JPH03505785A - Micro multi-electrode structure - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed description of the invention] ” Me The present invention provides a single substrate for electrochemical measurement and generation of electroactive species. This invention relates to a micro multi-electrode structure in which a plurality of electrodes are arranged.

Until now, there have been no suitable methods for the reliable detection and generation of minute amounts of electroactive species. Micro multi-den 8i! The structure is unknown. Measurement and generation of electroactive species Fundamental problems in testing electrochemical processes for the appropriate surface properties and geometry of the anode or electrode material used. It is to obtain. Only a uniform morphological composition that is uniform and highly reproducible This enables electrode reactions to occur in a uniform manner, which enables the measurement of minute currents and spatial This is important for measurements in extremely narrow conditions.

Miniaturized electrodes for such applications have surfaces in the square micron area. It is necessary to have certain surface material properties. In measurement in the biological field, the corresponding The electrochemical system is not disturbed by the small amount of material metabolism caused by Therefore, it is necessary to ensure that as little current as possible flows through the electrodes. Potenthoda For dynamic measurements, such a micro-multielectrode structure can increase the potential When the speed becomes 100 lIV/s, 74. flow becomes possible and its The height of the electrolyte solution being tested is similar to the phenomenon in polarography. Directly proportional to the concentration of electroactive species.

First, the necessary micro-multielectrode structure can be tested in areas that could not be tested in the past. It is necessary to create the possibility of electrochemical testing. In this case, the biological In addition to tests in textiles, further tests in electrochemical reactors In the case of re-systems, and in the past, measurements using normal microelectrodes could not be carried out. It is also of special importance in the case of corrosion tests.

Inserting individual microelectrodes or combining many such individual microelectrodes Its use in measurement is already known. These individual microelectrodes are It has been proposed for the measurement of the static and botensicodynamic methods. In this case, a plurality of flat electrodes are arranged in parallel to each other. Also many individual A similar electrode structure consisting of a microelectrode is also used, which is used as a measuring electrode or A large voltage drop is observed between the counter electrode and the reference electrode, and the current The disadvantage is that the density distribution is never uniform. Such individual microelectronics With poles, it is not possible to maintain a constant geometrical relationship between the electrode surfaces, and therefore the reproducibility It becomes impossible to make accurate measurements.

The purpose of the present invention is 1. Consistent geometry and reproducible electrochemical measurements It has the advantage of being able to obtain measured values, has a low failure rate, and has a low The goal is to create a micro-multi-electrode structure that enables measurements that are resistant to noise. this In order to solve the problem, the micro multi-electrode structure according to the present invention has one internal electrode and at least two other electrodes, the inner electrode is connected as a reference electrode and the other electrode The basic idea is to at least partially surround the internal electrodes when viewed from above the board. are doing. One internal electrode is connected as a reference electrode and is also selectively connected to a measurement voltage. Other electrodes used as poles or counter electrodes at least partially cover this inner electrode. sufficient shielding of the internal electrodes is obtained by surrounding them with This enables measurements that are not affected by At the same time, this micro-multielectrode structure Therefore, it is possible to establish a certain geometric arrangement and reduce the distance between the electrodes. created. This fundamentally reduced distance is uniquely due to the micro-multielectrode structure. This small distance between the electrodes results in poor conductivity. The influence of electrolyte solutions, such as physiological solutions, can be significantly reduced. Individuals like this By using a micro-multielectrode structure with a minimum constant distance between the electrodes, In addition to being able to obtain measurements that are not affected by noise, it has traditionally been rarely used for testing. systems that were often impossible or only possible using expensive correction methods. For the first time, it is now possible to measure become. In addition, in the case of organic electrolytes, which previously could not be measured without the addition of conductive salts, In some cases, using such a micro-multielectrode structure allows direct analytical and reaction-kinetic tests can be performed. Also, as a quasi-shield for the central reference electrode. Therefore, current measurement becomes significantly noise-free, and it is also possible to use the three-electrode method. Therefore, current measurement up to the picoampere region is possible. Distance between individual electrodes By minimizing the voltage due to electrolyte-related voltage drops (iR drops), minimizes positional errors and, at the same time, minimizes the electrochemical Test and measure local concentration gradients or simultaneously based on the smallest dimensions of the cell. This allows for simultaneous monitoring and measurement of multiple electroactive species. Also I Potentiometer in 3 electric scratching structure with relatively high potential rise rate reaching V/S Dynamic measurements are also possible by using such micro-electrodes. This means that the effect of capacitance, which becomes noticeable in macroscopic structures, can be largely eliminated. This is due to

By using the micro multi-electrode structure of the present invention, a simple method using gold as an electrode material can be achieved. 3. It is now possible to quantitatively measure various neurotransmitters using an electric scratching structure. He became multi-talented. In addition, platinum is used as the electrode material, and the surface of the electrode material is coated with yeast. By immobilizing and fixing the element, for example, we can produce highly reliable glucose that has been miniaturized. sensor can be realized. Furthermore, platinum is used for the electrode and the electrode is covered with a post-flow membrane. By inverting the oxygen concentration in various electrolytes can be measured.

The micro-multielectrode structure of the present invention also includes one reference electrode and at least two other electrodes. In addition to the Even for configurations that allow different electrochemically active species to be detected simultaneously, It can be applied in a simple way. Furthermore, in addition to simultaneous measurement of various substances, Lateral resolution of the concentration of the substance being measured is also possible.

A geometrically particularly suitable electrode structure with a particularly homogeneous current density distribution is a This is achieved by arranging each electrode concentrically within the frame. be done. The individual electrodes are provided on the substrate material, the connections in this case being e.g. This can be done using conductor tracks on the material. Deposits between adjacent electrodes and In order to prevent temporal changes in the characteristics of measurement results, it is necessary to at least It is advantageous to use such an arrangement with separation by one insulating layer.

Concentric arrangement of electrodes is, in principle, a species of multiple electrodes arranged concentrically around the center. allows obtaining various geometrical configurations. Significantly improved uniformity of current density distribution In the sense of The area of the inactive separation region is defined as the area of the active electrode segment. It is advantageous to make the area of the inert isolation region smaller than the active one. The capacitance can be reduced by using strategies to reduce the area of the electrode segments. effect can be largely eliminated.

For a series of measurements, choose a planar configuration, and for measurements involving electrically active species. It is advantageous to deposit the material to be applied dropwise onto this electrode. present invention A particularly advantageous form of micro-multi-electrode structure is that basically the electrodes are placed in a common plane It is to place it in. Electrode connections in such configurations are based on individual electrodes. It is advantageous to connect the contacts on the side opposite to the electrodes of the substrate through the through holes in the plate. It is.

obtained by concentric placement of other electrodes with respect to the inner electrode connected as a reference electrode. In addition to shielding the internal electrodes, the working electrodes are also shielded by other electrodes. Can be held. However, the internal electrode can be connected to the reference electrode by a corresponding connection. In addition to its function as a counter electrode, it can also function as a counter electrode. Internal electrode reference For use as a lighting electrode, the second type of electrode is used as the internal electrode. It is particularly advantageous to have such an arrangement. In particular, such a second type of electrode , requiring a certain minimum volume and, in addition, a particularly effective sealing of this kind of internal electrodes The board has internal electrodes on the substrate material and at least one other electrode on the substrate material. One insulating layer is connected between the two, and a certain distance from the substrate surface that holds the internal electrodes. This is achieved by placing the Using this method, the internal electrode space This allows for better shielding and measurement Noise resistance can be improved.

Furthermore, a counter electrode can be added to the working electrode, in which case at least two A working electrode and one counter electrode are provided at a radial distance from the reference electrode and preferably Preferably, the counter electrode should be larger than the working electrode, and the inside of the internal reference electrode should be It is advantageous to configure the heart distance to be larger than the working electrode. This method When used, a sufficiently effective shielding is also obtained for the working electrode, which makes the measurement possible. This makes it possible to further ensure a certain level of noise reduction.

When constructing a high-capacity reference electrode with high long-term stability, the inner electrode can be shaped like a needle. electrodes, at least one other electrode having at least one insulating layer interposed therebetween; the internal electrode at least partially surrounds the internal electrode, and the internal electrode is inserted through the through hole in the insulating layer. An arrangement in which the respective electrolytes are connected is advantageous. In this case, the internal electrode Each cavity can accommodate the electrolyte required for the second type of electrode, and the internal The electrodes are connected through through-holes to the respective electrolyte on which the measurement is to be carried out; In this way, it can also be used as a counter electrode.

According to a further advantageous embodiment, the inner electrode is placed in a cavity formed by the insulating layer; and at least one other electrode is embedded in the insulating layer and opening into the cavity, or Alternatively, a structure in which it is provided on the surface of an insulating layer is appropriate; By using a unique configuration, the internal electrode has good long-term stability and can be used many times. It can be realized.

Selective capture of certain electroactive species can be achieved using suitable permeable membranes. In the case of the present invention, the structure in which at least one film is provided on the electrode is It's advantageous.

In known methods, metals, in particular gold, platinum, palladium, iridium, are used as electrode materials. Conductive materials containing aluminum, rhodium, molybdenum, and tungsten, or carbon , in particular glassy carbon, polythione, or polypyrrole, and the desired For miniaturization, the electrode dimensions are preferably from a fraction of a micrometer to a fraction of a micrometer. It is between the limits.

In order to selectively capture metabolites or perform other biological measurements, the electrode structure requires to immobilize biologically active molecules and substances, especially enzymes and antibodies. The operation of the micro-multi-electrode structure according to the invention is advantageous in that the electrode structure can be constructed particularly easily by providing it on a substrate designed as a puncture sensor. Wear.

In particular, to enable fairly long-term monitoring within blood vessels and internal organs, the electrode structure must be It is advantageous to use a configuration in which the catheter is embedded in a substrate formed as a catheter. It is.

Hereinafter, the present invention will be explained in detail with respect to each embodiment shown in the drawings, and each embodiment will be explained in detail. In the description further advantages of the arrangement according to the invention are mentioned.

FIG. 1 is a sectional view showing a first embodiment of a micro multi-electrode structure according to the present invention, and FIG. , is a scaled plan view of the embodiment of FIG. 1 viewed from the direction of arrow H, and FIG. FIG. 3 is a cross-sectional view taken along the straight line 1-1. FIG. 4 is a plan view similar to FIG. FIG. 5 is a cross-sectional view showing yet another modified embodiment of the multi-electrode structure, which is a modification of the embodiment of FIG. 4 is a scaled plan view seen from the direction of arrow V, and FIG. 4 is a straight line IV-IV in FIG. Figure 6 shows a variant with a multilayer structure. A sectional view showing an example similar to FIGS. 1 and 4, FIG. 7 shows the configuration of FIG. 6 in the direction of the arrow ■. FIG. 6 is a cross-sectional view taken along the straight line Vl-Vl in FIG. 7. FIG. 8 is a sectional view showing an example of the needle-like electrode structure according to the present invention. 9 shows still another embodiment in the plane shown as II (II) in FIG. 2.3.5 or 7. 10 to 13 are cross-sectional views showing still other modified embodiments. The electrode is at least partially embedded within the insulating layer and formed within the insulating layer. 14 and 15 lead to a micro-multielectrode structure according to the invention. 3 is a plan view showing various embodiments of the substrates used, each having one common base; FIG. 16 and 1 with multiple microelectrode systems formed on the plate. 7 shows further applicability of the micro multi-electrode structure according to the present invention, When the electrode structure of the present invention in the embodiment of FIG. 16 is implanted within a catheter, The configuration examples in FIG. 17 each show a case where the system is applied to a once-through system.

In FIGS. 1 and 2, electrodes l, 2 and 3 are arranged on an inert substrate 5, They are electrically insulated from each other via an insulating layer 4. An overview of its functions is In other words, the internal electrode 1 used as a reference electrode is at least partially surrounded by an external electrode 2 adjacent to the Interrupted electrodes consisting of partially circular segments 2a, 2b, 3a, 3b The structure can be drawn out and used, and in addition, the inactive area is smaller than the active electrode surface. It is also formed small.

In the configuration shown in FIG. 3, the internal electrode 1 consists of two approximately semicircular electrodes located on the same radius. 2, and the internal electrode 1 not only functions as a reference electrode but also as a measuring electrode. Alternatively, connection can be made as a counter electrode to the working electrode.

4 and 5, the individual electrodes 1-3 are similarly mounted on an inert substrate material 5. are provided, and even in the case of brackets, the reference electrode 1 is concentric with the measuring electrode or working electrode 2. surrounded by Furthermore, a counter electrode 3 surrounds this measuring electrode 2. Meddling, And the connection is made using feed-through contacts 6 that pass through the inert substrate 5. this The configuration allows for a closed electrode structure.

In the case of the configuration according to FIGS. 6 and 7, the reference electrode is placed in the center of the structure on the inert substrate 5. l is attached. The reference electrode 1 is then surrounded by an insulating layer 4, which at the same time , the electrically contacting conductor tracks, indicated schematically by the symbol 15, are not shown in detail. Insulate until reaching the external terminal. On top of this insulating layer 4, at least A measuring electrode 2 is attached, which electrode and the contact conductor track are also surrounded by an insulating layer 4 at the same time. make sure that it is included. Further, on this insulating layer 4, a counter electrode 3 is provided concentrically. . Therefore, when viewed from above 5Fi5, internal electrode 1 is surrounded by other electrodes 2 and 3. It is rare. Thereby, the configuration shown in Figure 6 also allows for an uninterrupted electrode structure. do.

In addition, each electrode is electrically insulated from each other, and is energized using an opening. Connected to contacts. In such a configuration, the inner electrodes are separated by each outer electrode. quasi-shielded, which allows the measurement of small measured quantities in various measurement processes. Even in this case, measurements with extremely low noise are possible.

Additionally, the outer electrodes are slightly larger than the immediately inner electrodes due to their geometry. This allows the inert counter electrode to be larger than the respective measurement electrode. The need to listen is satisfied.

The basic advantage of the electrode structure according to the invention is that it is geometrically optimal and has minimal dimensions. , it is possible to realize a multi-electrode structure in the form of a four-plane structure. As a result, quasi-Miku It is possible to achieve miniaturization down to the long range.

A further possible three-dimensional structure is shown in cross section in FIG. In this case, glass or metal An open hole for the measurement environment is placed on the conductive needle-shaped substrate l formed as a microelectrode. An insulating layer 4 is provided.

Further, a measuring electrode 2 is provided concentrically with this, and a facing type 8i is provided via an insulating layer 4. Insulate from 3. The entire structure is then surrounded from the outside by an insulating layer 4. this structure is particularly advantageous when used as a puncture sensor.

FIG. 9 shows yet another multi-electrode structure. In this case, use it as a reference electrode. The enclosed electrode 1 is concentrically surrounded by two measuring electrodes 2a and 2b. Ma A counter electrode 3 surrounds the entire structure. On the one hand, such a configuration has two different It has the advantage of having the ability to detect electrochemically active species, and on the other hand, The product generated at electrode 2a is again replaced by electrode 2b, thereby characterizing the species. possible. The configuration in Figure 9 has a better effect on diffusion than the configuration in Figure 2. This has the advantage that a suitable geometrical arrangement can be obtained.

Furthermore, by using appropriate structural measures and special processing techniques, each electrode The insulating layer provided should be as thin as possible so that electrically active species or Optimum loading and unloading of generated products becomes possible. In such a structure, insulation There is no buildup of reaction products in the edge region of the transition zone between the layer and the electrode material.

However, an increase in the electrode area of reaction products or electroactive species, or When uniform current density distribution is required, it is possible to by using three-dimensional structures as shown in Figures 10 to 13, A fixed amount is carried in front of a metal electrode and the concentration of this substance is maintained at a constant value over a long period of time. It is possible to maintain the Therefore, such three-dimensional structures can be used for protection and diffusion. The membrane is used in a fixed amount in a fixed place to maintain its function over a long period of time. be able to.

FIG. 10 shows a possible configuration when the electrode l is placed directly on the inert substrate 5. This shows one of the following. The electrode 1 is surrounded by an insulating layer 4. This insulating layer 4 An electrode 2 is provided at the top. Furthermore, an insulator N4 is provided on top of it. Moreover, an electrode 3 is provided thereon. Electrode 3 preferably serves as a counter electrode used.

The structure of the electrode 3 can be modified in various ways, and one modification example is shown in FIG. As shown. In this case, electrode 3 is placed directly on electrode 2 following insulating layer 4. It is provided. This creates a three-dimensional structure as a heavy cylindrical cavity. can be done.

By using special insulating layers, e.g. polyimide, the construction height and therefore The quasi-cavity length can be made up to several hundred microns.

FIG. 12 further shows a quasi-closed variation of the electrode structure. in this case , an electrode 1 on an inert substrate 5 is concentrically surrounded by an insulating layer 4 . Absolutely On the edge layer 4 there is an electrode 2 used as a measuring electrode, on which an insulating layer 4' -9 Further, an electrode 3 is provided on that side. The insulating layer 4' is micro-processed. It can be made of silicon. Also, other modifications similar to the modification shown in FIG. As a modification, as shown in FIG. 13, the electrode 3 may be configured differently. It is possible.

All conductive substances can be used as electrode materials, especially metals. , conductive polymers, and glassy carbon, as well as gold, platinum, palladium, and silver. Particular preference is given to using noble metals which can be processed by thin film lithography. Also for special purposes It is also possible to use other metals as electrode materials.

Furthermore, various electrode materials can be used in the micro-multielectrode structure. follow Therefore, electrodes 1f+1 to 3 can be constructed using different electrode materials. Ru.

In addition to a roughly single electrode structure, it is also possible to combine multiple such electrode structures to create the same structure. It is also possible to create a flat multi-electrode using a similar method. Figures 14 and 1 5 shows an example. In this case, on one inert substrate 5, -7 or two or more electrode structures as shown in FIGS. 1O-13 are provided.

In the simplest case, such a microelectrode structure can be used as a three-electrode structure for macroscopic testing. All electrochemical test processes in all systems are It can be used for

In this case, it is used as a voltage-current deformation sensor. at the same time or with this Apart from this, this structure can also be used as a miniaturized reference voltage, ρ sensor, or Used for conductivity type sensors. Furthermore, such a structure can contain e.g. oxygen or Used as an electrochemical actuator for hydrogen production or as a stimulating electrode can be done. Furthermore, such a structure can be used as a matrix for impedance spectrometers. It can be used as a microsensor.

Similarly, use as a biosensor is also possible. For this, one of the electrodes must be Immobilize the enzyme. Also, for example, a plurality of electrodes as shown in Figure 2.3 or 9. It can also be used with separate enzymes. The electrode structure shown in Figure 14 is extremely small. Perform differential measurements between active and denatured enzymes in each measurement medium in a small space It can be used for. The resulting noise suppression improves measurement precision. Fundamental improvements in accuracy and reproducibility are obtained.

A further advantage of this electrode structure is that a protective film can be placed on one or the other of the electrodes, respectively. The electrode structure and assembly shown in Figures 10 to 13 are For the configurations shown in FIGS. 11 and 13, the top layer is It is also possible to form a protective film instead of the edge layer 4 or 4'.

As for operability, the form of a puncture sensor (Fig. 15) is possible, as well as the For example, a glucose It is also possible to transform it into a sensor such as the gas sensor 9, which allows for example It becomes possible to directly test the concentration of substances.

Furthermore, this micro multi-electrode structure can be integrated on one measurement chimbu 12, e.g. For example, it can be integrated into the conduit 13 as a flow sensor in a medical analyzer. (FIG. IT), in which case the measuring chip I2 is accommodated in the molded body 14. microphone The electrode structure is used as a group of sensors arranged in a two-dimensional array for cell culture testing. used to directly measure gases in the blood, such as oxygen. Can be used.

F Engineering G, 4F Engineering G, 1- Engineering G, 5F Engineering G, 8 F Engineering G, 10 F Engineering G, 11F Engineering G, 12 r Engineering G, 13 IO F Engineering G, 16 '73 r Engineering G, 17 Procedural amendment (formality) %formula% 2. Name of the invention Micro multi-electrode structure 3. Person making the correction Relationship to the case: Applicant 5. Date of amendment order: August 27, 1991 6. Subject of amendment: Specification and Translation of claims international v4f, report international search report

Claims (18)

[Claims] 1. electrically active electrodes (1, 2, 3) disposed on one substrate (5); In micro-multielectrode structures for electrochemical measurement and generation of species, one internal An electrode (1) and at least two other electrodes (2, 3) are provided and an internal electrical The pole (1) is connected as a reference electrode, the other electrodes (2, 3) are connected to the internal electrode (1). The micrometer is characterized in that it at least partially surrounds the substrate (5) in terms of shadow. Black multi-electrode structure. 2. Claims characterized in that the electrodes (1, 2, 3) are arranged concentrically. The electrode structure according to item 1 above. 3. The layers forming the electrodes (1, 2, 3) are separated by at least one insulating layer (4). The electrode structure according to claim 1 or 2, characterized in that the electrode structure is separated. Construction. 4. The electrodes include at least partially circular ring-shaped segments (2a, 2b, 3a, 3 b) and the area of the inactive separation region is the area of the active electrode segment. According to claim 1, 2, or 3, it is smaller than electrode structure. 5. A claim characterized in that the electrodes (1, 2, 3) are provided in a common plane. The electrode structure according to items 1 to 4 of the desired range. 6. The individual electrodes (1, 2, 3) pass through the through-holes (6) of the substrate (5) and connect to the substrate (5). 5) is connected to the contact portion on the side opposite to the electrode. The electrode structure according to items 1 to 5. 7. The internal electrode (1) is provided on the substrate material (5) and at least one other electrodes (2, 3) of the substrate (5) with at least one insulating layer (4) as an intermediate connection; It is characterized by being provided at a distance from the surface supporting the internal electrode (1) of the An electrode structure according to claims 1 to 6. 8. At least two working electrodes (2a, 2b) and one counter electrode (3) are connected to the reference Claim characterized in that it is provided at a radial distance from the electrode (1). The electrode structure according to items 1 to 6 in the range. 9. The counter electrode (3) is larger than the working electrode (2) and has an internal reference electrode (1). The claimant is characterized in that the center distance from the working electrode (2) is greater than that of the working electrode (2). The electrode structure according to items 1 to 8 of the desired range. 10. The internal electrode (1) is formed from a needle-shaped electrode (1) and has at least one The other electrodes (2, 3) are the internal electrodes ( 1), and furthermore, the internal electrode (1) is located within the insulating layer (4). (Fig. 8). The electrode structure according to any one of claims 1 to 9, characterized in that: 11. The internal electrode (1) is provided in the cavity formed by the insulating layers (4, 4'), and Furthermore, at least one other electrode (2, 3) is embedded within the insulating layer (4) and It communicates with the cavity or is provided on the surface of the insulating layer (4) (Fig. 10 13). The electrode structure according to any one of claims 1 to 10, characterized by: 12. Particularly, on the electrodes (1, 2, 3) at least one membrane is provided. The electrode structure according to any one of claims 1 to 11, characterized in that: 13. Metals, especially gold, platinum, palladium, iridium, and rhodium, can be used as electrode materials. conductive materials containing aluminum, molybdenum and tungsten, or carbon, especially Glassy carbon, polythione, or polypyrrole is used. An electrode structure according to claims 1 to 12. 14. A second type of electrode is used as the internal electrode (1). An electrode structure according to claims 1 to 13. 15. The dimensions of the electrodes (1, 2, 3) range from a fraction of a micron to a fraction of a millimeter. The electrode structure according to any one of claims 1 to 14, characterized in that the electrode structure is between 1 and 2. . 16. Biologically active molecules and substances, especially enzymes and antibodies, are immobilized on the electrode structure. The electrode structure according to any one of claims 1 to 15, characterized in that: 17. The electrode structure is provided on a substrate formed as a puncture sensor ( 15), the electrode structure according to any one of claims 1 to 16. 18. The electrode structure is provided on a substrate formed as a catheter ( 16), the electrode structure according to any one of claims 1 to 17.