KR20110104250A - Method of manufacturing planar bio-test strip and product thereof - Google Patents

Abstract

The present invention relates to a method for manufacturing a planar biological test strip and a finished product thereof. More particularly, the test strip includes a base piece, and a conductive circuit formed by a vapor plating method is installed on the base piece. The front and rear ends of the test electrode stage and the electrode circuit stage which is electrically connected to each other is provided, and the present invention also includes an enzyme reaction zone, the enzyme reaction zone is connected to the front end of the test electrode end, The manufacturing method includes (1) forming a shielding pattern by printing using a plastic thin film as a base piece, and (2) forming a base piece on which the shielding pattern is printed as a conductive plating layer by a vapor plating method, and (3) Physically remove the conductive plating layer covering the shielding pattern to expose the conductive circuit, and (4) enzyme reaction. The enzyme is placed on the reverse side, (5) covered with an upper cover membrane, and bonded, and this method can mass-produce the test strips and not only achieve the economic effect of reducing the production cost, but also improve the stability of the product quality and the market competitiveness. It can be increased.

Description

METHOD OF MANUFACTURING PLANAR BIO-TEST STRIP AND PRODUCT THEREOF

The present invention relates to a method for producing a planar biological test strip and a finished product thereof, and more particularly, to a test strip capable of testing a liquid physiological situation of a living body such as blood sugar, cholesterol, or urine fluid in human blood, and more particularly, a relatively good stability. The present invention relates to a manufacturing method that can produce finished products with high accuracy and accuracy and obtain economic benefits from the manufacturing process.

The average life expectancy of modern people is increasing and modern medical science and technology have made it possible to pretest and confirm the symptoms hidden in the human body through medical equipment, which can help to detect, prevent and treat diseases early. It became. For example, the blood glucose test of the human body is described. First, a small amount of blood is collected from the human body, and the collected blood is dropped into the blood glucose enzyme region on the test strip, and then the test is performed. Then, the blood glucose test meter starts the analysis and measures the blood glucose value of the human body. If there is an abnormality in the user's blood sugar level, it can be detected in advance to prevent the disease before it becomes more serious.

Referring to FIGS. 1 and 2 showing a conventional blood sugar reaction strip, the reaction strip 90 has a substrate 100 composed of a single piece of a soft plastic material (such as polyamide, for example), and on the substrate. A conductive circuit in which a conductive graphite material is printed in a mesh manner or coated with a copper thin film on the surface of the substrate 100 and then electrically connected to each other by photolithography, etching, or the like. And a test electrode end 931 and an electrode circuit end 932 are installed at the front end and the rear end of the conductive circuit 93, and the front end of the test electrode end 931 is an enzyme. It is connected to the reaction zone 92 (with enzyme) and siphon (91, siphon), and then covers the top cover 96, then exposes the electrode circuit stage 932 to the outside and finally Cut to the right size to complete the product All.

In the case of using, when the blood collected in the siphon (91) touches, the blood is absorbed to the enzyme reaction zone 92 through the capillary action, and then glucose and enzyme in the blood reacts to the electron flow The generated electron flow is passed through the test electrode terminal 931 and flows to the electrode circuit terminal 932, and the electrode circuit terminal 932 is connected to the blood sugar test device 95. The blood sugar test device 95 measures a current input through the electrode circuit stage 932 and converts the current into one novel signal, and finally, converts the corresponding electric signal into a blood glucose level corresponding thereto.

Although the conventional blood glucose response strip 90 described above has the effect of measuring blood glucose levels, it still has many disadvantages in its manufacturing method. For example, first, the first test electrode end 931 and the rear end electrode circuit end 932 are formed on a substrate made of a single piece of soft plastic 100 by graphite mesh printing. However, since the test electrode end 931 and the electrode circuit end 932 have a relatively long length and a relatively large area, the test electrode end 931 and the electrode circuit end 932 are relatively unstable at the time of processing, and thus, the electrical resistance value is unbalanced. And secondly, for example in US Patent Publication No. 7,465,597, the present invention relates to the fabrication of a conductive circuit of a blood sugar reaction strip using "Ore Lithography." The figure of the conductive circuit, which has already been designed, is precisely formed into a photo mask and then duplicated on the substrate, and the present invention projects the figure onto the substrate by applying an optical image forming principle. Since the light emitted from the light source continuously passes through the transparent portion of the photo mask to form an image on the surface of the substrate, the surface of the substrate must be cleanly treated, and then a photo resist must be applied again. The light rays passing through the photo mask react with the photoresist and we expose After the exposure is completed, the substrate is developed again, and the conductive metal without the photoresist and the shielding layer with the photoresist are installed again. When the photoresist is removed by chemical method (dissolution, acid etching), the metal covering the upper surface is also removed, leaving only the metal circuit, that is, the conductive circuit of the desired shape is manufactured in this way. Subsequent processing is followed by installation of the enzyme reaction zone, installation of the top cover and cutting to the appropriate size to make the finished product.

 Here, the conductive circuit of the blood sugar reaction strip produced by using the above-mentioned "optical plate technique" does not have problems such as the precision of the conductive circuit itself is low, the area is large due to graphite material, or the voltage control is not easy. This technique is used to form conductive circuits in micro devices and circuit boards with high precision. Therefore, there is a disadvantage in that the production cost is relatively high. In addition, since the photoresist sites are removed with chemicals after acid etching, the remaining acid residues may destroy the activity of the enzyme, and furthermore, when the enzyme is degraded or the environment is contaminated when the manufacturing process is not accurately controlled. May cause problems such as In view of the foregoing, this patent is not an ideal method. In conclusion, how to effectively solve and overcome the shortcomings of the conventional method for producing a blood glucose response strip has emerged as a very important problem, the inventors of the present invention is a method of producing and manufacturing a conventional planar biological test strip Based on the shortcomings, many years of practical experience and research and development have solved this problem, suggesting a method for manufacturing flat biological test strips with accuracy, stability and economy.

SUMMARY OF THE INVENTION An object of the present invention is to provide a method for producing a planar biological test strip and a finished product thereof, the contents of which are used as a base piece of plastic (the material of the base piece does not have elasticity), and is printed there. Finishing the finished product in the unit way, not only achieves the economic benefits of faster productivity and cost reduction, but also further simplifies the processing process, thereby increasing product quality stability and market competitiveness.

It is another object of the present invention to provide a method for producing a planar biological test strip with environmental protection function and a finished product thereof, and the printing method is treated with a shielding pattern (for example, using non-toxic ink) and again. After forming the metal conductive plating layer through the vapor plating process, the conductive plating layer covered on the shielding pattern was removed in a physical manner (for example, water washing) to expose the unblocked conductive circuit. This entire manufacturing process produces physical properties, which not only provides environmental protection, but also enables easy control of resistance values, more stable conductivity, and further improves the accuracy and agility of microcurrent measurement in electrochemical reactions. You can do it.

Technical means used in the present invention to achieve the above object includes the following contents. First, the present invention includes a base piece, and the base piece is composed of a plastic thin film, and forms a conductive circuit on the base piece through a vapor plating process, and in order to the front end and the rear end of the conductive circuit. A test electrode stage and an electrode circuit stage are provided, and further include an enzyme reaction zone, wherein the enzyme reaction zone is provided at the front end of the test electrode stage, and also includes an upper lid film, and the upper lid film is It is installed on the base piece to cover the base piece, wherein the electrode circuit terminal is conveniently exposed to the outside to proceed with the test.

Technical means used in the present invention to achieve the above-mentioned object includes another content as follows. The test electrode end of the conductive circuit on the ground piece is first completed by coating or printing a conductive material (such as graphite, conductive silver ink, etc.) that does not easily undergo chemical changes with the enzyme, and then the electrode circuit end and the test electrode end are separated from each other. A vapor-plated metal conductive material is applied to the test electrode terminal far from the electrode circuit stage and the enzyme reaction zone so as to allow electricity to pass through, and an upper and lower layer is formed on the test electrode terminal of the enzyme reaction zone to bond with each other. Complete the electrode. In this structure, since the test electrode terminal contacting the enzyme reaction zone is formed of a conductive material that does not easily cause chemical change with the enzyme, the stability of the test is high, and the enzyme component is increased even if the environment is changed or the storage period is extended. Since this does not change, the coefficient of variation CV can be easily controlled.

Technical means used in the present invention to achieve the above-mentioned object includes another content as follows. The base piece is composed of a plastic thin film in the form of pieces, and is then completed using a method of printing unit objects in large quantities.

Technical means used in the present invention to achieve the above-mentioned object includes another content as follows. The base piece is composed of a plastic thin film in the form of a roller, and is completed by a method of continuously printing a unit object in a roll to roll method.

In order to achieve the above object, the method of manufacturing the planar biological test strip of the present invention includes the following manufacturing process. (1) After forming a base piece with a plastic film of at least one layer and forming a shielding pattern by a printing method, the printed pattern of the test electrode end and the printed pattern of the electrode circuit end are exposed using the shielding pattern. (2) A conductive circuit is formed by a vapor plating method, and the conductive plating layer is applied to the base piece by using a steam plating process on the base piece on which the shielding pattern is printed. (3) The conductive plating layer area in which the shielding pattern is printed is removed. In this case, the conductive plating layer region in which the shielding pattern is formed in a physical manner is removed to expose a complete conductive circuit, and the conductive circuit includes a test electrode terminal and an electrode circuit terminal. (4) Place the enzyme in the enzyme reaction zone of the base piece. (5) An upper lid film is covered on the base piece and the electrode circuit end is exposed.

In order to achieve the above object, the present invention includes another manufacturing process as follows. (1) The test electrode ends are completed by forming a base piece with at least a single layer of plastic thin film and applying or printing a conductive material (such as graphite and conductive silver ink) which is not easily changed with enzyme. (2) A shielding pattern is formed by a printing method, and the shielding pattern is used to expose the electrode circuit end printed pattern. (3) forming a conductive circuit by a vapor plating method, and forming a test electrode terminal and an electrode circuit terminal far from the enzyme reaction zone by vapor plating a metal conductive material on the ground piece on which the shielding pattern is completed; The conductive plating layer is continuously covered on the base piece, and the electrode circuit terminal and the test electrode terminal are formed in a form in which electricity flows to each other, and upper and lower layers are formed on the test electrode terminal to complete the electrodes to be coupled to each other. (4) The conductive plating layer area in which the shielding pattern is printed is removed. In this case, the conductive plating layer region in which the shielding pattern is formed in a physical manner is removed to expose a complete conductive circuit, and the conductive circuit includes a test electrode terminal and an electrode circuit terminal. (5) Place the enzyme in the enzyme reaction zone of the base piece. (6) An upper lid film is covered on the base piece and the electrode circuit end is exposed.

In order to achieve the above-mentioned object, the planar biological test strip of the present invention further includes another manufacturing process as follows. The base piece is composed of a plastic thin film in the form of a roller, and is completed by a method of continuously printing unit materials in a roll-to-roll manner, thereby enabling rapid production in large quantities and production. Economic benefits that reduce costs can be achieved. It also simplifies processing and improves product quality stability and market competitiveness.

In summary, the inventors of the present invention planar biological test strips can be completed quickly in large quantities because they can be completed in the above-described printing thin film (such as plate printing or screen printing) or roll to roll. In addition to the economic benefits of being able to produce finished products and reducing production costs, the process can be simplified, the stability of product quality and the competitiveness of the market can be improved. This results in more stable, more accurate and agile test results.

1 is a perspective view showing the structure of a conventional blood glucose response strip.
Figure 2 is a perspective view showing a manufacturing process of a conventional blood glucose response strip.
3A-3D are perspective views showing the configuration according to the first embodiment of the present invention.
4 is a flowchart showing a manufacturing method of the first embodiment of the present invention.
5 is a perspective view showing the flow of the manufacturing process of the first embodiment of the present invention.
Figure 6 is a perspective view showing the arrangement of the manufacturing process of the first embodiment of the present invention.
7A-7E are perspective views showing the configuration according to the second embodiment of the present invention.
8 is a flowchart showing a manufacturing method of the second embodiment of the present invention.

In order to more clearly describe the present invention, the structure of the present invention and its technical details will be described in detail with reference to the accompanying drawings.

3A-3D are perspective views showing a first embodiment of the present invention for constructing a planar biological test strip. Referring to Figures 3A-3D, the biological test strip 10A includes a base piece 11A, wherein the base piece 11A has a single layer or a plurality of layers or a roller form (in this embodiment, a roller form). Continuous plastic thin film (e.g. PET thin film, PC thin film, PTFE thin film, nylon, polycarbonate, polystyrenes, styrene thin film, acrylonitrile thin film, or ABS) Thin film (Acrylonitrile butadiene styrene) using a material that does not have elasticity, such as those skilled in the art can be replaced by any material similar to this), and the vapor-plated on the base piece (11A) A conductive circuit 13A is provided in a manner, and a test electrode end 131A and an electrode circuit end 132A, which are electrically connected to each other in order, are provided at the front end and the rear end of the conductive circuit 13A, and the test electrode end ( 131A) The front end is connected to the enzyme reaction zone 16A, and an enzyme is installed in the enzyme reaction zone 16A, and an upper cover film 15A is also installed on the base piece 11A, and the test is performed. For convenience, the electrode circuit stage 132A exposes the outside.

Referring to FIGS. 3A and 3B together, the planar biological test strip 10A is configured in such a manner as to form a shadow mask 12A on the base piece 11A, and the shielding pattern The printed circuit of the conductive circuit 13A is exposed at 12A, and in this embodiment, the coating is not applied or printed on the test electrode end printed pattern area and the electrode circuit end printed pattern area in an engraved manner. Next, the conductive plating layer 17A is formed by vapor plating, and the conductive plating layer 17A region covered by the shielding pattern 12A is removed in a physical manner (for example, by washing with water) before the test. The extreme end 131A and the electrode circuit end 132A are exposed, and in this comparatively superior practice method, the shielding pattern 12A is formed by printing using non-toxic ink.

4 to 6, the method for manufacturing the planar biological test strip 10A of the present invention includes the following procedure.

(1) Shielding pattern 12A (21A) by continuously mass printing in the form of a piece or a roller (in this embodiment, using Roll to Roll) as an example (screen printing or recessed plate) Roller printing or the like may be used and the latter was used in this embodiment. That is, the plastic thin film 31 (for example, PET thin film, PC film, PTFE film, nylon film, nylon, polycarbonate, polystyrenes, styrene thin film, acrylonitrile thin film) formed in a roller form Or ABS thin film (acrylonitrile butadiene styrene) is used as a material of the base piece (11A) (as shown in Figure 3A), and the base piece (11A) is a recessed printing roller Continuous printing (or screen printing, can be replaced by a similar method to those skilled in the art) through the recessed plate of (32), a plurality of non-toxic aqueous on the recessed printing roller 32 A mesh pattern 321 for accommodating ink is provided and has a shielding pattern 12A for printing on the base piece 11A.

(2) The conductive plating layer formation 22A is formed by steam plating. That is, after performing the soft-drying treatment on the heat-drying equipment 33, the base piece 11A printed on the shielding pattern 12A is subjected to steam plating treatment on the vacuum vapor plating machine 34 again. At this time, the steam plating process is to roll the base piece (11A) through the steam plating roller to the roller finishing point (not shown in the drawing), and then to make a vacuum state using a vacuum pump and heat again to apply a high-purity conductive material (eg For example, a metal such as gold, copper, aluminum, etc.) is melted under a high temperature and evaporated in a gaseous state, and then the winding speed of the thin film is kept constant through a thin film winding facility, wherein the conductive metal fine particles which have become a gaseous state Are deposited on the surface of the base piece 11A, and then cooled again to complete a continuous conductive plating layer 17A on the base piece 11A.

During the vapor plating process, the vapor plating is controlled by controlling the evaporation rate of the conductive material (for example, metal such as gold, copper, aluminum), the moving speed of the base piece 11A, and the degree of vacuum in the vapor plating room. The thickness of the conductive plating layer 17A formed in this manner can be adjusted, and in this manner, the quality of the test electrode terminal 131A and the electrode circuit terminal 132A can be more accurately controlled.

(3) The conductive plating layer 17A (23A) covered on the shielding pattern 12A is removed. In other words, the base piece 11A after the steam plating process is removed, and the conductive plating layer 17A area covered on the shielding pattern pattern 12A (Mask) is removed through the cleaning equipment 35 (for example, water washing). The part exposed outside becomes the test electrode end 131A and the electrode circuit end 132A.

(4) Install an enzyme in the enzyme reaction zone of the base plate (24A). That is, the process of installing the enzyme using the enzyme printing equipment 36 in the ground piece 11A is performed, and the enzyme is placed on the ground piece 11A (enzyme reaction zone 16A), and the installation of the enzyme is performed. The method can be recessed, screen printed, spray printed or drip. In the present invention, if the depression printing method is selected, the thickness of the enzyme may be set differently according to the depth of the depression, and thus the enzyme reaction effect is more excellent, thereby obtaining more accurate test results.

(5) The top cover film is coupled to the base piece 11A (25A). That is, by using a plastic material (for example, a material such as plastic, acrylic, etc.) after the continuous printing process, the upper cover film 15A corresponding to each other is installed on the base piece 11A, and the electrode circuit end 132A is combined. ) To make testing more convenient. At this point, it should be remembered that the enzyme reaction zone 16A (test electrode end 131A) of the plastic thin film 31 may be installed to correspond to each other, as shown in FIG. Since the plurality of top cover films 15A can be installed, the efficiency of the manufacturing process can be improved.

(6) Cut into finished product in unit form (26A). That is, the plastic thin film 31 having all the correlation components installed therein is put into the cutting machine 37, and the cutting operation is performed to obtain a complete plurality of planar biological test strips 10A (glucometer).

7A-7E, a second embodiment of the planar biological test strip of the present invention is as follows. First, the biological test strip 10C includes a base piece 11C (the configuration of the base piece is the same as in the first embodiment), and a conductive circuit 13C is provided on the base piece 11C. The conductive circuit 13C includes a test electrode terminal 131C and an electrode circuit terminal 132C, among which the test electrode terminal 131C is a conductive material (graphite, conductive, which does not easily change chemically with an enzyme first). Or ink).

Subsequently, a vapor-plated metal conductive material (for example, a metal such as gold, copper, aluminum, etc.) is applied to the electrode circuit terminal 132C and the test electrode terminal 131C of the enzyme reaction zone 16C at a distance. The circuit terminal 132C and the test electrode terminal 131C are electrically connected to each other, and upper and lower layers are formed on the test electrode terminal 131C to complete the electrodes to be coupled to each other. Since the test electrode end 131C to which the enzyme reaction zone 16C contacts is formed of a stable conductive material, the enzyme of the enzyme reaction zone 16C does not cause chemical change, and thus the safety of the test is relatively high. The change factor (CV) can be easily controlled because the enzyme component does not change even if the environment changes or the storage period is extended.

8 is a flowchart showing a manufacturing method of the second embodiment of the present invention and includes the following contents.

(1) A test electrode is formed by printing or coating on a plastic thin film in advance (20C). That is, a plastic thin film in the form of a piece or a roller is used as a base piece material, and a test electrode end is formed by printing or applying a conductive material that does not easily react with an enzyme on the plastic thin film.

(2) A base plate having a shielded pattern is formed by a printing method (21C). That is, the shielding pattern 12C is printed on the base piece 11C, and the shielding pattern is connected to the test electrode end 131C.

(3) A conductive plating layer is formed by steam plating (22C). The base piece 11C on which the shielding pattern 12C is printed is subjected to a drying process, and then subjected to vapor plating to be tested at a place far from the electrode circuit stage 12C and the enzyme reaction zone 16C. The electrode end 132C and the test electrode end 131C are electrically connected to each other by forming an extreme end 131C, and an upper and lower layers are formed on the test electrode end 131C to complete the electrodes to be coupled to each other.

(4) The conductive plating layer 17A (23C) covered on the shielding pattern 12C is removed. That is, by removing the conductive plating layer (17C) area covered on the shielding pattern (12C) (Mask) by a physical method, the base piece (11C) after the steam plating process is completed by a washing facility (for example, water washing). At this time, a portion exposed outside becomes the test electrode end 131C and the electrode circuit end 132C.

(5) Install an enzyme in the enzyme reaction zone of the base plate (24C). That is, the process of installing the enzyme using the enzyme printing equipment 36 in the base piece (11C) proceeds, wherein the enzyme is placed on the base piece (11C) (enzyme reaction zone), the installation method of the enzyme Can be recessed, screen printed, spray printed or dripping.

(6) The top cover film is bonded to the base piece (11C (25C)). That is, by using a plastic material (for example, plastic, acrylic, etc.) that has completed the continuous printing process, the upper cover film 15C corresponding to each other is installed on the base piece 11C, and the electrode circuit end 132C is combined. ) To make testing more convenient.

(7) Cut into finished product in unit form (26C). That is, the plastic thin film 31 having all the correlated components installed therein can be cut into a cutting machine to obtain a complete plurality of planar biological test strips 10C (glucometer).

The foregoing has been described by way of example only in order to explain in detail the features and advantages of the present invention in a relatively good embodiment, the scope of the patent application is not limited to this without departing from the spirit and scope of the patent application and All other modifications and other processes are included in the scope of this patent application.

10A, 10C Biology Test Strips
11A, 11C Ground Scrap
12A, 12C shielded pattern
13A, 13C conductive circuit
131A, 131C test electrode
132A, 132C electrode circuit
15A, 15C Top Cover Membrane
17A, 17C conductive plating layer
16A, 16C enzyme reaction zone
31 plastic thin film
32 recessed printing roller
321 mesh pattern
33 Thermal Drying Equipment
34 vacuum vapor vending machine
35 Cleaning Equipment
36 Enzyme Printing Equipment
37 cutting machine
The test electrode is formed by printing or coating on a plastic thin film in advance. (20C)
The base plate is equipped with a shielding pattern. (21A, 21C)
The conductive plating layer is formed by a vapor plating method. (22A, 22C)
The conductive circuit layer is exposed by physically removing the conductive plating layer covering the shielding pattern. (23A, 23C)
Place the enzyme in the enzyme reaction zone on the base plate. (24A, 24C)
Bond the top cover to the base plate. (25A, 25C)
Cut into finished products in unit form. (26A, 26C)

Claims (14)

A planar biological test strip, wherein the test strip comprises a base piece and an enzymatic reaction zone, wherein the base piece consists of a plastic film, a shielding pattern is printed on the base piece, and the shielding pattern A conductive circuit is formed on the substrate by a vapor plating method, and the conductive circuit includes a test electrode terminal and an electrode circuit terminal that are in electrical communication with each other, and the enzyme reaction zone is connected to a front end of the test electrode terminal. Flat biological test strips. A planar biological test strip, wherein the test strip comprises a base piece, a conductive circuit, and an enzyme reaction zone, wherein the base piece is composed of a plastic thin film, the conductive circuit is installed on the base piece, The conductive circuit also includes a test electrode end and an electrode circuit end, wherein the test electrode end and the electrode circuit end are provided in electrical communication with each other, and the test electrode end is formed by applying or printing a conductive material. The electrode circuit terminal is formed by printing a shielding pattern on the ground piece and installing a metal conductive material on the shielding pattern by a vapor plating method after completing the test electrode terminal. Planar biological test strip, characterized in that connected to the front end of the test electrode. The method of claim 2,
And one end far from the enzymatic reaction zone on the test electrode end forms a metal conductive material formed by a vapor plating method and an electrode coupled to each other in an upper and lower layers. The method of claim 2,
Planar biological test strips using a material such as graphite or conductive silver ink as the conductive material for forming the test electrode end. The method according to claim 1 or 2,
The base piece is a planar biological test strip, characterized in that formed by adhesively bonding a single layer or a plurality of plastic thin films. The method according to claim 1 or 2,
The base piece is a PET thin film, a PC film, a PTFE film, a nylon film (Nylon), a polycarbonate film (polycarbonate), a polystyrene film (Polystyrenes), a styrene thin film, an acrylonitrile thin film, or an ABS thin film (Acrylonitrile butadiene styrene), etc. Flat biological test strips using the same material. The method according to claim 1 or 2,
The vapor plating metal conductive material of the conductive material is a planar biological test strip, characterized in that using a metal such as gold, silver, copper or aluminum. The method of making flat biological test strips
(1) forming a base piece with a roller-shaped plastic thin film, and again forming a shielding pattern by a printing method, wherein the shielding pattern is used to represent the printed pattern of the test electrode terminal and the printed pattern of the electrode circuit terminal. ,
(2) forming a conductive circuit by a vapor plating method, and installing the shielded pattern printed base piece by applying a continuous plating layer on the base piece through a process of vapor plating,
(3) The conductive plating layer covered on the shielding pattern is removed, that is, the conductive plating layer of the shielding pattern is removed by a physical method so that the conductive circuit is completely exposed, and the conductive circuit is electrically connected to each other before the test. It includes an extreme end and an electrode circuit end.
(4) A method for producing a planar biological test strip, comprising installing an enzyme in an enzyme reaction zone on a base piece. The method of making flat biological test strips
(1) The base of the test electrode is formed by forming a base piece with a roller-shaped plastic thin film and applying or printing a conductive material that does not easily undergo chemical changes with enzymes.
(2) forming a shielding pattern on the base piece by a printing method, and the shielding pattern pattern and one end of the test electrode terminal are connected to each other,
(3) forming a test electrode end and an electrode circuit end away from the enzyme reaction zone by vapor plating a metal conductive material on the ground piece on which the shielding pattern is formed, and forming a continuous conductive plating layer on the ground piece. The electrode circuit end and the test electrode end are formed in a form in which electricity is in communication with each other, and forms an upper and lower layers on the test electrode end to complete the electrodes to be coupled to each other,
(4) after finishing the plating process, the conductive plating layer covered on the shielding pattern of the base piece is washed and removed to expose the test electrode terminal and the electrode circuit terminal.
(5) A method for producing a planar biological test strip comprising installing an enzyme in an enzyme reaction zone on a base piece. The method according to claim 8 or 9,
The shielding pattern is a method of manufacturing a planar biological test strip, characterized in that the printing by using a non-toxic non-ink ink, printed by screen printing or screen printing method. The method according to claim 8 or 9,
The vapor plating metal conductive material of the conductive material is a method of manufacturing a planar biological test strip comprising a metal such as gold, silver, copper or aluminum. The method according to claim 8 or 9,
The enzyme is a method of manufacturing a planar biological test strip, characterized in that it can be installed on the base piece continuously in a recessed plate, screen printing, ink spray or drop. The method according to claim 8 or 9,
Method of manufacturing a planar biological test strip comprising the step of bonding the top cover film on the base piece, and then cut into a finished product in the form of a unit. 10. The method of claim 9,
And a material such as graphite or conductive silver ink as the conductive material for forming the test electrode end.

Images