JP2019032313A - Indicator and its manufacturing method - Google Patents

Abstract

To improve the detection accuracy of an indicator including a coloring component.SOLUTION: An indicator includes a strip-shaped bas material sheet S, and a porous layer P formed at one face of the base material sheet. The porous layer comprises: a first edge part E1 which is arranged at one end part of the base material sheet in a longitudinal direction, and located at one end part side; a second edge part E2 located at a side opposite to the first edge part; and a center part C located between the first edge part and the second edge part. The porous layer includes a first coloring component which detects an objective component, and exhibits a color by reacting mutually, and a second coloring component whose molecular weight is larger than that of the first coloring component. A ratio R1(=C12/C1c) of a concentration C12 of the first coloring component at the second edge part with respect to a concentration C1c of the first coloring component at the center part is not higher than 2.2.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an indicator including a color component that detects and colors a target component, and a method for manufacturing the indicator.

The indicator is used, for example, to check whether a liquid to be tested contains a target component (for example, H ⁺ , OH ⁻ , oxidizing agent, etc.) having a predetermined concentration or higher. Typical indicators include oxidant indicators (eg, oxidant test strips). For example, an oxidant is used as a disinfectant in a disinfectant for disinfecting an instrument such as a medical instrument. An indicator is used to check whether the disinfectant contains an effective concentration of disinfectant. As an indicator for oxidizing agents, for example, an indicator utilizing iodine starch reaction can be mentioned.

  The oxidant indicator includes a strip-shaped base sheet and a porous layer (such as paper or nonwoven fabric) formed on the surface. The porous layer contains a color component (for example, potassium iodide and starch) that detects and colors the target component. The porous layer is formed at one end of the base sheet in the length direction. In the oxidizing agent indicator, when the porous layer portion is immersed in a liquid to be tested, potassium iodide is oxidized by the oxidizing agent to generate iodine molecules, and the iodine molecules react with starch to give a color. Whether or not the oxidizing agent is contained in a predetermined concentration or more can be confirmed based on the degree of discoloration at this time.

  A strip-like indicator (such as a test paper) is produced by forming a porous layer on the surface at the end of a base sheet, impregnating the porous layer with a solution containing a drug, and drying (for example, Patent Document 1).

JP 2006-275716 A (paragraph [0065])

  However, when a strip-shaped indicator is manufactured and the concentration of the target component in the liquid is confirmed using such an indicator, the inspection accuracy may be lowered.

One aspect of the present invention includes a strip-shaped base sheet, and a porous layer formed on one surface of the base sheet,
The porous layer is disposed at one end portion in the length direction of the base sheet, the first edge portion on the one end side, the second edge portion on the opposite side to the first edge portion, and the first A center portion located between one edge portion and the second edge portion,
The porous layer includes a first color component that detects a target component and colors in response to each other, and a second color component having a molecular weight larger than that of the first color component,
The ratio R1 (= C12 / C1c) of the density C12 of the first color component in the second edge portion to the density C1c of the first color component in the center portion is 2.2 or less. .

Another aspect of the present invention includes a strip-shaped base sheet, and a porous layer formed on one surface of the base sheet,
The porous layer is disposed at one end portion in the length direction of the base sheet, the first edge portion on the one end side, the second edge portion on the opposite side to the first edge portion, and the first A center portion located between one edge portion and the second edge portion,
The porous layer includes a first color component that detects a target component and colors in response to each other, and a second color component having a molecular weight larger than that of the first color component,
The said base material sheet is related with the indicator which has a half cut trace just under the side end surface by the side of the said 2nd edge part of the said porous layer.

Still another aspect of the present invention provides a preparation step of preparing a base sheet and a porous layer formed on one surface of the base sheet,
A diffusion step of diffusing a first color component that detects a target component and reacts with each other in the porous layer and a second color component having a molecular weight larger than that of the first color component;
The present invention relates to a method for manufacturing an indicator, comprising: a step of dividing an end region having a relatively high concentration of the first coloring component in the porous layer and a remaining portion by a half cut.

  Inspection accuracy of the indicator including the color component can be improved.

It is a schematic plan view of the strip-shaped indicator which concerns on one Embodiment of this invention. It is a schematic plan view of the indicator which concerns on other embodiment of this invention. It is a schematic plan view of the indicator which concerns on further another embodiment of this invention. It is process drawing for demonstrating the manufacturing method of the indicator which concerns on embodiment of this invention. It is process drawing for demonstrating the procedure in the case of manufacturing an indicator industrially.

[indicator]
An indicator according to an embodiment of the present invention includes a strip-shaped (that is, strip-shaped) base sheet and a porous layer formed on one surface of the base sheet. The porous layer is disposed at one end in the length direction of the base sheet, and includes a first edge on one end, a second edge opposite to the first edge, a first edge, and a first edge A central portion located between the two edge portions. The porous layer detects a target component and includes a first color component and a second color component that react with each other and color. The ratio R1 (= C12 / C1c) of the density C12 of the first color component at the second edge part to the density C1c of the first color component at the center part is 2.2 or less.

  In an indicator including a strip-shaped base sheet and a porous layer formed on the surface, generally, a color component that detects and colors a target component is included in the porous layer. When manufacturing such an indicator industrially, the following method has been found to be efficient.

  First, as shown in FIG. 5, a belt-like porous layer P0 is provided at the center in the width direction of a base sheet S0 having a large size (more specifically, for a plurality of indicators), and includes a color component. The solution is applied to the porous layer P0 (for example, impregnated) and dried (step (a)). Next, as shown by a broken line, the base sheet S0 is divided into two in the width direction together with the porous layer P0, and a strip-shaped (that is, strip-shaped) indicator is obtained by finely cutting in the length direction ( Step (b)). In the strip-shaped indicator, the porous layer P is disposed on one surface at one end of the strip-shaped base sheet S.

  However, in this way, in the method of applying the solution after forming the porous layer P0 using the base sheet S0 for a plurality of indicators, the coloring component is applied to the entire porous layer P0 at a time in the step (a). It is difficult to grant. For this reason, usually, a solution is applied to a part of the porous layer P0 (for example, the central portion in the width direction of the porous layer P0) to diffuse the color component throughout the porous layer P0. The applied solution diffuses in the surface direction of the porous layer from the applied portion to the periphery. In such a method, since the timing at which the color component is diffused is shifted depending on the position in the porous layer P0, the distribution of the color component tends to vary. Application | coating of a solution is performed by dripping, application | coating, etc., for example. At this time, for example, the solution may be continuously applied to the central portion in the width direction of the porous layer P0 from one end portion to the other end portion in the length direction of the porous layer P0. The solution may be applied to the central portion in the width direction of the porous layer P0 from a plurality of discharge ports that are arranged open. In these cases, the distribution of the color components further varies.

  In the step (a), it is necessary to sufficiently diffuse the color component in the porous layer P0 in order to suppress the formation of the region where the color component does not exist in the porous layer P0. However, while the color component is diffused throughout the porous layer P0, the color component may accumulate at the end of the porous layer P0, and the concentration of the color component may become excessively high. In the indicator obtained by cutting the porous layer P0 in such a state together with the base sheet S0 in the step (b), the porous layer P is disposed at one end in the length direction of the base sheet S. It becomes. And in the edge part of the porous layer P of the other end part side of the length direction of the base material sheet S, the density | concentration of a color component will become high too much. When the concentration of the target component in the liquid to be tested is inspected using the indicator in such a state, an excessive color reaction occurs at the edge portion where the concentration of the color developing component is high, and the inspection accuracy decreases. In particular, when the porous layer includes a plurality of color components involved in the color reaction, the diffusibility in the porous layer differs if the molecular weights of these color components differ. Therefore, while the color component having low diffusibility is uniformly diffused in the porous layer P0, the color component having higher diffusibility accumulates at the end of the porous layer P0, and the concentration tends to be excessively high. The inspection degree tends to be lowered. In addition, depending on the type of the color component, the color of the edge portion of the porous layer having a high concentration of the color component may be darker than other regions in the state before being subjected to the test. The inspection accuracy may be reduced.

FIG. 1 is a schematic plan view of an indicator according to an embodiment of the present invention.
The indicator includes a strip-shaped base sheet S and a porous layer P formed on one surface of the base sheet S. The porous layer P is disposed at one end of the base sheet S in the length direction. The porous layer P includes a first edge E1 on one end side of the base sheet S, a second edge E2 on the opposite side of the first edge E1, a first edge E1, and a second edge E2. And a central portion C located between the two.

  In the present embodiment, the ratio R1 (= C12 / C1c) of the concentration C12 of the first color component in the second edge portion E2 of the porous layer P of the indicator to the concentration C1c of the first color component in the center portion C is set. 2.2 or less. That is, the concentration of the first color component in the second edge portion E2 of the porous layer P is suppressed from becoming excessively high. Therefore, the second edge portion E2 is suppressed from being darkly colored by the first color component, and excessive color reaction is suppressed from occurring at the second edge portion E2. Therefore, the inspection accuracy of the indicator can be increased.

In the strip-shaped indicator, when the porous layer is arranged at one end in the length direction of the base sheet, the end of the porous layer on the one end side of the base sheet (for example, 2 mm from the end) Of the porous layer opposite to the first edge portion (for example, a portion having a width of 2 mm from the end) is referred to as a second edge portion. A center part says the part located in the center in the direction along the length direction of a base material sheet of a porous layer. The concentration of each component in the central portion may be determined, for example, for a band-shaped portion having a width of 2 mm located in the center in the direction along the length direction of the base sheet of the porous layer. It is good also as a value which calculated | required and averaged about two adjacent strip | belt-shaped parts of width 2mm which pinch | interpose the centerline in the direction along the sheet | seat length direction.
Hereinafter, the indicator according to the present embodiment will be described in more detail with reference to the drawings as appropriate.

(Porous layer)
In the indicator, the porous layer is formed on one surface of the strip-shaped base sheet. The porous layer is shorter than the base sheet and is disposed at one end in the length direction of the base sheet. The porous layer includes a first color component and a second color component that detect a target component and react and color each other. In such an indicator, when the liquid containing the target component is brought into contact with the porous layer of the indicator, a color reaction involving the first color component and the second color component occurs, and the target component in the liquid The concentration can be confirmed.

  The porous layer may be formed on one side of the base sheet, but may be formed on both sides of the base sheet as necessary. Moreover, like the example of FIG. 1, you may form in not only one edge part in the length direction of a base material sheet but in both edge parts. At this time, a porous layer may be provided on both ends of one side of the base sheet, and a porous layer is provided on one end of the base sheet and the other side. In this case, a porous layer may be provided at the other end.

  The porous layer may be, for example, a porous film, but is preferably provided with a fiber assembly from the viewpoint of easily impregnating a solution containing a color component and a liquid to be tested. Moreover, you may use the laminated body of a porous film and a fiber assembly as a porous layer. Examples of the fiber aggregate include paper (including filter paper), non-woven fabric, woven fabric, knitted fabric, and the like. Of these, paper and non-woven fabric are preferred from the viewpoint of high impregnation with liquid.

  The material for the porous layer may be selected according to the application, and examples thereof include cellulose or derivatives thereof (cellulose ester, cellulose ether, etc.), resins (polyolefin resin, polyester resin, polyamide resin, etc.) and the like. The porous layer may contain one or more of these materials.

  The porous layer (specifically, the fiber assembly) includes a first color component and a second color component having a molecular weight larger than that of the first color component. More specifically, the first color component and the second color component are impregnated or supported on the porous layer (specifically, the fiber assembly). The first color component and the second color component are each diffused (or distributed in a dispersed state) in the porous layer (specifically, the fiber aggregate). As a 1st coloring component and a 2nd coloring component, various things can be used according to the use of an indicator, for example.

  Examples of the first color component include a component that is colored by a reaction with a second color component described later in the presence of the target component. Examples of the first color component include a redox indicator, an adsorption indicator, and a TLC (thin layer chromatography) color indicator. As the first color component, two or more of these may be used as necessary, but the concentration of the first color component in each part included in the porous layer, such as the second edge part and the central part, is Assume that calculation is performed by paying attention to one type of first color component.

  As the second colored component, for example, a component that reacts with the first colored component in the presence of the target component to be colored can be used. Since the second color component has a higher molecular weight than the first color component, the diffusibility when impregnating the porous layer is lower than that of the first color component. In the case where the second color component is a polymer, the average molecular weight (for example, the weight average molecular weight) of the second color component may be larger than the molecular weight of the first color component.

  The second color component may be selected according to the type of the first color component and / or the target component. For example, when the target component is an oxidizing agent, an iodide that generates iodine in the presence of the oxidizing agent may be used as the first coloring component, and starch may be used as the second coloring component. In this case, iodine produced by oxidation of iodide in the presence of an oxidizing agent and starch cause a color reaction by causing an iodine starch reaction, and the presence of the oxidizing agent can be detected. As the iodide, sodium iodide, potassium iodide and the like are preferable. Among these, potassium iodide is preferable from the viewpoint of easily generating iodine due to the action of the oxidizing agent.

  In the present specification, the first color component can generate the component A (iodine or the like) that actually reacts with the second color component and the component A in the presence of the target component. Any one of the precursors of the component A (iodide etc.) shall be included. That is, the concentration of the first color component in each part such as the second edge part or the center part may be calculated by paying attention to either component A or its precursor.

  The porous layer can contain an additive depending on the application, if necessary. For example, the porous layer may include an additive for facilitating confirmation of a color reaction between the first color component and the second color component. For example, when iodide is used as the first color component and starch is used as the second color component, the porous layer preferably further contains a reducing agent. The reducing agent has a function of reducing iodine produced by oxidation of iodide by an oxidizing agent as a target component, and can suppress an excessive color reaction, thereby further improving inspection accuracy. . As the reducing agent, iron (II) ion, tin (II) ion, hydride, or the like may be used. From the viewpoint of easily reducing iodine, thiosulfate, sulfite, hyposulfite, etc. may be used. preferable. As the thiosulfate, sulfite and hyposulfite, for example, alkali metal salts such as sodium salt and potassium salt are preferable. You may use a reducing agent individually by 1 type or in combination of 2 or more types.

  In the present embodiment, the ratio R1 (= C12 / C1c) of the density C12 of the first color component at the second edge part to the density C1c of the first color component at the center part may be 2.2 or less. is important. Thereby, since it is suppressed that a color reaction occurs excessively in the 2nd edge part and its neighborhood, the inspection accuracy of an indicator can be raised. From the viewpoint of reducing the variation in the color reaction in the porous layer, the ratio R1 is preferably 2 or less, and more preferably 1.7 or less. When the porous layer includes a reducing agent, the ratio R1 is more preferably 1.3 or less or 1.2 or less, and may be 1.1 or less.

  In the indicator, a solution containing the first color component is applied to the porous layer (for example, impregnated) and dried, whereby the first color component is supported on the porous layer. Therefore, the porous layer may have an inclination in the distribution of the first color component. For example, in the porous layer, the concentration of the first color component may increase from the first edge portion toward the second edge portion. However, in the indicator having such a gradient of density distribution, the density of the first color component tends to be excessively high in the second edge portion as compared with the central portion and the first edge portion. In the present embodiment, even when such a density distribution is provided, the high inspection accuracy of the indicator can be ensured by suppressing the density ratio R1 of the first color component within the above range. Note that the density of the first color component may increase continuously from the first edge portion toward the second edge portion, or may increase stepwise.

  The density ratio R1 of the first color component can be obtained as follows. First, the first color component extracted from each part is identified using a nuclear magnetic resonance spectrum, a mass spectrum, or the like. Next, the first color component extracted from each part is dissolved in a predetermined amount of solvent, and the absorbance at a wavelength characteristic of the first color component is measured. Then, the content (g) of the first color component in each of the second edge portion and the central portion is obtained by comparing with the absorbance of the sample of the solution containing the first color component of known concentration, and the second edge The ratio of the content (g) of the first color component in the part to the content (g) of the first color component in the center part can be calculated, and the ratio of the content can be set as the density ratio R1. . The first color component can be extracted from the indicator by cutting out the second edge portion and the central portion and using a solvent (such as water and / or an organic solvent) from each portion.

  When actually determining the concentration (mass%) of the first color component in each part, the ratio (mass%) of the content (g) of the first color component in the mass (g) of the porous layer for each part. ) And the actual concentration (mass%) of the first color component in each part. The mass of the porous layer in each part may be determined by measuring the dry mass of the porous layer after peeling the porous layer from the base sheet in each part. The total dry mass may be measured, and the porous layer may be exfoliated cleanly from the substrate sheet, and the measured mass of the substrate sheet may be subtracted.

  Further, instead of actually obtaining the content and concentration of the first color component in each part, the absorbance of the first color component extracted from the second edge part is relative to the absorbance of the first color component extracted from the center part. The ratio may be obtained, and this absorbance ratio may be used as the concentration ratio R1. In this case, if the liquid obtained is concentrated or diluted so that the mass of the liquid obtained by extracting the first color component from each part is the same, correction associated with variations in the concentration of each liquid is unnecessary. Become.

  When the absorbance of the first color component itself contained in the indicator is small and it is difficult to calculate the concentration ratio, a component to be colored (for example, an oxidizing agent or a reducing agent) is added to the extracted first color component. Then, the concentration ratio R1 may be obtained in a colored state. In this case, the concentration ratio R1 may be obtained from the absorbance ratio in consideration of the relationship of the molar ratio between the colored component and the first colored component from the reaction formula of the first component and the colored component.

  In addition, when it is difficult to obtain the concentration ratio R1 from the absorbance, using a high-performance liquid chromatography or gas chromatography, from a calibration curve obtained based on a sample of a solution containing a first color component having a known concentration, R1 may be calculated by obtaining the density of the first color component in each part.

  The slope of the density of the first color component can be determined according to the density ratio R1. For example, the density of the first color component in the first edge part, the second edge part, and the central part may be obtained in accordance with the case of obtaining the density ratio R1. For each part, it is convenient if the absorbance is measured according to the concentration ratio R1, and the slope of absorbance is determined as the slope of concentration. Moreover, when calculating | requiring the inclination of light absorbency, you may utilize the light absorbency of the state colored by adding the component made to color to a 1st color component like the case of density | concentration ratio R1.

The ratio R2 (= C22 / C2c) of the density C22 of the second color component at the second edge portion to the density C2c of the second color component at the center portion is the same as the density ratio R1 of the first color component. Although it may be larger than R1, it is preferable to satisfy the relationship of R1> R2. Since the second color component has a higher molecular weight than the first color component, it is less likely to diffuse into the porous layer than the first color component, and the second color component is diffused throughout the porous layer. In the meantime, the density of the first color component may increase at the second edge portion and its vicinity. In this case, R1> R2 is likely to occur, and the color reaction tends to be excessive. For example, when using iodide as the first color component and starch as the second color component, the molecular weight of iodide is smaller than starch and the diffusion rate is high, so the second edge and its The concentration of iodide in the vicinity tends to be high. Even in such a case, according to the present embodiment, it is easy to ensure high inspection accuracy of the indicator by limiting the concentration ratio R1 to the above range. That is, the indicator according to the present embodiment is particularly suitable for the case where the first color component and the second color component having a higher molecular weight (or a lower diffusion rate) than the first color component are used.
The concentration ratio R2 of the second color component is the same as in the case of R1, the second color component is extracted from each part, the second color component is identified, and the content of the second color component in each part It can be determined from the ratio, concentration ratio, absorbance ratio, or the like.

When the porous layer contains an additive for easily confirming the color reaction such as a reducing agent, the additive (reduction) in the central portion of the concentration Cr2 of this additive (reducing agent, etc.) at the second edge portion. The ratio R4 (= Cr2 / Crc) of the agent to the concentration Crc is preferably less than 1.5, and more preferably 1.2 or less or 1.1 or less. When the concentration ratio R4 of the additive is within such a range, it is easy to adjust the degree of coloration of the color reaction and to further improve the inspection accuracy.
In addition, the additive concentration ratio R4 is obtained from the content of the additive in each part, the concentration ratio, or the absorbance ratio, etc., by extracting the additive from each part and identifying the additive according to the case of R1. Can do.

  The distribution state of the second color component and the additive (reducing agent, etc.) in the porous layer may be inclined as in the case of the first color component. For example, in the porous layer, the concentration of the second color component and / or additive may increase from the first edge portion toward the second edge portion. When the diffusion rate of the second color component in the porous layer is small, the distribution of the second color component is smaller than the slope of the distribution of the first color component. The slope of is gentle. Regarding the gradient of the concentration of each component of the second color component and the additive in the porous layer, the state of the absorbance gradient can be used as an index according to the case of the first color component.

What is necessary is just to determine the length of a porous layer according to the use and size of an indicator. The length of the porous layer is, for example, 4 mm or more and 70 mm or less, and preferably 5 mm or more and 10 mm or less.
The length of the porous layer is the length of the porous layer in the direction along the length direction of the strip-shaped indicator.

  The thickness of the porous layer may be determined according to the material of the porous layer, the use of the indicator, and the like. The thickness of the porous layer is preferably 100 μm or more and 300 μm or less, for example.

  The indicator may further comprise a strip disposed adjacent to the porous layer. FIG. 2 is a schematic plan view of an indicator having a belt-like portion. The belt-like part B is disposed adjacent to the second edge part E2 of the porous layer P on one surface of the base sheet S. The strip-shaped portion B includes a first color component and a second color component, and is removable from the base sheet S. Such a belt-like portion B originally constitutes a part of the porous layer P, and is cut or divided from the porous layer P by making a cut outside the second edge portion E2 of the porous layer P. Is formed. Therefore, the belt-like part B is formed of the same material as the porous layer P.

Since the belt-like portion B is originally continuous with the porous layer P, the concentration of the first color component in the belt-like portion B is the second edge portion E2, the central portion C, and the first portion of the porous layer P. The density is higher than the density of the first color component in the edge portion E1. Therefore, the ratio R1 and the ratio R3 (= C13 / C1c) of the density C13 of the first color component in the band B to the density C1c of the first color component in the center C satisfy R3> R1. . Similarly, when the porous layer P includes an additive such as a second color component or a reducing agent, the concentration of these components in the band-like portion B is the first edge portion E1, the central portion of the porous layer P. It is higher than the concentration of each component in C and the second edge portion E2.
As for the density ratio R3 of the first color component, the first color component is extracted from the belt-like portion and the central portion, the first color component is identified, and the first color component in each portion is the same as in the case of R1. It can be determined from the content ratio, concentration ratio, or absorbance ratio of the components.

  The strip B can be removed before the indicator is cut into a strip shape, but when it is cut into a strip shape without being removed, the indicator remains in the indicator as shown in FIG. From the viewpoint of ensuring a higher inspection accuracy, it is preferable to remove the belt-like portion B at an appropriate stage before the indicator is subjected to the test.

The width of the strip portion B is not particularly limited, but is, for example, 1 mm or more and 5 mm or less, preferably 1 mm or more and 4 mm or less, and more preferably 1 mm or more and 3 mm or less (particularly 1 mm or more and 2 mm or less). When the strip B has such a width, the concentration gradient of the first color component in the porous layer P can be easily reduced, so that the inspection accuracy of the indicator can be further increased.
In addition, the width | variety of the strip | belt-shaped part B is the length of the strip | belt-shaped part B in the direction in alignment with the length direction of a strip-shaped indicator.

(Base material sheet)
The substrate sheet only needs to hold the porous layer, but preferably has an appropriate strength from the viewpoint of ensuring the handleability of the indicator. What is necessary is just to select the material of a base material sheet according to the use of an indicator. As a base material sheet, a film, a fiber assembly, etc. are mentioned, for example. The film may be a single layer film or a multilayer film. Examples of the fiber assembly include paper, nonwoven fabric, woven fabric, and knitted fabric. A laminate of a film and a fiber assembly may be used as the base sheet.

  Examples of the material of the base sheet include cellulose or derivatives thereof (cellulose ester, cellulose ether, etc.), resins (polyolefin resin, polyester resin, polyamide resin, etc.) and the like. Examples of the polyolefin resin include polyethylene and polypropylene. Examples of the polyester resin include polyethylene terephthalate (PET) and polybutylene terephthalate. Examples of the polyamide resin include polyamide 6, polyamide 66, polyamide MXD, and the like. The base sheet may contain one or more of these materials.

The substrate sheet may be in the form of a strip, and the width W3 and length L3 of the substrate sheet may be selected according to the application of the indicator. The width W3 of the base sheet is preferably 4 mm or greater and 30 mm or less, for example. The length L3 of the base sheet is preferably 40 mm or more and 100 mm or less, for example.
Although the thickness in particular of a base material sheet is not restrict | limited, For example, they are 100 micrometers or more and 300 micrometers or less.

  The base sheet may have a half cut mark. FIG. 3 is a schematic plan view of an indicator having a half-cut mark. The indicator in FIG. 3 is the same as the indicator in FIG. 1 except that the base sheet S has half-cut marks. As shown in FIG. 3, the half-cut mark H is formed immediately below the side end surface of the porous layer P on the second edge portion E <b> 2 side in the base sheet S.

  The half cut mark H is formed, for example, when the strip portion is divided or divided from the porous layer. The band-shaped portion is separated from the porous layer P by cutting the outer end portion of the second edge portion of the porous layer P. At this time, the base sheet S is not cut (that is, the porous layer is cut by half-cutting), but usually a trace (that is, half-cut trace H) remains on the surface of the base sheet S. .

  When the indicator is immersed in the liquid to be tested and pulled up, or when the liquid is dropped on the porous layer portion of the indicator, the excess liquid that cannot be absorbed by the porous layer is the second edge of the porous layer P. On the base material sheet S outside the portion E2 (that is, a step portion formed by a height difference between the surface of the porous layer P and the surface of the base material sheet S in the cross section in the thickness direction in the length direction of the indicator) Accumulation and inspection accuracy may be affected. In the indicator having the half-cut mark H, even if surplus liquid is supplied to the porous layer P, the liquid easily flows along the half-cut mark H (that is, the liquid is easily cut off). Accumulation is suppressed. Therefore, it becomes easier to ensure high inspection accuracy.

  The half cut marks H may be formed intermittently (for example, in a broken line shape) along the width direction of the base sheet S. From the viewpoint of securing higher liquid breakage, the half-cut marks H are continuous from one end to the other end in the width direction of the base sheet S (for example, linear (particularly linear)). It is preferable to be formed.

(Target ingredient)
In the indicator according to the present embodiment, since excellent inspection accuracy is ensured, the concentration of various target components involved in the color reaction of the first color component is inspected according to the type of the first color component. be able to. For example, when the first color component is iodide and the second color component is starch, an oxidant (for example, a peroxide such as hydrogen peroxide or peracetic acid) as a target component is indicated by an indicator. ) Concentration can be inspected.

(Indicator manufacturing method)
The indicator manufacturing method according to the present embodiment includes a preparation step (i) of preparing a base sheet and a porous layer formed on one surface of the base sheet, and detecting a target component in the porous layer. A diffusion step (ii) of diffusing a first color component that reacts with each other and a second color component having a molecular weight larger than that of the first color component; and a first color in the porous layer And a sorting step (iii) for sorting the end region having a relatively high component concentration and the remaining portion by half-cutting. Usually, since a base sheet for a plurality of indicators is used in the preparation step (i), a strip-shaped indicator (more specifically, a strip-shaped indicator having a width W3 and a length L3) is cut out. Step (iv) is performed.

FIG. 4 is a process diagram for explaining an example of the method for manufacturing the indicator according to the present embodiment.
In the preparation step (i), a large-sized base sheet S0 is used. The base sheet S0 has a width W1 that is sufficiently larger than the length L3 of the strip-shaped indicator (for example, twice or more of L3) and is sufficiently larger than the width W3 (for example, 10 times or more of W3). Has a length L1.

  In a region other than both ends in the width W1 direction of the base sheet S0, a belt-like porous layer P0 is attached along the length L1 direction. The belt-like porous layer P0 has a width W2 that is sufficiently smaller than the width W1, and has a length L2. The strip-shaped porous layer P0 is attached to, for example, the central portion in the width W1 direction of the base sheet S0.

  In the preparation step (i), the belt-like porous layer P0 may be attached to a predetermined position of the large-sized base sheet S0. Adhesion, double-sided tape, or the like may be used for pasting, and heat welding or laser welding may be used.

  Then, the step (ii) of diffusing the first color component and the second color component (and, if necessary, an additive) into the porous layer P0 is performed. In the diffusion step (ii), the first color component and the second color component are applied to the porous layer P0 and diffused into the porous layer P0. As described above, when a color component is imparted to a part of the porous layer P0 (for example, the central portion in the width direction of the belt-like porous layer P0) and diffused in the porous layer, it is particularly preferable. Variation in color component distribution is likely to occur. For example, when a coloring component is applied to the porous layer P0 using dripping, the coloring component is generally applied to a part of the porous layer P0 and diffused. When a plurality of color components are used, the variation in the distribution of each color component tends to be further increased. Thus, even when the distribution of the color components tends to vary, according to the present embodiment, an indicator with improved inspection accuracy can be provided by performing the sorting step (iii).

  In the diffusion step (ii), when the first color component is diffused in the porous layer P0, for example, a solution containing the first color component is distributed so that the first color component is distributed throughout the porous layer P0. At least, it is supplied or applied to the central portion in the width direction of the belt-like porous layer P0. The first color component is gradually diffused and spreads throughout the porous layer. Therefore, the concentration of the first color component at the end of the belt-like porous layer P tends to be excessively high.

  In the diffusion step (ii), the color component and / or additive is applied to the porous layer P0 in the form of a solution, for example. The coloring component and the additive may be applied as long as each component can be impregnated into the porous layer P0. However, rather than immersion, for example, liquid is directly applied to the porous layer P0 such as dripping, spreading, and coating. It is preferable to use such a method. When the porous layer is impregnated with the porous layer by immersing the porous layer in a solution containing the colored component, etc., the density and thickness of the porous layer, and the amount of solution retained due to surface tension vary. This is because the amount of the component supported on the porous layer is likely to vary. On the other hand, since the amount of solution applied to the porous layer can be easily controlled by using dripping or the like, the amount of color components per unit area in the porous layer is controlled to be constant compared to the case of using immersion. Easy to do. Therefore, the quality of the indicator can be stabilized. However, as described above, when the coloring component is applied (or impregnated) to the porous layer by using dropping or the like, the coloring component is applied to a part of the porous layer. It is difficult to control the distribution of color components in the quality layer. According to this embodiment, even if it is difficult to control the distribution of the color components in this way, the inspection accuracy of the indicator can be improved by the sorting step (iii).

  The component imparted to the porous layer P0 is diffused into the porous layer P0. After the solution is applied to the porous layer P0, the coloring component and / or the additive are usually supported on the porous layer P0 by drying. The first color component and the second color component may be applied simultaneously or individually to the porous layer P0. The additive may be applied to the porous layer P0 at the same time as at least one color component, or may be applied separately from the color component. For example, a solution containing the first color component and the second color component may be applied to the porous layer P0, and a solution containing the first color component and a solution containing the second color component are respectively provided. You may provide to the porous layer P0. In the latter case, each solution may be applied simultaneously or separately to the porous layer P0 (for example, after applying one solution, the other solution may be applied). When the additive is used, it may be added to the color component solution, or the additive may be added to the porous layer P0 separately from the color component solution. When a plurality of solutions each containing a color component are used, the additive may be added to a part of the solution or may be added to all the solutions.

  More specifically, in the diffusion step (ii), the porous layer P0 is impregnated with the first color component by impregnating the porous layer P0 with a solution containing the first color component and dried. It can be supported. The second color component may be impregnated or supported on the porous layer P0 in the diffusion step (ii) as in the case of the first color component. Even when an additive is used, the porous layer P0 may be impregnated or supported in the diffusion step (ii) as in the case of the first color component. The second color component and / or additive may be mixed in the solution containing the first color component, and the second color component and / or additive may be added separately from the solution containing the first color component. You may prepare the solution containing and impregnate the porous layer P0.

  In the sorting step (iii), the end portion of the band-shaped porous layer P0 in which the concentration of the first colored portion is excessively high (that is, the portion outside the second edge portion E2 of the porous layer P in the strip-shaped indicator). (Edge region)) is cut along a cut position (half-cut position) h indicated by a one-dot broken line to form the above-described band-shaped portion B. The end region may be removed from the base sheet. By removing the end region, the concentration ratio R1 of the first color component in the porous layer P of the indicator can be adjusted to the above range.

  The end region (band-like portion B) can be cut by half-cutting the porous layer P portion without cutting the base sheet S. At this time, a half-cut mark H may remain on the surface of the base sheet S. The half cut mark H can provide an indicator that can ensure high inspection accuracy. The band-like portion B after half-cutting can be removed when the indicator is cut out, and the indicator as shown in FIG. 1 and the indicator shown in FIG. Moreover, the strip | belt-shaped part B may remain in the indicator after cut out. In this case, an indicator as shown in FIG. 2 is obtained.

  The step (iv) of cutting out the indicator may be performed after the diffusion step (ii). However, the step (iv) is preferably performed after the division step (iii) and / or in parallel with the division step (iii). The end region can be easily cut. In the step (iv) of cutting out the indicator, a strip-shaped indicator having a width W3 and a length L3 is cut out. In the step (iv) of cutting out the indicator, for example, the base material sheet is divided into two in the width W1 direction together with the porous layer so as to cross the central portion of the belt-like porous layer, and is divided into a plurality in the length L1 direction. That's fine. For example, as in the case of FIG. 5, as shown by the broken line in FIG. 4, the base sheet S0 is divided into two in the width W1 direction together with the porous layer P0 so as to cross the central portion of the belt-like porous layer P0. In addition, a strip-shaped indicator is obtained by finely cutting in the length L1 direction. The cutting in the length L1 direction is preferably performed after the sorting step (iii) from the viewpoint of facilitating the cutting in the sorting step (iii). However, the two divisions in the width W1 direction may be performed after the diffusion step (ii) and before the division step (iii), and in parallel with the division step (iii) (for example, in the division step (iii)). (In parallel with the cutting of the end regions).

[Example]
EXAMPLES Hereinafter, although this invention is demonstrated concretely based on an Example and a comparative example, this invention is not limited to a following example.

<Example 1 and Comparative Example 1>
(Preparation of indicator)
An aqueous solution a containing 0.23% by mass of potassium iodide as a first color component and an aqueous solution b containing starch as a second color component at a concentration of 3.53% by mass were prepared.
At the center in the width direction of the PET film (length 150 mm × width 100 mm × thickness 200 μm), a strip-shaped filter paper (ADVANTEC, No. 1 filter paper, length 150 mm × width 16 mm) is added to the length of the PET film and the filter paper. Aligned direction and pasted with double-sided tape. The aqueous solution a and the aqueous solution b were dropped on the filter paper (specifically, the central portion in the width direction of the filter paper) to spread the solution over the entire filter paper. Then, it was dried for 10 minutes in a constant temperature bath at 80 ° C.

  The filter paper and the PET film were divided into two at the central portion in the width direction of the filter paper. One of the divided pieces was finely cut in the length direction as shown by a broken line in FIG. 4B to produce a strip-shaped indicator having a width of 6 mm. At this time, as for the half of the indicator (Example 1), the end (width 2 mm) of the filter paper opposite to the end where the filter paper of the indicator is arranged is indicated by a one-dot broken line in FIG. And half-cut at half-cut position h. For the remaining half of the indicator (Comparative Example 1), the filter paper was not half cut.

(Evaluation)
(1) Concentration ratios R1 and R2 and the gradient of the density of the first color component About the other two divided pieces, the filter paper part is the PET film, the width of 2 mm from the end on the filter paper side. The band was divided into four, and the first sample, the second sample, the third sample, and the fourth sample were formed in order from the end. In Example 1, the first sample corresponds to the first edge portion, the second sample corresponds to the center portion, and the third sample corresponds to the second edge portion. In Comparative Example 1, the first sample corresponds to the first edge portion, and the fourth sample corresponds to the second edge portion. In Comparative Example 1, the average values of the values of the second sample and the third sample were used for the concentration and absorbance of each component in the center.

  Then, the first color component was extracted from each sample with ion-exchanged water, and the obtained liquid was concentrated or diluted so that the mass of the liquid obtained from each sample was the same. Then, each liquid was colored by adding 0.1 g of 35% by mass hydrogen peroxide solution. The amount of hydrogen peroxide added here is sufficient to convert all iodide contained in each liquid into iodine. The liquid obtained by coloring the liquid obtained from the first sample to the fourth sample was designated as Sample 1 to Sample 4, and the absorbance at 350 nm was measured. 350 nm is an absorption wavelength characteristic of a component in which iodine produced by oxidation of potassium iodide by hydrogen peroxide is incorporated into starch. The ratio of the absorbance of sample 3 to the absorbance of sample 2 was determined and used as the R1 ratio in Example 1. Moreover, the average value of the light absorbency of sample 2 and sample 3 was calculated | required, ratio of the light absorbency of sample 4 with respect to this average value was calculated | required, and it was set as R1 ratio in the comparative example 1. The R1 ratio of Example 1 was 1.40, and the R1 ratio of Comparative Example 1 was 3.69.

  Regarding Example 1, the absorbance at 350 nm of Sample 1, Sample 2, and Sample 3 is 0.030, 0.035, and 0.049, respectively, and the absorbance from the first edge portion toward the second edge portion. (That is, the concentration of the first color component) increased. It should be noted that the concentration of starch in which iodine was incorporated in each part (that is, the concentration of produced iodine) calculated from the absorbance of Samples 1 to 3 in the above-described procedure was 0.009% by mass of the first sample, respectively. The second sample was 0.010 mass% and the third sample was 0.015 mass%.

(2) Indicator inspection accuracy For each of Example 1 and Comparative Example 1, the filter paper portion of the slit-shaped indicator was dipped in a 35% by mass aqueous hydrogen peroxide solution and pulled up.
In the indicator of Example 1, it was confirmed that the entire filter paper portion was colored almost uniformly, and the aqueous hydrogen peroxide solution contained hydrogen peroxide at an effective concentration. On the other hand, in the indicator of Comparative Example 1, the second edge portion was colored yellow before being immersed in the hydrogen peroxide solution. Further, in the indicator of Comparative Example 1, after being immersed in the aqueous hydrogen peroxide solution, the second edge portion of the filter paper and the vicinity thereof are darkly colored, and it is determined whether hydrogen peroxide is contained in an effective concentration. It was hard to get along.

<Example 2 and Comparative Example 2>
An aqueous solution c containing sodium sulfite as a reducing agent at a concentration of 2% by mass was prepared.
In addition to the aqueous solution “a” and the aqueous solution “b”, the aqueous solution “c” was further dropped onto the filter paper, and each solution was spread over the entire filter paper. Except for this, indicators were prepared and evaluated in the same manner as in Example 1 and Comparative Example 1, respectively. The R1 ratio of Example 2 was 1.04, and the R1 ratio of Comparative Example 2 was 2.25.

  Further, for Sample 1 to Sample 4, the iodine concentration in each part was determined in the same manner as in Example 1 and Comparative Example 1, and this iodine concentration was determined in each part in Example 1 and Comparative Example 1. By subtracting from the concentration, the concentration (% by mass) of the reducing agent in each part was determined. When the R4 ratio in Example 2 and Comparative Example 2 was determined, the R4 ratio in Example 2 was 0.92 (≈1), and the R4 ratio in Comparative Example 2 was 1.50.

  Regarding Example 2, the absorbance at 350 nm of Sample 1, Sample 2, and Sample 3 is 0.112, 0.119, and 0.124, respectively, and the absorbance from the first edge portion toward the second edge portion. (That is, the concentration of the first color component) increased. In addition, the density | concentration (namely, density | concentration of the produced | generated iodine) of the starch in which the iodine was taken in in each part calculated from the light absorbency of the samples 1 to 3 in the above-described procedure was 0.035% by mass of the first sample, respectively. The second sample was 0.037 mass% and the third sample was 0.086 mass%.

  When evaluation (2) was performed for each of Example 2 and Comparative Example 2, the indicator of Example 2 showed that the entire filter paper portion was almost uniformly colored, and the aqueous hydrogen peroxide solution had an effective concentration. It was confirmed to contain hydrogen oxide. On the other hand, in the indicator of Comparative Example 2, whitish spots were seen at the second edge portion of the filter paper and in the vicinity thereof, and it was difficult to judge whether hydrogen peroxide was contained in an effective concentration.

  In the indicator according to the present embodiment, high inspection accuracy can be ensured. Therefore, the indicator is suitable for an application for inspecting the concentration of various target components such as an oxidant indicator.

  P: porous layer, S: substrate sheet, E1: first edge portion, E2: second edge portion, C: center portion, B: belt-like portion, H: half cut mark, h: half cut position

Claims (21)

A strip-shaped base sheet, and a porous layer formed on one surface of the base sheet,
The porous layer is disposed at one end portion in the length direction of the base sheet, the first edge portion on the one end side, the second edge portion on the opposite side to the first edge portion, and the first A center portion located between one edge portion and the second edge portion,
The porous layer includes a first color component that detects a target component and colors in response to each other, and a second color component having a molecular weight larger than that of the first color component,
The ratio R1 (= C12 / C1c) of the density C12 of the first color component in the second edge part to the density C1c of the first color component in the center part is 2.2 or less.   The ratio R1 and the ratio R2 (= C22 / C2c) of the density C22 of the second color component at the second edge portion to the density C2c of the second color component at the center portion are R1> R2 The indicator according to claim 1, wherein the relationship is satisfied. The porous layer comprises a fiber assembly,
The indicator according to claim 1 or 2, wherein the fiber assembly includes the first color component and the second color component.   The indicator according to any one of claims 1 to 3, wherein the fiber assembly is paper or non-woven fabric.   5. The indicator according to claim 1, wherein in the porous layer, the concentration of the first color component increases from the first edge portion toward the second edge portion.   The said base material sheet is an indicator of any one of Claims 1-5 which has a half cut trace just under the side end surface by the side of the said 2nd edge part of the said porous layer. Furthermore, on the one surface of the base sheet, a belt-like portion disposed adjacent to the second edge portion is provided,
The strip portion includes the first color component and the second color component,
The said strip | belt-shaped part is an indicator of any one of Claims 1-6 which is removable with respect to the said base material sheet.   The indicator according to claim 7, wherein the ratio R1 and the ratio R3 (= C13 / C1c) of the density C13 of the first color component in the strip portion to the density C1c satisfy R3> R1. The target component is an oxidizing agent,
The first color component is an iodide that generates iodine in the presence of the oxidizing agent;
The indicator according to claim 1, wherein the second color component is starch.   The indicator according to claim 9, wherein the iodide is potassium iodide.   The indicator according to claim 9 or 10, wherein the porous layer further includes a reducing agent for reducing the iodine.   The indicator according to claim 11, wherein a ratio R4 (= Cr2 / Crc) of the reducing agent concentration Cr2 in the second edge portion to the reducing agent concentration Crc in the central portion is less than 1.5. A strip-shaped base sheet, and a porous layer formed on one surface of the base sheet,
The porous layer is disposed at one end portion in the length direction of the base sheet, the first edge portion on the one end side, the second edge portion on the opposite side to the first edge portion, and the first A center portion located between one edge portion and the second edge portion,
The porous layer includes a first color component that detects a target component and colors in response to each other, and a second color component having a molecular weight larger than that of the first color component,
The said base material sheet is an indicator which has a half cut trace just under the side end surface by the side of the said 2nd edge part of the said porous layer. A preparation step of preparing a base material sheet and a porous layer formed on one surface of the base material sheet;
A diffusion step of diffusing a first color component that detects a target component and reacts with each other in the porous layer and a second color component having a molecular weight larger than that of the first color component;
A method for producing an indicator, comprising: a step of dividing an end region having a relatively high concentration of the first color component in the porous layer and a remaining portion by a half cut.   The manufacturing method of the indicator of Claim 14 which further has the process of removing the said edge part area | region from the said base material sheet.   In the diffusion step, the first color component and the second color component are simultaneously or individually applied to a part of the porous layer and diffused in the porous layer. 15. The method for producing an indicator according to 15.   17. The diffusion process according to claim 14, wherein in the diffusion step, the first color component and the second color component are dripped and diffused into the porous layer simultaneously or individually. The manufacturing method of an indicator.   The manufacturing method of the indicator of any one of Claims 14-17 which forms a half cut trace in the said base material sheet in the said division process. In the preparation step,
The base sheet having a width W1 and a length L1, and a width W2 (W2 <W1) and a length that are attached along the length L1 direction to regions other than both ends in the width W1 direction of the base sheet A belt-like porous layer having a thickness L2,
The manufacturing method of the indicator of any one of Claims 14-18 in which the said edge part area | region contains the both ends in the width W 2 direction of the said strip | belt-shaped porous layer.   The substrate sheet was cut into a strip shape having a width W3 (however, W3 <L1) and a length L3 (where L3 <W1), and the porous layer was disposed at one end in the length L3 direction. The method for manufacturing an indicator according to claim 19, further comprising the step of cutting out the indicator. In the step of cutting out the indicator,
21. The indicator according to claim 20, wherein the base sheet is divided into two in the width W1 direction and into a plurality in the length L1 direction along with the porous layer so as to cross a central portion of the belt-shaped porous layer. Manufacturing method.

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