. A method of measuring the concentration of a gaseous specie on biological surfaces comprising: contacting said biological -surface with a transparent electrochemical sensor capable of detecting said gaseous specie at different regions of said biological surface which includes a transparent support base and situated on one side thereof a plurality of functionally independent sensing electrodes, a reference electrode, and a counter electrode, said electrodes being in contact with a electrolytic solution, and said functionally independent sensing electrodes being capable of detecting gaseous specie present at different regions of said biological surface.

19. A method as described in Claim 18 wherein said gaseous specie is oxygen.

20. A method as described in Claim 18 wherein said transparent support base is made of glass.

21. A method as described in Claim 18 wherein said transparent support base is made of a flexible or rigid halogenated hydrocarbon polymer film.

22. A method as described in Claim 18 wherein said sensing electrodes are made of a noble metal.

23. A method as described in Claim 18 wherein said sensing electrodes are situated on said support surface in a two- dimensional array.

24. A method as described in Claim 23 wherein said two- dimensional array comprises between eight (8) to thirty-two (32) measuring electrodes.

25. A method as described in Claim 24 wherein said sensing electrodes are between 20/ι to 100/1 in diameter.

26. A method as described in Claim 25 wherein said sensing electrodes are 4 ju to 200/1 apart.

27. A method as described in Claim 26 wherein said sensing electrodes are coated with insulating material.

28. A method as described in Claim 18 wherein said transparent electrochemical sensor is covered with porous oxygen-permeable material,

29. A method as described in Claim 28 wherein said porous oxygen-permeable material is transparent.

30. A method as described in Claim 29 wherein said porous oxygen-permeable material is drawn from the group consisting of polymers of poly(dimethylsiloxane-carbonate) , polyethylene, or tetrafluoroethylene.

31. A method as described in Claim 30 wherein said porous oxygen permeable material encloses an electrolytic solution.

32. A method as described in Claim 18 wherein said reference electrode is composed of chloride silver.

33. A method as described in Claim 32 wherein said reference electrode is situated between said sensing electrodes and said counter electrode.

34. A method as described in Claim 18 wherein said counter electrode is composed of a noble metal.