JP3952156B2 - Biosensor - Google Patents

Description

【００８７】
なお、表１における各符号の意味は、次のとおりである。
＜乾燥後＞
×：剥離
△：周辺捲れ
○：きれいな膜
＜緩衝液中＞
×：すでに剥離か溶液の振蕩で剥離
△：溶液振蕩で剥離しないが、周辺膨潤またはピンセットで簡単に剥離
○：きれいな膜。ピンセットで引っ掻いた場合、ピンセットとの接触面よりも少し広い幅で膜が取れる
◎ピンセットで引っ掻いた場合、ピンセットと接触した部分だけ膜が取れる
【００８８】
表１からわかるように、すべての実施例において、比較例より酵素膜の付着力が向上した。また、実施例９の５つの例の比較から、混合層中の高分子Ｂの含量が多いほど（すなわち高分子Ｂの表面露出面積比が大きいほど）、酵素膜の付着力が強いことが判った。より具体的には、高分子Ｂの比率が２０％（物質Ａ：高分子Ｂ＝４：１）以上が望ましい。
【００８９】
（実施例１５）フローインジェクション分析装置によるセンサの評価
実施例６〜１２で作成したセンサをフローセルに装着し、図２０に示すフローインジェクション分析装置で、アスコルビン酸（ＡＳＡ、１００ｍＭ）、およびグルコース（１０ｍＭ）の溶液に対する応答のピーク電流を測定した。測定条件を以下に示す。
・キャリア液：３３ｍＭのリン酸二水素カリウムとリン酸一水素ナトリウム、５０ｍＭの塩化カリウムを含む緩衝溶液。ｐＨ６．８。
・流速：１．０ｍｌ／ｍｉｎ
・サンプル注入量：１０μｌ
・チューブ：サンプラーのサンプルインジェクターからセンサまでのチューブ長が１２０ｃｍ、内径が０．８ｍｍ。
得られた結果を、単位濃度当たりの出力（感度）および選択比にまとめて、表２に示す。
【００９０】
【表２】

【００９１】
表２から、混合層の材料および作成方法によりＡＳＡ／グルコース選択比が大きく異なることが分かり、また、選択比が低いと感度も低い傾向が見られた。一般的にいうと、センサの感度が高いほど、また、選択比が低いほど、センサとしては望ましい。選択比の視点からは、混合層の中に確実に物質Ａの含量が１００％である部分を有するセンサ（例えば実施例１０のセンサ）が望ましい。しかし、すでに述べたように、標的成分に比べて共存妨害成分の濃度が比較的低い試料を測定する場合など、選択比がある程度高くてもよいケースもあることから、実際の状況に応じて、適したタイプのセンサを選択すればよい。
【００９２】
（比較例５）フローインジェクション分析装置によるセラミック基体電極の評価
上記実施例で用いたセラミック電極基体と同ロットのものを、表面に混合層を付けずにフローセルに装着し、図２０に示すフローインジェクション分析装置で、実施例１５と同じ条件で過酸化水素（ＨＰＯ）およびＡＳＡ（濃度は共通して２ｍＭ）に対する応答のピーク電流を測定した。その結果を表３に示す。電極はアスコルビン酸と過酸化水素に対して、ほぼ同程度の感度を示した。
【００９３】
【表３】

【００９４】
（比較例６）フローインジェクション分析装置による混合層無しセンサの評価比較例４で製造したグルコースセンサをフローセルに装着し、図２０に示すフローインジェクション分析装置で、実施例１５と同じ条件でＡＳＡおよびグルコースの溶液（濃度は共通して５ｍＭ）に対する応答のピーク電流を測定した。その結果を表４に示す。センサは妨害成分のＡＳＡに対して、グルコースよりも２倍以上の応答を示した。
【００９５】
【表４】

【００９６】
上記の実施例と比較例から明らかなように、本発明により、高精度でかつ安定性が優れたバイオセンサを実現できた。
【図面の簡単な説明】
【図１】 本発明によるバイオセンサの基本構造を示す図
【図２】 キトサンの基本構造を示す図
【図３】 混合層中の物質Ａと高分子Ｂの混合態様の例を示す図
【図４】 混合層中の物質Ａと高分子Ｂの混合態様の例を示す図
【図５】 混合層中の物質Ａと高分子Ｂの混合態様の例を示す図
【図６】 混合層中の物質Ａと高分子Ｂの混合態様の例を示す図
【図７】 バイオセンサの構造の例を示す図
【図８】 バイオセンサの構造の例を示す図
【図９】 バイオセンサの構造の例を示す図
【図１０】 混合層中の表層部の例を示す模式図
【図１１】 混合層中の表層部の例を示す模式図
【図１２】 バイオセンサの構造の例を示す図
【図１３】 バイオセンサの構造の例を示す図
【図１４】 バイオセンサの構造の例を示す図
【図１５】 バイオセンサの構造の例を示す図
【図１６】 バイオセンサの構造の例を示す図
【図１７】 バイオセンサの構造の例を示す図
【図１８】 セラミック基板上に作成した３極系基体の例を示す図
【図１９】 混合層の物質Ａ：高分子Ｂの表面組成と付着力との関係を示す図
【図２０】 フローインジェクション分析装置を示す図
【図２１】 従来のバイオセンサの基本構造を示す図
【符号の説明】
１…酵素膜
２…選択透過膜
３…混合層
４…膜
６…基体
７…絶縁基板
８…作用電極[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a biosensor that detects and measures a specific component from a medium in which many components are mixed, and more particularly to an electric current detection type electrochemical biosensor.
[0002]
[Prior art]
Biosensors focus on the substrate specificity of biocatalysts such as enzymes, microorganisms, antibodies, and receptors, and there are a wide variety of components in combination with transducers, which are physical devices, using these biological sources as conversion elements. A specific component is detected and measured from the mixture. In particular, biosensors combining an oxidoreductase and an electrochemical measurement type transducer are particularly attracting attention because of their high sensitivity and ease of measurement. A typical example is a hydrogen peroxide detection biosensor in which a hydrogen peroxide-generating oxidoreductase and a hydrogen peroxide electrode are combined.
[0003]
In addition to hydrogen peroxide, a hydrogen peroxide electrode, which is a type of current measurement transducer, responds to a reducing substance such as uric acid or ascorbic acid (hereinafter referred to as an interfering component) to generate a current. Therefore, when measuring components in samples such as biological samples that contain many of these interfering components, it is an inevitable task to eliminate the influence of interfering components in order to ensure the measurement accuracy of the biosensor. . The most effective means for solving the above-mentioned problem is to provide a permselective membrane that eliminates coexisting substances on the electrode surface or in the vicinity thereof and allows hydrogen peroxide to permeate selectively or preferentially.
[0004]
FIG. 21 is a diagram showing the basic structure of this type of biosensor. In FIG. 21, 6 is a substrate having a hydrogen peroxide electrode, 2 is a permselective membrane, and 1 is an enzyme membrane on which a biocatalyst containing a hydrogen peroxide producing enzyme is immobilized. The principle will be briefly described below.
[0005]
When the medium to be measured is brought into contact with the surface of the sensor, the target component, for example, glucose diffuses into the enzyme film 1, and is oxidized by the enzyme contained therein, for example, glucose oxidase, to generate hydrogen peroxide. The generated hydrogen peroxide passes through the permselective membrane 2 and reaches the electrode surface of the substrate 6 where it is oxidized and converted into electronic information. Since electronic information (for example, current) and glucose oxidized by an enzyme have a linear correlation, the concentration of glucose can be measured from the output current. On the other hand, the coexistence disturbing component also diffuses to the enzyme membrane 1 like glucose, but is excluded by the permselective membrane 2 and cannot reach the electrode surface of the substrate 6. This ensures that the output current is derived from the target component and ensures measurement accuracy.
[0006]
Conventionally, various materials and manufacturing methods have been proposed as a hydrogen peroxide selective permeable membrane. For example, in the sensor used in the glucose analyzer of Yellow Spring Instruments Inc, a technique is adopted in which a cellulose acetate permselective membrane, an enzyme membrane, and a sandwich membrane made of polycarbonate are fixed to the surface of the platinum electrode with an O-ring or the like. (Special Publication, Royal Society of Chemistry, Vol. 167, p71-88, 1998). Japanese Patent Application Laid-Open No. 5-149911 discloses a permselective membrane manufactured by applying a protein on a water absorbent body such as cellulose filter paper.
[0007]
Japanese Patent Laid-Open No. 7-15936 discloses a sensor in which a permselective membrane made of a cellulose acetate membrane or an ion exchange resin membrane is directly formed on an electrode substrate. Japanese Patent Laid-Open No. 8-50112 discloses a glucose sensor in which a cellulose acetate film, a glucose oxidase-photocrosslinked polyvinyl alcohol mixture film, and a perfluorosulfonic acid ion exchange membrane are sequentially laminated on a working electrode.
[0008]
In addition, in order to ensure the adhesiveness of a film | membrane and sensor stability, these devices are devised to attach a protective film to the upper part. As another method for ensuring the adhesion of the membrane, in Japanese Patent Laid-Open No. 2000-2683, a permselective membrane is formed in a shape that covers only the surface of the working electrode, and the enzyme membrane thereon is interposed via a silane coupling agent. A method is disclosed in which a selective membrane is physically pressed by an enzyme membrane after bonding to the substrate surface. In JP-B-2-35933, an albumin crosslinked membrane is directly formed on the electrode surface as a hydrogen peroxide permselective membrane, and in JP-A-7-77509, a base polymer membrane is further applied under the albumin crosslinked membrane. A method is disclosed. The permselective membrane made of albumin has good adhesion with the enzyme membrane.
[0009]
[Problems to be solved by the invention]
In such a conventional technique, the following problems occur. When a cellulose acetate film or the like is prepared in advance and attached to the electrode surface, the film is thick in order to obtain a certain film strength, and adhesion with the electrode is poor. For this reason, dispersion | distribution of information generate | occur | produces, a response speed and detection sensitivity fall, and, as a result, measurement accuracy falls. In order to maintain detection sensitivity, an electrode having a large area is required. In addition, this method is difficult to automate manufacturing and is not suitable for mass production at low cost.
[0010]
On the other hand, when the cellulose acetate film or ion exchange resin film is directly formed on the electrode surface, it can be made thinner and the adhesion between the electrode can be improved compared to the case where the film is prepared in advance and mounted on the electrode surface. However, the poor adhesion between the permselective membrane and the enzyme membrane remains as a problem. The reason for this is that permselective membranes such as cellulose acetate are hydrophobic, and the adhesion to the substrate can be improved to some extent by, for example, hydrophobic treatment of the substrate surface, but enzyme membranes are generally hydrophilic. This is because it is difficult to obtain adhesion with a hydrophobic permselective membrane. For this reason, the enzyme film is thinly coated on the entire surface, and another film is further provided thereon to suppress the enzyme film and maintain the operational stability of the sensor. However, this type of sensor is particularly indispensable for the automation and speeding up of analysis. In the flow type measuring device, the membrane is peeled off by the shear force when the carrier liquid flows and the membrane is damaged by the pressure change caused by the pulsating flow. Has become a big problem.
[0011]
Further, in the sensor using an albumin cross-linked membrane as described in JP-B-2-35933 and JP-A-7-77509, the permselective membrane and the enzyme membrane are almost the same, so the adhesion between the membranes is quite strong. However, in order to achieve a certain selectivity, there is a problem that the permselective membrane needs to be thick, and since the membrane material is a hydrophilic protein, the stability during long-term use is lacking.
[0012]
In view of the present situation, an object of the present invention is to provide a biosensor having high adhesion, high accuracy and excellent stability between a selectively permeable membrane and an enzyme membrane, or between a selectively permeable membrane and an electrode. There is.
[0013]
[Means for solving the problems and their functions and effects]
In order to achieve the above object, claim 1 provides a biosensor comprising a substrate having a hydrogen peroxide electrode and an enzyme film on which a biocatalyst containing a hydrogen peroxide-producing enzyme is immobilized. And a substance selected from the group consisting of cellulose derivatives and ion exchange resins (referred to as substance A) and a functional group selected from the group consisting of aldehyde groups, amino groups, carboxyl groups, and epoxy groups. A mixed layer composed of a molecular substance (referred to as polymer B) was formed. Substance A in the mixed layer mainly eliminates coexistence hindering components and plays a role of selectively or preferentially permeating hydrogen peroxide. On the other hand, the polymer B in the mixed layer mainly serves to adhere the mixed layer to the enzyme film and / or the substrate. That is, the mixed layer is a hydrogen peroxide permselective membrane and at the same time functions to attach the enzyme membrane to the electrode substrate. As a result, the weakness of the film adhesion is eliminated, so that this biosensor is highly accurate and stable.
[0014]
The biosensor according to claim 1, wherein an exposure ratio of the polymer B in the mixed layer in a contact surface between the mixed layer and the enzyme film is 20% or more of a surface area. . Therefore, since the contact opportunity of the polymer B and the enzyme membrane is ensured, a necessary adhesion force can be obtained between the mixed layer and the enzyme membrane.
[0015]
According to a third aspect of the present invention, in the biosensor according to the first or second aspect, the content of the polymer B in the mixed layer is the highest in the outermost layer portion in contact with the enzyme film, and is away from the enzyme film. Therefore, the gradient composition is gradually reduced. Therefore, the adhesion between the mixed layer and the enzyme film can be efficiently secured with a small amount of polymer B.
[0016]
The biosensor according to claim 1 or 2, wherein the content of the polymer B in the mixed layer is the largest in the outermost layer portion in contact with the enzyme film and the substrate, and the enzyme film The gradient composition gradually decreases as the distance from the substrate increases. Therefore, the adhesive force between the mixed layer and the enzyme film and the adhesive force between the mixed layer and the substrate can be efficiently secured with a small amount of the polymer B.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0019]
FIG. 1 is a diagram showing a basic structure of a biosensor according to the present invention. In FIG. 1, 6 is a substrate having a hydrogen peroxide electrode, 3 is a mixed layer, and 1 is an enzyme membrane on which a biocatalyst containing a hydrogen peroxide-producing enzyme is immobilized. The mixed layer 3 is composed of a substance selected from the group consisting of cellulose derivatives and ion exchange resins (referred to as substance A), aldehyde group (—CHO), amino group (—NR 2, R: hydrogen or alkyl group), carboxyl group It consists of two components: (—COOH) and a polymer substance having a functional group selected from the group consisting of epoxy groups (referred to as polymer B).
[0020]
The substance A mainly removes coexistence interference components and plays a role of preferentially permeating hydrogen peroxide. Whether to select a cellulose derivative or an ion exchange resin may be determined in consideration of the purpose of use of the sensor, the substrate material, the structure thereof, and the like. These substances are effective as materials for hydrogen peroxide selective membranes, but generally have poor adhesion to enzyme membranes and substrates.
[0021]
Examples of the cellulose derivative include cellulose acetate having an acetyl substituent or a derivative thereof, cellulose acetate butyrate or cellulose butyrate having a butyl substituent, nitrocellulose having a nitro substituent, and ethyl cellulose. Among these, derivatives having an acetyl substituent represented by cellulose acetate are more preferable because they have many achievements as materials for various films. On the other hand, a preferred example of the ion exchange resin is Nafion (registered trademark) manufactured by DuPont, which is an ion exchange resin containing perflurosulfonic acid. This resin having a strong negative charge is particularly suitable for the removal of negative ionic interfering components. The substance A is generally poor in reactivity and has a hydrophobic tendency.
[0022]
The polymer B mainly plays a role of compensating for the insufficient adhesion of the substance A to the enzyme film or the substrate. The polymer B may be of any material or structure as long as it is a polymer substance having a functional group selected from the group consisting of the aldehyde group, amino group, carboxyl group, and epoxy group. Preferable examples include natural polymers such as polysaccharides and derivatives thereof, proteins, and synthetic polymers such as polyamino acids, polyamides, polyimides, polyacryls, and epoxy resins. These polymers are generally highly reactive and have a hydrophilic tendency. In particular, it shows high affinity with the enzyme membrane. For example, one type of polysaccharide derivative is chitosan, which is a polysaccharide derivative having an amino substituent.
[0023]
FIG. 2 is a diagram showing the basic structure of chitosan. In FIG. 2, R is 100% acetyl group (—COCH 3) is chitin, and chitosan is produced by deacetylation of chitin. Generally, 10 to several tens percent of acetyl groups remain. Chitosan is characterized by being rich in reactivity and being soluble in a mixed solvent composed of water and various organic solvents according to the degree of deacetylation.
[0024]
The mixed layer functions as a hydrogen peroxide permselective membrane and at the same time as an adhesive layer for attaching the enzyme membrane onto the substrate. Therefore, as long as the mixed layer fulfills the above two functions, the existence form of the substance A and the polymer B contained therein is not particularly limited. Preferable specific examples of the existence form include a mode in which both are present in a physically mixed state without being chemically bonded, or a partial bond by ionic bond, covalent bond, etc. at the interface where both molecules contact. And an embodiment that is present.
[0025]
3-6 is a figure which shows the example of the mixing aspect of the substance A and the polymer B in a mixed layer. In the figure, the substance A is represented by a white region or a gray curve, and the polymer B is represented by a black region or a black curve. As a preferable example of the mixing mode of the substance A and the polymer B in the mixed layer, as shown in FIG. 3, the mode in which the substance A and the polymer B are dispersed and mixed with each other, as shown in FIG. A mode in which the substance A and the polymer B are mixed at the level of the polymer molecule can be mentioned. Moreover, as another preferable example, as shown in FIG. 5, the structure in which the substance A and the polymer B form respective phases and phase-separate, or as shown in FIG. The aspect which has a comb-like interface structure is mentioned. In addition, these mixing aspects may exist simultaneously. For example, if FIG. 6 represents the part of the mixed layer 3 in FIG. 1, the CC cross section of FIG. 6 exhibits the structure of FIG. Furthermore, when the phase interface is magnified and observed, the structure shown in FIG. 4 or 5 is observed. By such various mixing modes, the substance A and the polymer B are strongly connected to form a continuous film.
[0026]
Since the polymer B plays a role of adhering the enzyme film and the mixed layer, the polymer B needs to be exposed on the surface of the mixed layer in contact with the enzyme film. The exposure ratio may be appropriately determined in consideration of various situations such as required film adhesion, materials of the substance A and the polymer B, and the surface structure, but is preferably 20% or more of the surface area. Thereby, since the contact opportunity of the polymer B and the enzyme membrane is ensured, a necessary adhesion force can be obtained between the mixed layer and the enzyme membrane.
[0027]
On the other hand, unlike the case of the interface with the enzyme film, at the interface with the substrate, there are many cases of obtaining a satisfactory adhesion force only with the substance A. In addition, when the sensor film (here, the sensor film refers to all films formed on the substrate) is integrated, it is sufficient that the sensor film is in close contact with the substrate and strongly adheres. There are cases where it is not necessary. In such a case, it is not necessary for the polymer B to be present in the surface layer portion facing the substrate side of the mixed layer, and it is desirable that the polymer B is not substantially contained. The reason is that polymer B, which functions as an adhesive, generally has poor hydrogen peroxide permselectivity, and therefore contributes little to the interfering substance removal function of the mixed layer, and conversely reduces the measurement sensitivity of the sensor due to diffusion resistance. This is because there is an effect. Here, “substantially” means that the presence of the polymer B cannot be detected by an existing analysis method.
[0028]
FIG. 7 is a diagram showing an example of the structure of a biosensor having the above mixed layer. As shown in FIG. 7, on the side of the mixed layer 3 in contact with the substrate 6, there is a region that does not substantially contain the polymer B (that is, a region that is substantially only the substance A). Is preventing the decline. In addition, the area | region of the lattice pattern shown by "A + B" in a figure means that the substance A and the polymer B are contained simultaneously, and does not show the ratio of both. The same applies to the following.
[0029]
Unlike the case of FIG. 7 described above, when sufficient adhesion to the substrate can be obtained with the substance A alone, but the adhesion is not sufficient, the polymer B only on the working electrode surface of the hydrogen peroxide electrode and its peripheral region. The polymer B can be included in other regions, and a method of ensuring the adhesion of the mixed layer to the substrate can be employed. A sensor having this aspect is particularly desirable in the case of a planar hydrogen peroxide electrode in which a film conductor is formed on an insulating substrate.
[0030]
FIG. 8 is a diagram illustrating an example of the structure of a biosensor having the mixed layer as described above. In FIG. 8, 7 is an insulating substrate, and 8 is a working electrode formed thereon. Although the counter electrode and the reference electrode are often formed together, only the portion including the working electrode 8 is shown in this figure. As shown in FIG. 8, the mixed layer 3 above and around the working electrode 8 has a region that does not substantially contain the polymer B, thereby preventing a decrease in measurement sensitivity as in the example of FIG. 7. It is out. At the same time, since the outer region having the polymer B has strong substrate adhesion, the film substrate adhesion of the entire mixed layer is maintained.
[0031]
FIG. 9 is a diagram illustrating an example of another biosensor structure. The difference from FIG. 7 is that there is a region “A + B1” in which the substance A and the polymer B are simultaneously contained on the side of the mixed layer 3 in contact with the substrate 6. Note that the region of the mixed layer 3 on the side in contact with the enzyme membrane 1 is indicated by “A + B2”, and there is a region “A” in which the polymer B is not substantially contained. For example, in a case where the substance A alone has insufficient substrate adhesive force, by adopting this mode, adhesion to the substrate 6 is realized by the polymer B1, and a sensor with strong substrate adhesion can be obtained. Here, the ratio of the polymer B1 exposed to the substrate 6 is preferably 10% or more of the surface area. The reason why the polymer B is distinguished from B1 and B2 is that they are not necessarily the same component. In general, since the substrate 6 and the enzyme film 1 are made of different materials, there are cases where it is better to use different polymers in order to achieve optimum adhesion.
[0032]
The thickness of this region (“A”) in a sensor having a region in which the polymer B is substantially not included in the mixed layer 3 as shown in FIGS. 7 to 9 is the required sensor performance. In addition, the material of the film to be used and the manufacturing method thereof, and the composition and thickness of the mixed portion of the substance A and the polymer B in the upper and lower portions in the thickness direction of the portion are appropriately determined in consideration of various situations. . If the concentration of the coexisting interference component in the sample to be tested is high and a high interference component removal rate is required to ensure measurement accuracy, the thickness is increased. On the contrary, when the influence on the accuracy of the measurement sensitivity becomes stronger than the influence of the disturbing component, the portion is appropriately thinned in view of the balance between the disturbing substance removal rate and the sensitivity.
[0033]
In the case where the film containing the mixed layer is formed directly on the substrate in situ and the majority of the interfering component elimination function depends on the region substantially free of the polymer B, the generally preferred “A” The lower limit of the thickness range is 100 nm, and the upper limit is 2000 nm. When the thickness is 100 nm or less, the removal rate of interfering substances decreases due to a decrease in diffusion restriction or pinholes in most materials, and it becomes difficult to apply to samples having a high concentration of interfering components such as urine. In addition, at 2000 nm or more, a strong exclusion action is produced against hydrogen peroxide, leading to a decrease in measurement accuracy. Of course, this is not the case when a considerable disturbing component function is achieved even in the mixing portion above and below the portion “A”.
[0034]
As already described, the polymer B that functions as an adhesive generally has poor hydrogen peroxide selective permeability. Therefore, in order to function efficiently as a hydrogen peroxide selective permeable membrane, it is preferable to achieve the required film adhesion and to keep the ratio of the polymer B in the mixed layer as small as possible. From this viewpoint, it is desirable that the polymer B in the mixed layer is concentrated in the surface layer portion. As such a preferred embodiment, there is an embodiment having a gradient composition in which the content of the polymer B in the mixed layer is the largest on the outermost side (side in contact with the enzyme membrane and / or the substrate) and gradually decreases toward the inside. Can be mentioned.
[0035]
10 and 11 are schematic views showing examples of the surface layer portion in the mixed layer having the structure as described above. In the figure, the black part means the polymer B, and the other part means the substance A. As can be seen from FIGS. 10 and 11, since the polymer B is present most in the outermost layer portion, the amount of the polymer B used for obtaining the necessary adhesive force can be reduced, and the substance is contained inside. Since the A content is large, the ability to remove interfering components is high. Further, since the composition change gradually occurs from the surface layer portion to the inside, the sense of unity between the substance A and the polymer B is maintained, and the strength of the entire mixed layer is efficiently maintained. In addition, as shown in FIG. 11, the substance A may be substantially not included in the outermost layer portion. Such a graded composition may be present on one side or both sides of the mixed layer. In particular, when sufficient adhesion or adhesive force is selected with the substance A alone with the substrate, the gradient composition may be formed only on the side in contact with the enzyme film.
[0036]
12-15 is a figure which shows the example of the structure of the biosensor which has the above mixed layers. The mixed layer 3 in FIG. 12 has a unidirectional gradient composition in which the content of the polymer B is the highest on the side in contact with the enzyme film 1 and gradually decreases toward the substrate 6 side. The mixed layer 3 in FIG. 13 has a unidirectional gradient composition similar to that in FIG. 12, but there is a region in which the polymer B is not substantially included on the base 6 side. The mixed layer 3 in FIG. 14 has a bi-directionally gradient composition in which the content of the polymer B is the largest on both the enzyme membrane 1 side and the substrate 6 side, and gradually decreases toward the inside of the layer. In this case, the position where the content of the polymer B is the smallest need not necessarily be at the center point in the film thickness direction. Of course, the content of the polymer B in the outermost layer portion may be different between the substrate 6 side and the enzyme membrane 1 side, and different components may be adopted on both sides. Furthermore, as shown in FIG. 15, there may be a region where the polymer B is not substantially contained in the mixed layer 3. The structure of the mixed layer and the mixing mode of the substance A and the polymer B described above can be achieved by physical observation means such as an electron microscope, and analysis means such as X-ray photoelectron spectroscopy and secondary ion mass spectrometry. Can be confirmed.
[0037]
The biosensor mixed layer according to the present invention has been described above. Next, the entire structure of the biosensor will be described. If the mixed layer 3 is located between the substrate 6 including the hydrogen peroxide electrode and the enzyme membrane 1 on which the biocatalyst including the hydrogen peroxide-producing enzyme is immobilized (see FIG. 1), the structure is satisfied. Is not limited. In addition to the basic structure shown in FIG. 1, a structure (FIG. 16) in which a film 4 is further formed on the enzyme film 1 can be considered as an example.
[0038]
The role of the film 4 formed on the enzyme film 1 is to protect the enzyme film 1 from an external sample, or to limit the arrival of the component to be measured to the enzyme film 1 and to measure a higher concentration sample. To respond. As an example of the former, a sensor that analyzes components in blood can be considered. Since blood contains many macromolecules such as proteins that degrade the sensor due to adhesion to the surface of the enzyme membrane, the measurement accuracy of the sensor can be prevented by providing a protective membrane to prevent these components from reaching the enzyme membrane. And stability can be improved. As an example of the latter, there is a sensor that can handle a wide range of concentration measurements without diluting the test sample or by diluting it several times during online measurement of urine components or manufacturing processes in the industrial field. Can be mentioned.
[0039]
Moreover, the enzyme film 1 may have a structure composed of a plurality of layers instead of a single layer. FIG. 17 shows an example in which the enzyme membrane 1 has two layers. As a preferable example of a sensor provided with a plurality of layers of enzyme membrane 1, in the case of a sensor having a reaction system that converts a component to be measured into hydrogen peroxide by a multi-stage enzyme reaction using a plurality of enzymes, There are cases where the layers can be converted more efficiently. Another example is a multifunctional biosensor that detects a plurality of components simultaneously using a plurality of enzymes.
[0040]
The biosensor according to the present invention is mainly used for analysis of components that can be substrates for hydrogen peroxide-producing enzymes, such as glucose, lactic acid, amino acids, and alcohols. More specifically, for analysis of components that can be substrates for hydrogen peroxide-producing enzymes in media that may contain coexisting interfering substances that oxidize on the electrode surface in the same manner as hydrogen peroxide and give a current signal. Used. Examples of these media include biological fluids such as urine, blood and saliva, fruit juice and drinking water in the industrial field, and intermediate media in production processes. Examples of coexistence hindering substances contained in these media include ascorbic acid, uric acid, acetaminophen, etc., but the biosensor according to the present invention measures the target component with negligible influence of these components. can do.
[0041]
Next, the manufacturing method of the biosensor according to the present invention will be described. The biosensor according to the present invention can be manufactured in various ways depending on the substrate including the electrode to be used, the material of the selected film, the sensor film structure, and the like. The method can be roughly divided into a method and a method of directly forming a film on a substrate surface from a film material. Here, the latter method of directly forming a film on the surface of the substrate will be described in detail.
[0042]
First, a substrate including a hydrogen peroxide electrode is prepared. The shape of the substrate is not limited, but a hydrogen peroxide electrode system including a working electrode is preferably formed on a flat insulating substrate. As the insulating substrate, a glass plate, a silicon wafer, a ceramic plate, or the like can be considered. The electrode system on the insulating substrate only needs to include a working electrode. From the viewpoint of manufacturing cost of the sensor and simplification of the measurement system using the sensor, the working electrode and the counter electrode (bipolar system), or the working electrode and the counter electrode It is also preferable that the reference electrode (tripolar system) is patterned and formed on the substrate. FIG. 18 shows an example of a tripolar base material produced by a screen printing technique on a ceramic substrate.
[0043]
Next, the process proceeds to film formation on the substrate, and the substrate is pretreated as necessary. The main purpose of the pretreatment is to clean and activate the substrate surface. As a cleaning method, cleaning with water or acid can be considered. In particular, cleaning with an acid is preferable because surface activation can be expected simultaneously with removal of dirt. Preferable examples of the acid species include strong acids such as nitric acid, sulfuric acid and hydrochloric acid, and weak acids such as phosphoric acid, formic acid, coenoic acid and acetic acid. In addition, it is necessary to wash | clean the base | substrate after wash | cleaning with an acid with water. The substrate that has been cleaned is dried as necessary. The drying conditions are not particularly limited, but generally preferable temperatures include 20 to 80 ° C., drying times of 5 to 120 minutes, and the like. In the case where the next process is a process using an aqueous solution, drying can be omitted.
[0044]
Next, surface treatment of the substrate is performed as necessary. The main purpose of the surface treatment is surface activation (introduction of a reactive functional group) for improving the adhesion of the mixed layer to the substrate or / and improvement of the affinity between the substrate and the mixed layer. As a treatment method, various commonly used methods such as silanization treatment, plasma treatment, electrochemical treatment, or application of a coating material can be used. A preferred example is silanization treatment. The silanizing agent may be appropriately selected in consideration of the situation such as the material of the substrate and the permselective membrane and the type of functional group, but generally preferred examples include amino groups, carboxyl groups, epoxy groups, alkene groups, Those containing a functional group such as a halogen group and a vinyl group are desirable, and the most desirable is a silanizing agent containing an amino group and an epoxy group.
[0045]
Specific examples include allyltrichlorosilane, allyltriethoxysilane, allyltrimethylsilane, 3- (2-aminoethylaminopropyl) trimethoxysilane, 3-aminopropyltrimethoxysilane, 3-aminopropyltriethoxysilane. Chloromethyldimethylchlorosilane, chloromethyltrimethylsilane, 3-chloropropyltrimethoxysilane, dimethoxymethylchlorosilane, dimethylaminotrimethylsilane, methylchlorosilane, ethoxydimethylvinylsilane, ethyldichlorosilane, 3-glycidoxypropyltrimethoxysilane, 3 -Glycidoxypropylmethyldimethoxysilane, hydroxymethyltrimethylsilane, 3-methacryloxypropyltrimethoxysilane, 3-methacryloxypropi Methyl dimethoxy silane, methyl vinyl dichlorosilane, trichlorovinylsilane, triethoxy vinyl silane, trimethoxy vinyl silane, and material selected from the group consisting of trimethyl vinyl silane. Of these, 3-aminopropyltriethoxysilane and 3-glycidoxypropyltrimethoxysilane are most preferable as inexpensive silanizing agents for efficiently introducing amino groups or epoxy groups onto the substrate surface.
[0046]
As a method and procedure of silanization treatment, first, a silanizing agent is diluted with a solvent to a certain concentration to prepare a silanization solution. Next, the substrate surface is brought into contact with the silanization solution for a certain period of time and then dried with or without washing. As another method, a method of applying a silanized solution to the surface of the substrate and drying it with a film forming apparatus such as a spin coater can be used. In addition, in the method of drying without applying cleaning after contact with the silanization solution or coating with a film forming apparatus, a thin film of silanizing agent is formed on the surface of the substrate.
[0047]
Subsequently, the mixed layer is formed. The formation method of the mixed layer may be appropriately selected by selecting from well-known film formation methods in consideration of the conditions such as the selected material and the planned structure.
[0048]
The first preferred method for producing the mixed layer is as follows. First, a single film of substance A (or polymer B) is formed on a substrate, and then polymer B containing a solvent capable of at least partially dissolving or swelling substance A (or polymer B). A stock solution of (or substance A) is applied thereon and held for a certain period of time before the solvent is evaporated and dried. For example, in the case of the mixed layer shown in FIGS. 7, 12, and 13 having a structure in which the polymer B is concentrated on the side in contact with the enzyme membrane, the mixed layer is manufactured as follows. First, a film of substance A is formed on the substrate, and then a stock solution of polymer B containing a solvent (referred to as solvent α) that can at least partially dissolve or swell substance A is applied thereon. Further, after holding for a certain period of time, the solvent is volatilized and dried.
[0049]
The principle is as follows. The solvent α contained in the stock solution of the polymer B at least partially dissolves or swells the substance A under the stock solution and changes at least the outermost layer portion of the substance A into a highly fluid state. Thereby, the fluid substance A and the polymer B are diffused and mixed with each other. Thereafter, since the solvent is removed, the mixture is dried in a mixed state to form a mixed layer. The thickness, structure, and degree of mixing of the mixing part of the mixing layer are the properties (particularly boiling point, solubility in substance A) and amount of solvent α contained in the polymer B stock solution, the concentration of polymer B, substance A and It is controlled by the contact time of the polymer B with the undiluted solution, environmental factors (particularly air temperature and humidity), and the subsequent processing method.
[0050]
The subsequent treatment method refers to either a method in which the applied undiluted solution is dried as it is after contacting for a certain time, or a method in which it is partially removed and dried. As a method of drying the applied stock solution as it is, a method of dropping the stock solution of polymer B and then drying it for a certain time (drop method), or a substrate on which the film of substance A is formed on the base solution of polymer B For example, there is a method of dipping inside and pulling it up after a certain period of time and drying it as it is. On the other hand, as a method for partially removing the applied stock solution, there is a method of forming a film by spin coating rotation. That is, after the stock solution is applied and spread over the entire film surface of the substrate material A by preliminary rotation or the like, the stock solution is retained for a certain period of time and then the excess stock solution is removed by high speed rotation. Among the methods described above, the pulling method and the spin coating method are suitable for forming a thin film, and the drop method is suitable for forming a thick film from a small amount of material. These film forming methods will be described later.
[0051]
Further, in the case of the mixed layer having a structure in which the polymer B is concentrated on both the side in contact with the enzyme membrane and the side in contact with the substrate, as shown in FIGS. To be manufactured. First, a film of the substance B1 is formed on the substrate, and then a stock solution of the substance A containing a solvent capable of at least partially dissolving or swelling the polymer B1 is applied thereon and held for a certain period of time. Then, the solvent is volatilized and dried to form a substrate-side mixed portion of the mixed layer. Subsequently, the polymer B2 stock solution is similarly applied to form a mixed portion on the side of the mixed layer in contact with the enzyme membrane. The polymers B1 and B2 may be the same material.
[0052]
A second preferred method for producing the mixed layer is to sequentially form a substance A film → polymer B film (or polymer B1 film → substance A film → polymer B2) on a substrate. Therefore, a method of forming a mixed layer by applying appropriate means can be mentioned. This method is particularly effective when it is difficult to produce by the first method or the formation of the mixed structure is insufficient. Examples of means for mixing the laminated substance A and polymer B include heat treatment, pressure treatment, and treatment with a solvent capable of partially dissolving both.
[0053]
The heat treatment is applied when the fluidity of one or both of the substance A and the polymer B is increased by heating, and the chemical properties of the material itself are stable at a predetermined temperature. In this case, both substances having increased fluidity at high temperatures diffuse into each other and form a mixed layer. In this case, temperature and heating time are effective means for controlling the structure of the mixed layer. If the stability as the material of the substance A and the polymer B is maintained, the heating temperature is not particularly limited, but a generally desirable temperature range is 50 ° C to 200 ° C. On the other hand, the pressure treatment is hardly restricted by the stability problem derived from the material, but since the film thickness and the film density are greatly changed by the pressure, specific conditions are required for the properties of the material. It is necessary to determine appropriately according to the situation such as sensor specifications. Further, the formation of the mixed layer by the method of treating with a solvent is similar in principle to the first production method. That is, the fluidity of the material is increased and mixed by dissolution or swelling with a solvent. In addition, heating, pressurization, and use of a solvent may be performed independently or in combination.
[0054]
As a third preferred method for producing the mixed layer, there is a method in which both are prepared as a mixed material in advance at a certain ratio and then the mixed layer is formed. In this case, the composition of the mixed layer is controlled by adjusting the composition ratio in the mixed material. Usually, the substance A and the polymer B in the mixed layer are mixed throughout the layer by forming the film once, but the mixed layer is formed by laminating mixed materials having different mixing ratios in multiple stages. Can be controlled. For example, in order to manufacture a mixed layer having the structure shown in FIG. 7, a film of only substance A is first formed on a substrate, and then a mixed portion is formed using a mixed material of substance A and polymer B.
[0055]
The method for mixing the substance A and the polymer B in the mixed layer has been described above. Since any method needs to form a film from a bulk material, a specific film forming method will be described next. .
[0056]
As a preferred example of a specific film formation method, a method in which a material is adjusted to a stock solution with a constant concentration with a solvent is spread on the surface of the substrate, and then the solvent is evaporated. A film forming method. In the present invention in which the main material of the mixed layer is an organic substance, the former method of producing a film after adjusting to a stock solution having a constant concentration is more preferable. The solvent used for adjusting the stock solution may be appropriately determined in consideration of various situations such as a mixed layer material and a specific method for forming the mixed layer.
[0057]
Preferable examples of the solvent applied to the material containing a cellulose derivative containing an acetyl group include acetone, methyl acetate, ethyl acetate, methyl ethyl ketone, methyl cellosolve, methyl cellosolve acetate, ethyl lactate, 4-hydroxy-4-methyl-2-pentanone (Diacetone alcohol), ethylene chloride, methanol, ethanol, formaldehyde, and water. Moreover, methanol, ethanol, 1-propanol, 2-propanol, formaldehyde, water, etc. are mentioned as a solvent applied to the ion exchange resin which has perfluorosulfonic acid. These solvents can be used alone or in admixture of plural kinds.
[0058]
The solvent applied to the polymer B is mainly selected in consideration of the solubility in both the polymer B and the substance A, the production method of the portion having both the polymer B and the substance A in the mixed layer, and the like. The As will be described later, the selection of the solvent is not only related to the formation method of the mixed layer, but also has a strong influence on the performance and adhesion performance of the mixed layer as a hydrogen peroxide selective film.
[0059]
In addition, when a mixed layer is prepared by adjusting a mixture of substance A and polymer B, it is desirable to design a solvent system that is soluble in both materials, but one is dissolved and the other is dissolved. May be in the form of dispersed particles, or in the form of an emulsion in which both are dissolved in separate solvents that do not co-dissolve.
[0060]
The concentration of the stock solution may be determined in consideration of various situations such as film material, solution viscosity, target film thickness, coating method, and the like, and is not particularly limited. If they are the same, the film thickness has a positive correlation with the stock solution concentration, so the stock solution concentration may be considered as an important factor for adjusting the film thickness. As an example, when the film is formed directly on the surface of the substrate including the electrode by the spin rotation coating method, the concentration of the stock solution is desirably in the range of 2 to 10 (w / v)%. In this example, the film thickness is positively correlated with both concentration and viscosity. As the concentration increases, the solution viscosity also increases abruptly, so that the film thickness can be largely adjusted with a small change in concentration.
[0061]
Preferable examples of the method of developing the film stock solution in a layered manner on the surface of the substrate include dropping coating, casting coating, spin coating with a film forming apparatus such as a spin coater while the substrate is stationary, and contacting the substrate with the stock solution. The method of pulling up is mentioned. In the case where the substrate surface including the electrode is a flat substrate, the spin rotation method can control the film thickness with high accuracy and is suitable for producing a homogeneous film. Another more preferable method is dipping coating with a lifting device that can control the speed to a constant level. Dipping coating by a lifting device can form a fairly uniform film even when the substrate surface is not flat.
[0062]
When the volatility of the solvent used to adjust the stock solution of substance A or polymer B is high, the film will be completed at the same time as the completion of the coating operation, but if the solvent contains a low volatility, After film coating is completed, the process proceeds to the drying process. Basically, drying may be performed at room temperature without particularly controlling the atmosphere, but in some cases, measures such as heating or decompression may be taken. Generally reasonable drying times include a range of minutes to hours.
[0063]
When the production of the mixed layer is completed, the process moves to the production of the enzyme membrane. As the enzyme film, a method of forming a film in advance and then attaching it to the surface of the mixed layer, and a method of directly forming a film on the spot can be considered, but a method of directly forming the film on the spot is preferable. As a specific manufacturing method, a method substantially similar to the above-described mixed layer forming method can be applied.
[0064]
As described above, the sensor manufacturing method in which the mixed layer and the enzyme film are sequentially formed on the substrate surface has been described. Needless to say, however, if the film 4 is further required, it may be manufactured in a subsequent process. It will be described again that some or all of the substrate cleaning and surface treatment prior to the production of the mixed layer can be omitted.
[0065]
As described above, according to the present invention, the substance A in the mixed layer preferentially permeates hydrogen peroxide, and the polymer B in the mixed layer adheres the mixed layer to the enzyme film or the substrate. A highly accurate and highly stable biosensor can be realized. Further, when the film is formed directly on the surface of the substrate from the film material, the manufacturing cost can be reduced.
[0066]
【Example】
The present invention will be described in more detail with reference to the following examples, but the present invention is not limited to these examples.
[0067]
(Example 1) Cleaning of substrate surface with nitric acid
50 ml of 1N nitric acid was added to the glass container, and then the ceramic electrode substrate (see FIG. 18) was completely immersed in the liquid, and was gently shaken several times by hand and left at room temperature for 30 minutes. Subsequently, the substrate was taken out and washed with a large amount of deionized water.
[0068]
(Example 2) Silanization treatment of substrate surface with 3-aminopropyltriethoxysilane
In a separate glass container, 49.5 ml of deionized water and 0.5 ml of 3-aminopropyltriethoxysilane were added and mixed to prepare a 1% aminosilane solution. Subsequently, the ceramic electrode substrate treated with nitric acid in Example 1 was soaked in the solution, gently shaken several times by hand, and allowed to stand at room temperature for 30 minutes. Subsequently, the substrate was taken out and washed with a large amount of deionized water.
[0069]
(Example 3) Silanization treatment of substrate surface with 3-glycidoxypropyltrimethoxysilane
In a separate glass container, 49.5 ml of isopropyl alcohol and 0.5 ml of 3-glycidoxypropyltrimethoxysilane (epoxysilane) were added and mixed to prepare a 1% epoxysilane solution. Subsequently, the container was covered and placed in an incubator at 75 ° C. together with the ceramic electrode substrate. After holding for 20 minutes, the ceramic electrode substrate was placed in an epoxy silane solution and stirred with vibration for 5 minutes. Next, the electrode substrate was taken out of the glass container and left to dry in the same temperature atmosphere for 30 minutes. Finally, the electrode substrate was taken out, washed with isopropyl alcohol, and dried at room temperature.
[0070]
(Example 4) Preparation of enzyme membrane stock solution
Glucose oxidase (EC 1.1.3.4, Sigma-Aldrich) 2290 units was dissolved in 0.7 ml sodium phosphate buffer solution (100 mM, pH 6.0) to obtain an enzyme solution. Further, 25 mg of bovine serum albumin (BSA) was weighed and dissolved in 1.0 ml of deionized water to prepare a BSA solution. Subsequently, 0.2 ml of the prepared BSA solution was taken, added to the enzyme solution, and mixed uniformly. 0.1 ml of a 2.0% (v / v)% glutaraldehyde aqueous solution was added to the mixed solution after stirring and stirred. In this way, an enzyme membrane stock solution was prepared.
[0071]
(Example 5) Trial production of mixed layers having different compositions
First, a 5 (w / v)% cellulose acetate solution (solution A) having a substitution degree of 2.4 was prepared with a solvent of chloroform 90 to ethanol 10 (volume ratio, hereinafter the same). Similarly, a 5% aldehyde-modified cellulose solution (solution B) having a degree of acetyl substitution of 1.0 and an aldehyde group content of about 4 mmol / g was prepared with a mixed solvent of water 50 and ethanol 50. Next, the electrode substrate that has been aminosilanized by the method of Example 2 is set on a spin coater, and both the above solutions are mixed at a ratio of Solution A: Solution B = 19: 1 and stirred vigorously, and then set. The mixture was quickly dropped on the substrate and a mixed layer was formed by spin coating. Similarly, a mixed layer having a mixing ratio of the solution A and the solution B of 9: 1, 5: 1, 4: 1, 3: 1, 2: 1, and 1: 1 was prepared. For comparison, a film of only solution A was also prepared. When the prepared mixed layer was observed with an electron microscope, it showed a phase separation structure with a size of several tens of nanometers. The mixing ratio was almost the same.
[0072]
(Example 6) Trial manufacture of glucose sensor-Part 1
The electrode substrate treated with epoxy silanization in Example 3 was set on a spin coater, and a cellulose acetate film was prepared using an 8 (w / v)% cellulose acetate solution (solvent acetone) having a substitution degree of 2.4 adjusted in advance as a stock solution. It was created. Subsequently, a 3% chitosan (including 0.75% acetic acid) solution prepared with a mixed solvent of water 60 and acetone 40 was dropped so as to cover the working electrode, and held for 1 minute, and then the chitosan film was formed by spin coating. Formed. Thereafter, 10 μl of the enzyme membrane stock solution prepared in Example 4 was dropped onto the working electrode with a pipette and dried in an atmosphere at 35 ° C. for 30 minutes to prepare an enzyme membrane. The sensor produced in this way has a structure in which the polymer B is concentrated on the side in contact with the enzyme membrane as shown in FIG. 7, FIG. 12, and FIG.
[0073]
(Example 7) Trial manufacture of glucose sensor-Part 2
The electrode substrate treated with epoxy silanization in Example 3 was set on a spin coater, and a cellulose acetate film was prepared using an 8 (w / v)% cellulose acetate solution (solvent acetone) having a substitution degree of 2.4 adjusted in advance as a stock solution. It was created. Subsequently, a 3% chitosan (containing 0.75% acetic acid) aqueous solution was dropped so as to cover the working electrode, and a chitosan film was formed by spin coating. Thereafter, the substrate was placed in a solvent of acetone 60: water 40 and held for 3 minutes, then taken out and dried. Finally, 10 μl of the enzyme membrane stock solution prepared in Example 4 was dropped onto the working electrode with a pipette and dried in an atmosphere at 35 ° C. for 30 minutes to prepare an enzyme membrane. The sensor produced in this way has a structure in which the polymer B is concentrated on the side in contact with the enzyme membrane as shown in FIG. 7, FIG. 12, and FIG.
[0074]
(Example 8) Trial manufacture of glucose sensor-Part 3
Pipette 10 μl of 3 (w / v)% perfluorosulfonic acid ion exchange resin (Nafion) solution (solvent isopropyl alcohol 85 to water 15) on the working electrode of the electrode substrate treated with aminosilanization in Example 2. The Nafion film was prepared by dripping. Subsequently, a polyethyleneimine film was formed by spin coating using a 4% polyethyleneimine aqueous solution. Next, a tray containing a mixture of isopropyl alcohol 60 and water 40 is prepared, and the substrate is set so that the surface with the film faces downward on the tray about 10 cm away from the liquid surface. The container was sealed in a container controlled to an atmosphere of 0 ° C. and held for 30 minutes. Thereafter, the substrate was taken out and dried. Finally, 10 μl of the enzyme membrane stock solution prepared in Example 4 was dropped onto the working electrode with a pipette and dried in an atmosphere at 35 ° C. for 30 minutes to prepare an enzyme membrane. The sensor thus prepared has a structure in which the polymer B is concentrated on the side in contact with the enzyme membrane as shown in FIGS.
[0075]
(Example 9) Trial manufacture of glucose sensor-Part 4
In the same manner as in Example 5, a mixed layer having a mixing ratio of 9: 1, 5: 1, 4: 1, 3: 1, 2: 1 of solution A and solution B was formed on the electrode substrate, and then Then, 10 μl of the enzyme membrane stock solution prepared in Example 4 was dropped on the pipette working electrode and dried in an atmosphere at 35 ° C. for 30 minutes to prepare an enzyme membrane. The sensor thus produced has a mixed layer with a substantially uniform composition throughout.
[0076]
(Example 10) Trial manufacture of glucose sensor-Part 5
First, a 2 (w / v)% cellulose acetate solution (solution A) having a substitution degree of 2.4 was prepared with a solvent of chloroform 90 and ethanol 10. Similarly, a 2% aldehyde cellulose solution (solution B) having a acetyl substitution degree of 1.0 and an aldehyde group content of about 4 mmol / g was prepared with a mixed solvent of water 50 and ethanol 50. Further, a 5 (w / v)% cellulose acetate solution having a substitution degree of 2.4 was prepared with acetone. Next, the electrode substrate treated with aminosilanization in Example 2 was set on a spin coater, the solution A and the solution B were mixed at a mixing ratio of 5: 1 and vigorously stirred, and then the set substrate was mixed. A spin coat film was formed by dripping quickly onto the film. Subsequently, spin coating was performed using a 5 (w / v)% cellulose acetate solution prepared with acetone. Finally, a stock solution having a mixing ratio of solution A and solution B of 4: 1 was prepared, and a film was formed by spin coating. Thereafter, 10 μl of the enzyme membrane stock solution prepared in Example 4 was dropped with a pipette and dried in an atmosphere at 35 ° C. for 30 minutes to prepare an enzyme membrane. The sensor thus produced has a mixed layer as shown in FIG.
[0077]
(Example 11) Trial manufacture of glucose sensor-Part 6
The electrode substrate treated with aminosilanization in Example 2 was set on a spin coater, an aqueous solution of 3% chitosan (including 0.75% acetic acid), and 8 (w / v)% cellulose acetate having a substitution degree of 2.4. A three-layer laminated film of chitosan / cellulose acetate / chitosan was prepared using the solution (solvent acetone) as a stock solution. Subsequently, the substrate was placed in a mixed solvent of acetone 60: water 40 and held for 3 minutes, then taken out and dried. Finally, 10 μl of the enzyme membrane stock solution prepared in Example 4 was dropped onto the working electrode with a pipette and dried in an atmosphere at 35 ° C. for 30 minutes to prepare an enzyme membrane. In this way, a sensor having a mixed layer with a large content of substance B in the surface layer portion and a large content of substance A inside was manufactured.
[0078]
(Example 12) Trial manufacture of glucose sensor-Part 7
The electrode substrate treated with aminosilanization in Example 2 was set on a spin coater, an aqueous solution of 3% chitosan (including 0.75% acetic acid), and 8 (w / v)% cellulose acetate having a substitution degree of 2.4. A three-layer laminated film of chitosan / cellulose acetate / chitosan was prepared using the solution (solvent acetone) as a stock solution. Subsequently, the substrate was placed in a mixed solvent of acetone 60: water 40 and held for 3 minutes, and then taken out. Next, the substrate was placed in a 0.75% aqueous acetic acid solution and cultured with shaking for 30 minutes. Thereafter, the substrate was taken out and dried. Finally, 10 μl of the enzyme membrane stock solution prepared in Example 4 was dropped onto the working electrode with a pipette and dried in an atmosphere at 35 ° C. for 30 minutes to prepare an enzyme membrane. The mixed layer of the sensor prepared in this example has a structure in which the substance A is partially exposed on the surface in contact with the enzyme film.
[0079]
Comparative Example 1 Trial Production of Glucose Sensor <Comparison with Example 6>
The electrode substrate treated with epoxy silanization in Example 3 was set on a spin coater, and a cellulose acetate film was prepared using an 8 (w / v)% cellulose acetate solution (solvent acetone) having a substitution degree of 2.4 adjusted in advance as a stock solution. It was created. Thereafter, 10 μl of the enzyme membrane stock solution prepared in Example 4 was dropped onto the working electrode with a pipette and dried in an atmosphere at 35 ° C. for 30 minutes to prepare an enzyme membrane.
[0080]
Comparative Example 2 Trial Production of Glucose Sensor <Comparison with Example 8>
Pipette 10 μl of 3 (w / v)% perfluorosulfonic acid ion exchange resin (Nafion) solution (solvent isopropyl alcohol 85 to water 15) on the working electrode of the electrode substrate treated with aminosilanization in Example 2. The Nafion film was prepared by dripping. Subsequently, a polyethyleneimine film was formed by spin coating using a 4% polyethyleneimine aqueous solution. Finally, 10 μl of the enzyme membrane stock solution prepared in Example 4 was dropped onto the working electrode with a pipette and dried in an atmosphere at 35 ° C. for 30 minutes to prepare an enzyme membrane.
[0081]
Comparative Example 3 Trial Production of Glucose Sensor <Comparison with Example 11>
The electrode substrate treated with aminosilanization in Example 2 was set on a spin coater, an aqueous solution of 3% chitosan (including 0.75% acetic acid), and 8 (w / v)% cellulose acetate having a substitution degree of 2.4. A three-layer laminated film of chitosan / cellulose acetate / chitosan was prepared using the solution (solvent acetone) as a stock solution. Finally, 10 μl of the enzyme membrane stock solution prepared in Example 4 was dropped onto the working electrode with a pipette and dried in an atmosphere at 35 ° C. for 30 minutes to prepare an enzyme membrane.
[0082]
(Comparative Example 4) Direct deposition of enzyme membrane on electrode substrate
After treating the ceramic electrode substrate according to Example 1 and Example 2, an enzyme membrane was prepared on the working electrode with the enzyme membrane stock solution prepared by the method of Example 4.
[0083]
(Example 13) Evaluation of adhesion of mixed layer
For the mixed layer prepared in Example 5 and remaining attached to the substrate, the substrate adhesion of the film was evaluated by the cellophane taping method. Apply ordinary commercial cellophane tape to cover the membrane and surrounding area, press with your finger to apply pressure to the tape surface, check the adhesion, peel off the tape, and visually check the peeling status of the membrane. confirmed. These operations were repeated until the film was completely peeled off or up to 20 times. Then, 2 points were obtained for the film that remained intact after one taping, 1 point for partial peeling, and 0 point for complete peeling, and the total score was quantified as adhesion. The result is shown in FIG.
[0084]
As already described in Example 5, since the composition of the surface layer and the inside of the mixed layer is almost uniform, the mixing ratio of the solution and the surface composition of the substance A: polymer B of the mixed layer are almost the same. As shown in FIG. 19, the substrate adhesion force of the mixed layer containing the aldehyde cellulose solution (polymer B) is much higher than the substrate adhesion force of the film of the cellulose acetate solution (substance A) alone. In addition, there is a substantially positive correlation between the content of aldehyded cellulose (polymer B) in the mixed layer and the adhesive force. However, if the content of the polymer B increases as the surface composition of the substance A: the polymer B exceeds 9: 1 (that is, if the surface exposed area ratio of the polymer B exceeds 10%), this tendency is not significant. .
[0085]
(Example 14) Observation of sensor film
About the sensor created in Examples 6-12 and Comparative Examples 1-3, the presence or absence of film | membrane peeling was observed after drying. The non-peeled sensor was placed in a buffer solution containing 33 mM potassium dihydrogen phosphate and sodium monohydrogen phosphate (containing 50 mM potassium chloride, pH 6.8) and immersed overnight, and the film was observed. The results are shown in Table 1.
[0086]
[Table 1]

[0087]
In addition, the meaning of each code | symbol in Table 1 is as follows.
<After drying>
X: peeling
Δ: Surrounding drowning
○: Clean membrane
<In buffer>
X: already peeled or peeled by shaking the solution
Δ: Not peeled by solution shaking, but easily peeled by peripheral swelling or tweezers
○: A clean film. When scratching with tweezers, the film can be removed with a width slightly wider than the contact surface with tweezers.
◎ When scratching with tweezers, only the part in contact with tweezers can be removed
[0088]
As can be seen from Table 1, in all examples, the adhesion of the enzyme film was improved as compared with the comparative example. Further, from the comparison of the five examples of Example 9, it was found that the greater the content of polymer B in the mixed layer (that is, the greater the surface exposed area ratio of polymer B), the stronger the adhesion of the enzyme film. It was. More specifically, the ratio of the polymer B is preferably 20% (substance A: polymer B = 4: 1) or more.
[0089]
(Example 15) Sensor evaluation by flow injection analyzer
The sensors prepared in Examples 6 to 12 were attached to a flow cell, and the peak current of the response to a solution of ascorbic acid (ASA, 100 mM) and glucose (10 mM) was measured with the flow injection analyzer shown in FIG. The measurement conditions are shown below.
Carrier solution: a buffer solution containing 33 mM potassium dihydrogen phosphate, sodium monohydrogen phosphate, and 50 mM potassium chloride. pH 6.8.
・ Flow rate: 1.0 ml / min
Sample injection volume: 10 μl
Tube: The tube length from the sample injector of the sampler to the sensor is 120 cm, and the inner diameter is 0.8 mm.
The obtained results are shown in Table 2 together with the output (sensitivity) per unit concentration and the selection ratio.
[0090]
[Table 2]

[0091]
From Table 2, it can be seen that the ASA / glucose selection ratio varies greatly depending on the material of the mixed layer and the preparation method, and when the selection ratio is low, the sensitivity tends to be low. Generally speaking, the higher the sensitivity of the sensor and the lower the selection ratio, the better the sensor. From the viewpoint of the selection ratio, a sensor having a portion in which the content of the substance A is 100% in the mixed layer (for example, the sensor of Example 10) is desirable. However, as already mentioned, there are cases where the selectivity may be higher to some extent, such as when measuring a sample with a relatively low concentration of coexisting interference components compared to the target component, so depending on the actual situation, A suitable type of sensor may be selected.
[0092]
(Comparative Example 5) Evaluation of ceramic substrate electrode by flow injection analyzer
The same lot as the ceramic electrode substrate used in the above example was mounted on a flow cell without a mixed layer on the surface, and hydrogen peroxide (under the same conditions as in Example 15 was obtained using the flow injection analyzer shown in FIG. The peak currents of responses to HPO) and ASA (concentration 2 mM in common) were measured. The results are shown in Table 3. The electrode showed almost the same sensitivity to ascorbic acid and hydrogen peroxide.
[0093]
[Table 3]

[0094]
(Comparative Example 6) Evaluation of sensor without mixed layer by flow injection analyzer The glucose sensor produced in Comparative Example 4 was attached to a flow cell, and the flow injection analyzer shown in FIG. The peak current of the response to the solutions (concentration is 5 mM in common) was measured. The results are shown in Table 4. The sensor responded more than twice as much to glucose as the interfering component ASA.
[0095]
[Table 4]

[0096]
As is clear from the above Examples and Comparative Examples, the present invention has realized a biosensor with high accuracy and excellent stability.
[Brief description of the drawings]
FIG. 1 shows the basic structure of a biosensor according to the present invention.
[Figure 2] Diagram showing the basic structure of chitosan
FIG. 3 is a view showing an example of a mixing mode of the substance A and the polymer B in the mixed layer.
FIG. 4 is a diagram showing an example of a mixing mode of a substance A and a polymer B in a mixed layer
FIG. 5 is a view showing an example of a mixing mode of the substance A and the polymer B in the mixed layer.
FIG. 6 is a diagram showing an example of a mixing mode of the substance A and the polymer B in the mixed layer.
FIG. 7 shows an example of the structure of a biosensor.
FIG. 8 is a diagram showing an example of the structure of a biosensor
FIG. 9 is a diagram showing an example of the structure of a biosensor.
FIG. 10 is a schematic diagram showing an example of a surface layer portion in a mixed layer.
FIG. 11 is a schematic diagram showing an example of a surface layer portion in a mixed layer.
FIG. 12 shows an example of the structure of a biosensor
FIG. 13 shows an example of the structure of a biosensor.
FIG. 14 shows an example of the structure of a biosensor.
FIG. 15 shows an example of the structure of a biosensor.
FIG. 16 shows an example of the structure of a biosensor.
FIG. 17 shows an example of the structure of a biosensor.
FIG. 18 is a diagram showing an example of a tripolar base body formed on a ceramic substrate.
FIG. 19 is a graph showing the relationship between the surface composition of the substance A: polymer B in the mixed layer and the adhesion force.
FIG. 20 shows a flow injection analyzer.
FIG. 21 shows a basic structure of a conventional biosensor.
[Explanation of symbols]
1 ... Enzyme membrane
2 ... Permselective membrane
3 ... Mixed layer
4 ... Membrane
6 ... Base
7 ... Insulating substrate
8 ... Working electrode

Claims (4)

  In a biosensor comprising a substrate having a hydrogen peroxide electrode and an enzyme membrane on which a biocatalyst containing a hydrogen peroxide-producing enzyme is immobilized, a cellulose derivative or an ion exchange resin is interposed between the substrate and the enzyme membrane. A substance selected from the group (referred to as substance A) and a polymer substance (referred to as polymer B) having a functional group selected from the group consisting of an aldehyde group, an amino group, a carboxyl group, and an epoxy group. A biosensor characterized in that a mixed layer is formed.   The biosensor according to claim 1, wherein an exposure ratio of the polymer B in the mixed layer at a contact surface between the mixed layer and the enzyme film is 20% or more of a surface area.   The content of the polymer B in the mixed layer is the highest in the outermost layer portion in contact with the enzyme membrane, and has a gradient composition that gradually decreases as the distance from the enzyme membrane increases. Item 3. The biosensor according to Item 2.   The polymer B has a gradient composition in which the content of the polymer B in the mixed layer is the highest in the outermost layer portion in contact with the enzyme film and the substrate, and gradually decreases with distance from the enzyme film and the substrate. The biosensor according to claim 1 or 2.

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