JPH0731187B2 - Test tool - Google Patents

Description

TECHNICAL FIELD The present invention relates to a test device for detecting a biological component.
In particular, the present invention relates to a test device that can appropriately analyze even an excessively supplied body fluid for the analysis of body fluid components.

[Problems to be Solved by Conventional Techniques and Inventions] In the field of clinical examination, as a means for detecting or quantifying a specific component in a body fluid such as urine or blood, a dry type containing a certain amount of a necessary reagent The test piece is widely used. That is, a multilayer analytical piece (also referred to as a multilayer analytical element or a multilayer analytical element) for quantifying a specific component in a liquid sample by a dry method quickly and simply is already known. For example, JP-A-49-
No. 53888 (corresponding to US Pat. No. 3,992,158), JP-A-50-13
7192, JP 51-40191, JP 52-3488, JP 52-131786, JP 53-131089, JP 54-2970.
No. 0, JP-A-54-34298, JP-B-61-61347, US No. 4
110079, US 4132528 and other specifications and [Clini
cal Chemistry] Vol. 24, pp. 1335-1350 (1978).

Most of these are for detecting a chemical change or physical property change that is caused by reacting with a specific component in the sample by simply supplying a sample such as urine or blood onto the test device by a predetermined means. In addition, although these do not require strict sample weighing, in order to cause chemical changes and physical property changes depending on the content of specific components in the sample, the amount of sample supplied to the test device Had to be kept constant within a predetermined range.
Conventionally, a method of supplying a specimen to a test device by using a sampling device capable of accurately collecting a minute amount of sample or an excessive amount of sample after a predetermined time after supplying an arbitrary amount of sample to the test device Methods such as washing with water or removing with absorbent paper were used.

However, these methods require a high degree of specialized skill in the method of using a dedicated sampling tool, and are methods suitable for a specialist to perform on a large amount of specimens. Further, in the latter method, it is necessary to strictly determine the time from the supply of the sample to the removal of the excess sample, and the operation is complicated, which causes a measurement error.

The present invention has been made in view of the above-mentioned problems of the prior art, and provides a test device which supplies an arbitrary amount of sample and does not require subsequent removal of an excessive amount of sample. To aim. In addition, the present invention is a test device that can perform an analytical test without requiring strictness in the amount of a sample so that a specific component of body fluid can be detected or quantified even by an expert or a patient himself / herself. The purpose is to provide.

[Means for Solving Problems] A gist of the present invention is to provide a carrier for a liquid component, a carrier layer, a detector layer, a developing material layer,
An absorber layer having a through hole for spotting a liquid on the spreading material layer, and the layers are surrounded by a frame so that the layers are stacked in this order so that there is substantially no gap between them. The above-mentioned test tool.

The test device for analyzing a specific component in a liquid sample (such as blood) according to the present invention detects a chemical change by reacting with a carrier and a characteristic component in a sample (body fluid such as blood). A structure having a reaction detector (layer) and a sample supplier (layer) for supplying or developing a liquid sample to the reaction detector, that is, a developer (layer), as a pre-stage of the sample supplier. , So that an appropriate amount of sample can be supplied,
An excess analyte absorber (layer) having the performance described below is provided. That is, an absorber layer having a liquid-absorbing ability to absorb an excess body fluid sample is provided as a pre-stage of sample supply or development.

And, as an absorber that absorbs the excess amount of the sample,
A material having an appropriate absorbability such as woven cloth, knitted cloth, non-woven cloth, paper or non-fibrous porous material can be used, but woven cloth or knitted cloth is particularly preferable.

In addition, these materials, in order to improve the absorption rate,
It is desirable that the surface is hydrophilized by a chemical means such as impregnation with a surfactant or a physical means such as plasma treatment, corona discharge treatment, and ultraviolet treatment.

[Operation] The operation of the present invention will be described by taking as an example the case where a blood sample is dropped on a test tool for measurement.

The test tool is a reaction detector that is provided on the carrier and that reacts with the characteristic components in the sample (blood) and detects its chemical changes. (1) High absorption of paper or cloth There are a superabsorbent reactive carrier prepared by impregnating and drying a reactive reagent solution in a reactive carrier, and a reaction detector prepared by (2) coating a polymer solution containing a reactive reagent on a plastic carrier.
Regarding the latter (2), a sample developing material for supplying a sample over a wide range is further installed on the test tool. Therefore, in the conventional test device, when a predetermined amount of blood is supplied to the test device, as shown in FIG. 3C, the blood has the high absorbency of the test device, as shown by the arrow. The test is carried out along the horizontal direction in the reactive carrier or the sample developing material layer 3 ', and also penetrates in the vertical direction through the highly absorbent reactive carrier or the sample developing material layer 3'of the test tool to test. The reaction with the reagent contained in the reactive carrier layer 2'or the reactive detector layer of the ingredient is started. At this time, the supplied blood 9 becomes spherical on the layer 3 ', as shown in the figure, and diffusion into the layer 3'does not occur rapidly. Further, even if the diffusion is started, it takes a lot of time to develop in the lateral direction, and the amount of the sample per unit area of the site where the sample amount is dropped, the reaction proceeds until it becomes constant, It causes measurement error.

On the other hand, in the present invention, as shown in FIG.
An excessive amount of the blood that has been dripped onto is absorbed by the surrounding absorber 4. That is, at least the part 5 where the blood is dropped
By providing an absorber layer 4 that absorbs excess blood in the surroundings except for the above, the amount of blood per unit area of the site 5 onto which the blood is dropped can be made constant in a very short time, and the expansion material layer 3 can be made constant. The amount diffused at a concentration and supplied to the sensing body layer 2 is made substantially constant, that is, the amount of blood contributing to the reaction in the sensing body 2 can be defined. Therefore, it is possible to promptly detect a chemical change according to the amount of the characteristic component in the sample (blood).

The material of the liquid absorber used in the test body of the present invention is, for example, a material having a liquid absorbing ability made of a material such as cotton or chemical fiber. Specifically, a nylon / polyester knitted fabric can be used. Its liquid absorption capacity is
It is capable of absorbing body fluids such as blood to some extent.

The structure of the liquid absorber used in the present invention preferably has a through hole, as described below. For example, the third
As shown in FIG. B, the position where the sample should be dropped, that is, the position of the through hole 5 can be sensed by the feel of only the finger, and thus the sample can be easily spotted. The through hole depends on the physical properties of the body fluid sample applied to the test. That is, the amount of the sample per unit area of the portion where the sample is dropped can be made constant in a very short time, and the amount of the sample contributing to the reaction in the reaction detector can be made constant as specified. It is a thing. Also, by adjusting the size of the through hole, the speed at which the liquid sample is supplied to the reaction detector can be adjusted.

Therefore, the structure of the test tool can be determined according to the ability of the reaction detector.

Next, the test device according to the present invention is shown in FIG. 1A, and the structure of the conventional test device is shown in FIG. 1B for comparison.

In the structure of the test device (FIG. 1B) according to the prior art, for example, a gelatin solution is applied onto a transparent film (transparent carrier) 1 made of polyethylene terephthalate and dried to give a reaction detection layer (blood cell filtration / reaction film). Form 2. Then, a knitted fabric is laminated thereon as a spreading member (blood spreading knit) 3 for uniformly spreading the sample.

On the other hand, in the test device structure of the present invention, as shown in FIG. 1A, a reaction detection layer (blood cell filtration / reaction) obtained by coating and drying a gelatin solution containing a reaction detection agent on the transparent carrier layer 1. Film) 2 and an excess sample absorbent material 4 composed of a knitted fabric having a through-hole 5 for laminating a film 2 thereon and a spreading member layer 3 made of a blood spreading unit and having a through hole 5 for dropping a sample.
(Blood sucking unit) is laminated. Then, the whole is surrounded by a plastic frame 6 and sandwiched. In the detection analysis, a blood sample is spotted on the recess 5 from the top of FIG. 1A. Then, an excessive amount of blood is absorbed by the absorber layer 4, but the spreader layer 3 is supplied at a constant supply amount and the detection layer 2 is supplied.
Rapidly permeates a predetermined amount, reacts with the reaction detector there, and is colored. The color development is detected from the side indicated by 7 with a light source of a predetermined wavelength, and the color density is measured.
As described above, in the test device of the present invention, since the through-hole 5 is provided at the center of the absorber layer 4, the supplied liquid sample (blood, etc.)
Are uniformly absorbed by the absorber 4 around the through-hole 5 from the surroundings. However, for example, in the structure as shown in FIG. 1B, since it is absorbed via the reagent layer or the spreading member layer (3), there is a drawback that the reaction proceeds while passing through the layer. It was something.

Next, the analytical test with the test device according to the present invention will be described with reference to specific examples, but the present invention is not limited to the following description.

[Example] Glucose oxidase, peroxidase, L-aminoantipyrine, N-ethyl-N- was added to the reaction detection layer 2.
A test device prepared by the structure shown in FIG. 1A using a gelatin containing (2-hydroxy-3-sulfopropyl) -m-toluidine as a reaction reagent and containing titanium dioxide powder dispersed therein, The following experiment was conducted on the test tool manufactured with the structure shown in FIG. 1B having the reaction detection layer manufactured with the same reagent and structure.

Blood containing glucose at concentrations of 100 mg / dl and 300 mg / dl, respectively, was calibrated using the test device of the present invention and a conventional test device. In this case, the reaction detector produces the following reaction.

Glucose + oxygen → (glucose oxidase) → gluconic acid + hydrogen peroxide (H ₂ O ₂ ) hydrogen peroxide + chromogen → (pertioxidase) → dye +
Water (H ₂ O) The dropping amount for this calibration was changed to a range of 10 to 40 μl, and the dropping amount was dropped on the test device having the above structure.
The intensity of the coloration after the minute was measured at a wavelength of 565 nm as the relative intensity of the reflected light to that before the coloration. FIG. 2 shows a graph in which the measured values are blotted against the dropped amount.

What is measured by the test tool shown in FIG. 1A is shown by a circle and a solid line, and the result measured by the test tool structure shown in FIG. 1B is shown by a black circle and it is set as a comparative example. In addition, the test result of glucose concentration blood of 100 mg / dl is shown by I, and the test result of glucose concentration blood of 300 mg / dl is shown by II.

As shown in the graph of FIG. 2, what is measured by the test device of the present invention can be detected at a substantially constant value without being affected by the dropping amount, that is, the amount of the sample, as shown by the solid line. Was revealed.

EFFECTS OF THE INVENTION The test device of the present invention is provided with an excess sample absorber so as to supply a fixed amount of body fluid, that is, a sample to the reaction detection layer. To provide a test sample that can be accurately detected even if the amount of the sample is excessive. Secondly, to provide a test device that can accurately detect the concentration of components in the sample without being restricted by the amount of the sample in a wide range. Thirdly, it provides a remarkable technical effect such as the provision of a test tool that enables even non-specialists such as patients to analyze and detect their own body fluids easily and easily.

[Brief description of drawings]

FIGS. 1A and 1B are explanatory sectional views showing a test tool of the present invention in comparison with a conventional test tool. FIG. 2 is a graph comparing the measured values of the test device of the present invention and the conventional test device. 3A, 3B and 3C are explanatory views for explaining the test device of the present invention. [Explanation of symbols of main parts] 1 ... Transparent carrier 2 ... Reaction detector layer 3 ... Sample spreading layer 4 ... Excess sample absorber 5 ... Through hole

Front page continued (72) Inventor Hiroshi Suzuki 2-44-1, Hatagaya, Shibuya-ku, Tokyo Terumo Corporation (72) Inventor Takeo Nomura 2-44-1, Hatagaya, Shibuya-ku, Tokyo Terumo Corporation (56) References JP-A-57-182648 (JP, A)

Claims (2)

[Claims] 1. A test tool for analyzing a liquid component, comprising a carrier layer, a detector layer, a developing material layer, and an absorber layer having a through hole for spotting the liquid on the developing material layer. The test tool, wherein each layer is surrounded by a frame so as to be laminated in this order so as not to have a substantial gap therebetween. 2. The test tool according to claim 1, wherein the absorbent layer is made of a hydrophilically treated woven fabric, knitted fabric, non-woven fabric, paper or non-fiber porous material.