JP2021092567A - Specimen sampling tool, manufacturing method of specimen sampling tool, and measuring system - Google Patents

Abstract

To provide a specimen sampling tool capable of surely sampling a specimen.SOLUTION: A specimen sampling tool includes a main body portion having an inner space portion for transferring a liquid specimen to the inside by a capillary phenomenon, the main body portion includes a plate-like portion formed in plate shape and a protruding portion that protrudes in a thickness direction of the plate-like portion from a first surface of the plate-like portion, and the inner space portion has a sampling port opened to the outside of the main body portion for sampling the specimen at a tip end of the protruding portion.SELECTED DRAWING: Figure 3

Description

This application relates to a sample collection tool, a method for manufacturing a sample collection tool, and a measurement system.

Conventionally, for example, a sample collecting tool is provided with a plate-shaped portion formed in a plate shape, and the plate-shaped portion is provided with an inner space portion for transferring a liquid sample (for example, blood) to the inside by a capillary phenomenon. There is. The inner space portion is provided with a collection port that is opened to the outside of the plate-shaped portion for collecting a sample. The collection port is arranged on the side peripheral surface of the plate-shaped portion (for example, Patent Document 1).

By the way, as a method of collecting a sample, for example, a method of sucking a sample on the surface (for example, blood on the skin) from a collection port and collecting the sample, or a method of dropping the sample from above (for example, from a syringe or a bottle) and supplying the sample. A method of collecting a sample by sucking it from a collection port can be mentioned. However, in the sample collection tool according to Patent Document 1, when collecting a sample by the latter method, for example, when the amount of the sample supplied is too large or an operator with a low proficiency level makes an erroneous operation. In addition, the sample may drip from the sample collection tool.

Japanese Unexamined Patent Publication No. 2009-175118

Therefore, an object is to provide a sample collecting tool capable of reliably collecting a sample, a method for manufacturing the sample collecting tool, and a measurement system.

The sample collecting tool includes a main body portion having an inner space portion for transferring a liquid sample to the inside by a capillary phenomenon, and the main body portion includes a plate-shaped portion formed in a plate shape and a first surface of the plate-shaped portion. The plate-shaped portion is provided with a protrusion protruding in the thickness direction of the plate-shaped portion, and the inner space portion is provided with a collection port opened to the outside of the main body portion for collecting a sample at the tip of the protrusion. ..

Further, in the sample collection tool, the inner space portion includes a transfer portion extending in the thickness direction from the collection port inside the protrusion, a storage portion for storing a sample inside the plate-shaped portion, and the main body. The transfer portion is connected to one end of the storage portion in the thickness direction view, and the opening port is connected to one end of the storage portion in the thickness direction view. It may be configured to be connected to the other end.

Further, in the sample collection tool, the inner space portion includes a transfer portion extending in the thickness direction from the collection port inside the protrusion portion, and a storage portion for storing the sample inside the plate-shaped portion. The plate-shaped portion includes a first wall portion and a second wall portion separated in the thickness direction to form the storage portion, and the transfer portion penetrates the first wall portion to store the storage portion. The plate-shaped portion may be connected to the portion and may include a guide portion extending from the first wall portion to the second wall portion in order to guide the sample from the transfer portion to the storage portion.

Further, in the sample collecting tool, the surface of the guide portion may be smoothly continuous with the surface of the transfer portion.

Further, in the sample collecting tool, the inner space portion includes a guide hole portion extending from the transfer portion to the second wall portion inside the first wall portion and the guide portion, and the guide hole portion is a guide hole portion. It may be formed so that the opening cross-sectional area becomes smaller toward a predetermined direction.

Further, in the sample collecting tool, the first surface of the plate-shaped portion may be provided with a recess around the protruding portion.

Further, in the sample collecting tool, at least the region of the plate-shaped portion that overlaps the protruding portion in the thickness direction may be formed transparently, and the protruding portion may be formed transparently.

Further, in the sample collecting tool, the inner space portion is provided with an opening opening that is open to the outside of the main body portion, and the opening opening is a surface of the plate-shaped portion opposite to the first surface. It may be arranged on two sides.

Further, the sample collecting tool may be configured to include a columnar portion connected to the side peripheral surface of the plate-shaped portion.

Further, in the sample collecting tool, the plate-shaped portion is provided with a permeation portion for allowing at least a part of the sample in the storage portion to permeate on the second surface, which is a surface opposite to the first surface, and the columnar portion. The portion may be configured to protrude from the second surface of the plate-shaped portion in the thickness direction.

Further, the method for manufacturing the sample collection tool is the sample collection tool, and the inner space portion is connected to the transfer portion extending in the thickness direction from the collection port inside the protrusion portion and the transfer portion. A method for manufacturing a sample collecting tool, comprising a storage portion for storing a sample inside the plate-shaped portion, wherein the base member has a protrusion and a transfer opening constituting the transfer portion. The base member is prepared so that a layer member having a storage opening constituting the storage portion and a membrane member covering the storage opening are prepared, and the transfer opening and the storage opening are connected to each other. And fixing the layer member, and fixing the layer member and the film member so that the film member covers the storage opening.

Further, the measuring system includes the sample collecting tool and a measuring machine for measuring a sample collected by the sample collecting tool.

FIG. 1 is an overall perspective view of a measurement system according to an embodiment. FIG. 2 is an internal view of region II of FIG. FIG. 3 is an overall perspective view of the sample collecting tool according to the same embodiment. FIG. 4 is a perspective view of a main part of the sample collecting tool according to the same embodiment. 5A and 5B are an overall view of the sample collecting tool according to the same embodiment, where FIG. 5A is a side view and FIG. 5B is a bottom view. FIG. 6 is an enlarged view of the VI area of FIG. FIG. 7 is a cross-sectional view of a main part of lines VII-VII of FIG. FIG. 8 is an enlarged view of the VIII region of FIG. FIG. 9 is an enlarged cross-sectional view taken along line IX-IX of FIG. FIG. 10 is an enlarged cross-sectional view taken along the line XX of FIG. FIG. 11 is an enlarged view of the XI region of FIG. FIG. 12 is a cross-sectional view at the same position as in FIG. 7, showing a state in which a sample is collected. FIG. 13 is a cross-sectional view at the same position as in FIG. 9, showing a state in which a sample is collected. FIG. 14 is a diagram showing an example of a method for collecting a sample collecting tool according to the present embodiment. FIG. 15 is a diagram showing another example of a method for collecting a sample collecting tool according to the present embodiment. FIG. 16 is a diagram illustrating a method of manufacturing a sample collecting tool according to the present embodiment, and is a perspective view seen from below. FIG. 17 is a diagram illustrating a method for manufacturing a sample collecting tool according to the present embodiment, and is a perspective view seen from below. FIG. 18 is a cross-sectional view of a main part of the sample collecting tool according to another embodiment. FIG. 19 is a cross-sectional view of a main part of the sample collecting tool according to still another embodiment. FIG. 20 is a cross-sectional view of a main part of the sample collecting tool according to still another embodiment. FIG. 21 is an enlarged cross-sectional view of the XXI-XXI line of FIG. FIG. 22 is a cross-sectional view of a main part of the sample collecting tool according to still another embodiment. FIG. 23 is an enlarged view of the XXIII region of FIG. 22. FIG. 24 is an enlarged cross-sectional view taken along the line XXIV-XXIV of FIG. FIG. 25 is an enlarged cross-sectional view taken along the line XXV-XXV of FIG. 24.

Hereinafter, one embodiment of the measurement system and the sample collection tool will be described with reference to FIGS. 1 to 17. In each drawing (the same applies to FIGS. 18 to 25), the dimensional ratio of the drawings and the actual dimensional ratio do not always match, and the dimensional ratios between the drawings do not necessarily match. Absent.

As shown in FIG. 1, the measurement system 100 includes a sample collection tool 1 for collecting a sample and a measuring device 101 for measuring a sample collected by the sample collection tool 1. Then, the measuring machine 101 measures, for example, the concentration of the component in the sample.

The sample is not particularly limited as long as it is liquid, and examples thereof include body fluids such as blood, serum, plasma, saliva, and urine. The measuring component measured by the measuring device 101 is not particularly limited, and examples of the measuring component include glucose, cholesterol, free fatty acid, triglyceride, uric acid, and lactic acid.

As shown in FIGS. 1 and 2, the measuring machine 101 positions the measuring machine main body 102 having the mounting port 102a on which the sample collecting tool 1 is mounted, the measuring unit 103 for measuring the sample, and the sample collecting tool 1. It includes a position detection unit 104 for detection and a sample specified amount detection unit 105 for detecting the amount (specified amount) of the sample of the sample collection tool 1. The measuring unit 103, the position detecting unit 104, and the sample specified amount detecting unit 105 are arranged inside the measuring machine main body 102, respectively.

The configuration of the measuring unit 103 is not particularly limited, but in the present embodiment, the measuring unit 103 includes a contact unit 103a that comes into contact with the sample collecting tool 1 when measuring a sample, and the contact unit 103a has a convex shape. It is formed in the shape of a spherical surface. Further, for example, when the sample is blood and the measurement component is glucose, the measurement unit 103 includes, for example, an electrode and a processing film coated on the electrode.

Specifically, after blood is separated into blood cells and plasma by a blood cell separation membrane provided in the sample collection tool 1, only plasma that has passed through the blood cell separation membrane is transferred onto the electrode. Then, glucose in plasma is converted to hydrogen peroxide by an enzyme reaction membrane coated on the electrode, and then the amount of hydrogen peroxide is measured on the electrode. That is, the sample collection tool 1 according to the present embodiment is a sample collection tool 1 that collects a sample as a measurement sample by an electrochemical reaction.

The position detection unit 104 detects whether or not the position of the sample collection tool 1 is appropriate. The configuration of the position detection unit 104 is not particularly limited, but in the present embodiment, the position detection unit 104 includes a pair of electrodes 104a and 104a. Then, when the position of the sample collecting tool 1 with respect to the measuring machine 101 is appropriate, the pair of electrodes 104a and 104a conduct with each other.

The sample specified amount detection unit 105 detects whether or not the amount of the sample collected by the sample collection tool 1 is appropriate. The configuration of the sample specified amount detection unit 105 is not particularly limited, but in the present embodiment, the sample specified amount detection unit 105 includes a pair of electrodes 105a and 105a. Then, when the amount of the sample collected by the sample collection tool 1 is appropriate, the pair of electrodes 105a and 105a conduct with each other.

As shown in FIGS. 3 to 6, the sample collecting tool 1 is formed in a long length. The sample collection tool 1 includes a main body portion 2 and a columnar portion 3 connected to the main body portion 2. Further, the main body portion 2 includes a plate-shaped portion 4 formed in a plate shape and a protruding portion 5 protruding from the plate-shaped portion 4.

In each figure and the following description, the first direction D1 is referred to as the longitudinal direction D1 (of the main body portion 2 and the plate-shaped portion 4), and the second direction D2 orthogonal to the first direction D1 is referred to as the (main body portion 2). , The lateral direction D2 (of the plate-shaped portion 4), and the third direction D3 orthogonal to the first direction D1 and the second direction D2, respectively, is referred to as the thickness direction D3 (of the main body portion 2 and the plate-shaped portion 4). Depending on the shape of the sample collection tool 1, the first direction D1 may be the lateral direction and the second direction D2 may be the longitudinal direction.

The plate-shaped portion 4 has a first surface 4a facing the first side in the thickness direction D3 (the side in the direction of the arrow in the thickness direction D3 in each figure) and the second side in the thickness direction D3 (in the direction of the arrow in the thickness direction D3 in each figure). It is provided with a second surface 4b facing (opposite side) and a side peripheral surface 4c connecting the first surface 4a and the second surface 4b. The protruding portion 5 protrudes from the first surface 4a of the plate-shaped portion 4 in the thickness direction D3. Further, the first surface 4a of the plate-shaped portion 4 is provided with a concave recess 4d around the protruding portion 5.

The columnar portion 3 is connected to the side peripheral surface 4c of the plate-shaped portion 4. Specifically, the columnar portion 3 extends in the longitudinal direction D1 from the side peripheral surface 4c of the plate-shaped portion 4. Further, the dimension of the columnar portion 3 in the thickness direction D3 is larger than the dimension of the plate-shaped portion 4 in the thickness direction D3.

The columnar portion 3 protrudes from the first surface 4a of the plate-shaped portion 4 and also protrudes from the second surface 4b of the plate-shaped portion 4 in the thickness direction D3. As a result, the sample collection tool 1 has a step between the columnar portion 3 and the first surface 4a of the plate-shaped portion 4, and also has a step between the columnar portion 3 and the second surface 4b of the plate-shaped portion 4. There is a step between them.

Further, the main body unit 2 includes a detected unit 2a detected by the position detecting unit 104 (see FIG. 2). The configuration of the detected portion 2a is not particularly limited, but in the present embodiment, the detected portion 2a is a conductor arranged on the second surface 4b of the plate-shaped portion 4. Then, when the position of the sample collecting tool 1 with respect to the measuring machine 101 is appropriate, the detected unit 2a is connected to the pair of electrodes 104a and 104a of the position detecting unit 104, respectively, and conducts between the pair of electrodes 104a and 104a. Let me.

Further, the main body 2 includes a detection circuit 6 that constitutes a circuit to be detected by the sample specified amount detection unit 105 (see FIG. 2). The configuration of the detection circuit unit 6 is not particularly limited, but in the present embodiment, the detection circuit unit 6 includes a pair of conductive units 6a and 6a having conductivity. The conductive portion 6a includes a first terminal 6b arranged in the inner space portion 7 described later, and a second terminal 6c connected to the electrode 105a of the sample specified amount detection unit 105.

Then, when the amount of the sample collected by the sample collection tool 1 is appropriate, the pair of conductive portions 6a and 6a are electrically connected to each other between the first terminals 6b and 6b by the sample. As a result, the pair of conductive portions 6a and 6a are electrically connected, so that the detection circuit unit 6 conducts the pair of electrodes 105a and 105a of the sample specified amount detection unit 105.

The main body 2 includes an inner space 7 that transfers a sample to the inside by a capillary phenomenon. The inner space portion 7 includes a collection port 7a that is opened to the outside of the main body 2 for collecting a sample, and an opening 7b that is open to the outside of the main body 2 to cause a capillary phenomenon. The inner space portion 7 is open to the outside of the main body portion 2 only by the collection port 7a and the opening port 7b. Further, the inner space portion 7 is a concept including a surface constituting the inner space.

The collection port 7a is open in the thickness direction D3 of the plate-shaped portion 4. Specifically, the collection port 7a is arranged at the tip of the protrusion 5. As a result, the position of the collection port 7a can be easily recognized.

The opening 7b is arranged on the second surface 4b of the plate-shaped portion 4. As a result, the second surface 4b on which the opening port 7b is arranged is the surface opposite to the first surface 4a on which the collection port 7a is arranged. Therefore, it is possible to prevent the open port 7b from being mistaken for the collection port 7a.

The protruding portion 5 includes a truncated cone-shaped protruding main body portion 5a and a convex portion 5b that further protrudes from the tip of the protruding main body portion 5a in the thickness direction D3. A pair of convex portions 5b is provided. The pair of convex portions 5b, 5b are separated in the longitudinal direction D1 so as to form a gap, and are arranged so as to face each other in the longitudinal direction D1.

As a result, a gap is formed between the convex portions 5b and 5b. Therefore, for example, when the tip of the protruding portion 5 comes into contact with the patient's skin, it is possible to prevent the collection port 7a from being sealed by the skin. it can. Therefore, even when the tip of the protrusion 5, that is, the convex portion 5b is in contact with the patient's skin, blood passes through the gap between the convex portions 5b and 5b and is introduced into the collection port 7a. The number of convex portions 5b is not particularly limited.

The protruding portion 5 is formed transparently. Moreover, the plate-shaped portion 4 is transparently formed in a region that overlaps with the protruding portion 5 in the thickness direction D3. Specifically, the plate-shaped portion 4 is transparently formed except for the detected portion 2a and the detection circuit portion 6. As a result, the position of the collection port 7a can be recognized from the second surface 4b side of the plate-shaped portion 4.

Here, the configuration of the inner space portion 7 will be described with reference to FIGS. 6 to 11.

As shown in FIGS. 6 and 7, the inner space portion 7 is connected to the transfer portion 7c extending in the thickness direction D3 from the collection port 7a inside the protrusion 5 and the end portion (downstream end portion) of the transfer portion 7c. A storage portion 7d for storing a sample inside the plate-shaped portion 4 and a buffer portion 7e connected to an end portion (downstream end portion) of the storage portion 7d and capable of accommodating a sample are provided. The buffer portion 7e is provided with an opening port 7b, and the opening port 7b opens the buffer portion 7e to the outside of the main body portion 2.

The plate-shaped portion 4 includes a first wall portion 4e and a second wall portion 4f that are separated in the thickness direction D3 to form the storage portion 7d. The outer surface of the first wall portion 4e constitutes the first surface 4a of the plate-shaped portion 4, and the outer surface of the second wall portion 4f constitutes the second surface 4b of the plate-shaped portion 4. There is.

The second wall portion 4f is configured to allow a part of the sample (plasma in blood in the present embodiment) of the storage portion 7d to permeate. As a result, the plate-shaped portion 4 is provided with a permeation portion 4g (that is, a second wall portion 4f) on the second surface 4b to allow a part of the sample of the storage portion 7d to permeate. The transmission portion 4g is formed in a deformable film shape.

The configuration of the permeation portion 4g is not particularly limited, but in the present embodiment, the permeation portion 4g is a blood separation membrane that allows only plasma to permeate in order to separate blood cells and plasma from blood. That is, although not particularly limited, the sample collecting tool 1 according to the present embodiment does not include a reagent for reacting with a sample (blood) in the inner space 7.

Further, the transfer portion 7c is connected to the storage portion 7d by penetrating the first wall portion 4e of the plate-shaped portion 4. That is, the first wall portion 4e of the plate-shaped portion 4 also constitutes the terminal portion (downstream end portion) of the transfer portion 7c. By the way, since the first wall portion 4e is separated from the second wall portion 4f in the thickness direction D3, when the sample is transferred from the first wall portion 4e to the second wall portion 4f, for example, the sample due to the capillary phenomenon Transfer speed slows down.

Therefore, as shown in FIG. 8, the plate-shaped portion 4 includes a guide portion 4h extending from the first wall portion 4e to the second wall portion 4f. The surface of the guide portion 4h is smoothly continuous with the surface of the transfer portion 7c without having a step. As a result, the guide portion 4h guides the sample from the first wall portion 4e to the second wall portion 4f, so that the sample can be smoothly transferred from the transfer unit 7c to the storage unit 7d. Therefore, when the sample is transferred from the first wall portion 4e to the second wall portion 4f, it is possible to prevent the sample transfer speed from becoming slow.

Therefore, as shown in FIG. 9, the transfer unit 7c is connected to one end (upstream end) of the storage unit 7d in the thickness direction D3. The opening 7b is connected to the other end (downstream end) of the storage portion 7d in the thickness direction D3. Specifically, the other end of the storage portion 7d is connected to the buffer portion 7e having the opening portion 7b. As a result, the sample transferred from the transfer unit 7c is transferred from one end to the other end of the storage unit 7d, so that the sample can be transferred over the entire area of the storage unit 7d.

In the present embodiment, by transferring the sample to the first side in the longitudinal direction D1 (the side in the direction of the arrow in the longitudinal direction D1 in each figure), the sample can be transferred over the entire area of the storage unit 7d. That is, it is not necessary to transfer the sample to the second side of the longitudinal direction D1 (the side opposite to the arrow direction of the longitudinal direction D1 in each figure).

In addition, in the thickness direction D3 view, the dimension W1 in the lateral direction D2 (direction orthogonal to the sample transfer direction) of the storage portion 7d becomes larger toward the sample transfer direction (first side in the longitudinal direction D1). And then it gets smaller. As a result, the sample can be more reliably transferred over the entire area of the storage unit 7d. The first terminal 6b of the conductive portion 6a of the detection circuit portion 6 is arranged on the end (downstream end) side of the storage portion 7d.

Further, in the storage unit 7d, the measurement area 7h where the sample is measured is an area in contact with the measurement unit 103 (see FIG. 2). Although not particularly limited, in the present embodiment, the maximum width W1 of the measurement region 7h is the maximum value of the dimension W1 in the lateral direction D2 of the storage unit 7d.

Then, in the thickness direction D3 view, it is preferable that the distance W2 between the transfer portion 7c and the measurement region 7h is smaller than the maximum width W1 of the measurement region 7h. According to such a configuration, the amount of sample required from the transfer unit 7c to the measurement area 7h is reduced. Therefore, the amount of sample required to measure the sample can be reduced.

By the way, usually, the sample is transferred to the opening 7b by the capillary phenomenon. At this time, since the opening port 7b is separated from the storage unit 7d, a large amount of sample is required to transfer the sample to the opening port 7b.

Therefore, as shown in FIGS. 10 and 11, the buffer unit 7e includes a deterrent unit 7f that suppresses the transfer of the sample from the storage unit 7d. The restraint portion 7f is connected to the terminal portion (downstream end portion) of the storage portion 7d. In FIG. 11, the broken line indicates the boundary between the storage unit 7d and the buffer unit 7e (suppression unit 7f).

The dimension W3 of the restraint portion 7f in the thickness direction D3 is larger than the dimension W4 of the end portion of the storage portion 7d in the thickness direction D3. As a result, the inner space portion 7 is provided with a step 7 g between the restraint portion 7f and the storage portion 7d. Therefore, it is possible to prevent the sample from being transferred from the storage unit 7d to the suppression unit 7f due to the capillary phenomenon. Although not particularly limited, the dimension W3 of the restraint portion 7f is preferably 1.5 times or more of the dimension W4 of the terminal portion of the storage portion 7d with the step 7g as a boundary, and is preferably 2 times or more. Is even more preferable.

Moreover, the hydrophilicity of the restraint portion 7f is smaller than that of at least a part of the storage portion 7d. That is, the hydrophilicity of the deterrent part 7f (specifically, the average hydrophilicity of the entire deterrent part 7f) is higher than the hydrophilicity of the storage part 7d (specifically, the average hydrophilicity of the entire storage part 7d). , Is getting smaller. As a result, it is possible to further suppress the transfer of the sample to the suppression unit 7f, so that it is possible to effectively prevent the sample from being transferred from the storage unit 7d to the suppression unit 7f.

Although not particularly limited, for example, the hydrophilicity of the restraining unit 7f may be smaller than the hydrophilicity of the entire storage unit 7d. Further, for example, the hydrophilicity of the restraining unit 7f may be smaller than the hydrophilicity of the upstream region of the storage unit 7d and the same as the hydrophilicity of the downstream region of the storage unit 7d. It is preferable that the hydrophilicity of the region of the storage portion 7d that overlaps with the transfer portion 7c in the thickness direction D3 view is larger than the hydrophilicity of the restraint portion 7f.

In this way, even if the position of the opening 7b is far from the end of the storage portion 7d, the transfer of the sample can be stopped at the end of the storage portion 7d. As a result, even if the sample is transferred only by the capillary phenomenon without centrifuging, the position of the opening 7b is not constrained by the end of the storage portion 7d, so that the position of the opening 7b is designed. Can have a degree of freedom. The opening 7b communicates the deterrent portion 7f with the outside of the main body portion 2.

Next, the function of the shock absorber 7e will be described with reference to FIGS. 12 and 13.

The sample transferred by the capillary phenomenon (colored portion in FIGS. 12 and 13) fills the collection port 7a, the transfer portion 7c, and the storage portion 7d as shown in FIGS. 12 and 13. By the way, for example, the head of the sample in the transfer section 7c may cause the sample in the transfer section 7c to leak to the storage section 7d.

Therefore, the volume of the buffer portion 7e is larger than the volume of the transfer portion 7c. As a result, when the sample in the transfer unit 7c leaks to the storage unit 7d, the buffer unit 7e can accommodate the sample leaking from the storage unit 7d accordingly. As a result, even if the sample in the transfer unit 7c leaks to the storage unit 7d due to the head of the sample in the transfer unit 7c, it is possible to suppress the leakage of the sample from the opening 7b.

Further, the contact portion 103a (see FIG. 2) of the measurement unit 103 of the measuring machine 101 comes into contact with the transmission portion 4g of the plate-shaped portion 4 of the sample collection tool 1. Since the transmission portion 4g is formed in a deformable film shape, the contact portion 103a may come into contact with the transmission portion 4g, so that the transmission portion 4g may be deformed and the volume of the storage portion 7d may be reduced. .. In particular, in the present embodiment, the contact portion 103a is formed in a convex spherical shape.

Therefore, the volume of the buffer portion 7e is preferably 30% or more, and more preferably 50% or more of the volume of the storage portion 7d. As a result, when the permeation unit 4g is deformed and the volume of the storage unit 7d becomes smaller and the sample leaks from the storage unit 7d, the buffer unit 7e can accommodate the sample leaked from the storage unit 7d. it can. Therefore, it is possible to prevent the sample from leaking from the opening 7b.

Next, a method of collecting a sample by the sample collecting tool 1 will be described with reference to FIGS. 14 and 15.

First, as shown in FIG. 14, by turning the collection port 7a downward, a sample on the surface, for example, blood appearing on the skin can be sucked up from the collection port 7a and collected. The region of the plate-shaped portion 4 that overlaps the protruding portion 5 in the thickness direction D3 and the protruding portion 5 are transparently formed. As a result, the position of the collection port 7a can be easily recognized from the second surface 4b side of the plate-shaped portion 4, so that the sample can be easily collected.

The columnar portion 3 may be gripped when collecting the sample. Since the columnar portion 3 is connected to the side peripheral surface 4c of the plate-shaped portion 4, for example, by picking the columnar portion 3 with a finger and operating the columnar portion 3 so as to rotate, the direction of the collection port 7a (upward, Downward) can be easily changed. This makes it possible to facilitate, for example, the work of collecting a sample and the work of attaching the sample collecting tool 1 to the measuring machine 101 (see FIG. 1).

Further, since the collection port 7a is open in the thickness direction D3, as shown in FIG. 15, by turning the collection port 7a upward, a sample supplied by dropping from above, for example, a syringe X1 (or a bottle). Etc.), and the sample that is dropped and supplied can be sucked from the collection port 7a and collected.

At this time, even if the sample leaks from the collection port 7a, the plate-shaped portion 4 can receive the sample. Moreover, since the first surface 4a of the plate-shaped portion 4 has a recess 4d (see FIG. 3) around the protrusion 5, that is, the collection port 7a, the leaked sample can be retained in the recess 4d. .. Therefore, it is possible to prevent the sample from dripping from the sample collection tool 1. In this way, the sample can be reliably collected by any of the collection methods.

Further, since the columnar portion 3 protrudes from the second surface 4b of the plate-shaped portion 4, the sample collecting tool 1 is placed on the mounting surface X2 with the second surface 4b of the plate-shaped portion 4 facing downward. At that time, the end portion of the second surface 4b of the plate-shaped portion 4 and the columnar portion 3 are supported by the mounting surface X2. As a result, since the transmission portion 4g, which is important for measurement, is separated from the mounting surface X2, it is possible to prevent the transmission portion 4g from coming into contact with the mounting surface X2. In addition, only the columnar portion 3 may be supported by the mounting surface X2, and the entire second surface 4b of the plate-shaped portion 4 may be separated from the mounting surface X2.

Further, since the collection port 7a is provided not on the first surface 4a of the plate-shaped portion 4 but at the tip of the protruding portion 5 protruding from the first surface 4a of the plate-shaped portion 4, the area in contact with the sample is reduced. can do. Thereby, for example, it is possible to prevent the measuring machine 101 (see FIGS. 1 and 2) from being contaminated with the sample.

Next, a method for producing the sample collection tool 1 will be described with reference to FIGS. 16 and 17.

The number of members constituting the sample collecting tool 1 is not particularly limited, but the sample collecting tool 1 according to the present embodiment is composed of three members 11 to 13 as shown in FIGS. 16 and 17. The three members 11 to 13 include a base member 11 that forms most of the columnar portion 3 and the plate-shaped portion 4, a layer member 12 that forms a part of the storage portion 7d and the restraint portion 7f, and a transmission portion 4g (the first). It includes a film member 13 that constitutes the two wall portions 4f).

The material of the base member 11 is not particularly limited, but may be, for example, a synthetic resin (for example, polycarbonate). The material of the membrane member 13 is not particularly limited, but may be, for example, a synthetic resin (for example, polycarbonate) capable of permeating plasma from blood.

The surfaces forming the transfer portion 7c and the storage portion 7d of the base member 11 are subjected to the hydrophilic treatment, and the surfaces forming the storage portion 7d of the membrane member 13 are subjected to the hydrophilic treatment. Thereby, the transfer of the sample in the transfer unit 7c and the storage unit 7d can be promoted. Although not particularly limited, as the hydrophilization treatment, for example, a surfactant (for example, 29- [4- (1,1,3,3-tetramethylbutyl) phenoxy] -3,6,9,12, Coating treatment with 15,18,21,24,27-nonaoxanononacosan-1-ol, polyoxyethylene sorbitan monolaurate, polyoxyethylene lauryl ether, polyvinylpyrrolidone, etc.) can be adopted.

The base member 11 is provided with, for example, a cushioning recess 11a forming the cushioning portion 7e and a guiding protrusion 11b forming the guide portion 4h on one side surface. The cushioning recess 11a is formed in a bottomed concave shape, and includes a deterrent recess 11c that constitutes the deterrent portion 7f. Further, the base member 11 includes a protrusion 5 (not shown in FIGS. 16 and 17) protruding from the other surface, and the protrusion 5 is a transfer opening constituting the transfer portion 7c. It has 11d.

Since the guide protrusion 11b is provided on the base member 11, the guide portion is provided regardless of the position of the layer member 12 with respect to the base member 11 (for example, even if the position of the layer member 12 deviates from an appropriate position). The surface of 4h is smoothly continuous with the surface of the transfer portion 7c without any step (see FIG. 8).

Further, the protrusion amount of the guide protrusion 11b may be larger than the thickness of the layer member 12. As a result, the guide portion 4h can be reliably applied to the second wall portion 4f of the plate-shaped portion 4 constituting the storage portion 7d (see FIG. 8).

Further, the layer member 12 includes a storage opening 12a constituting the storage unit 7d and a deterrent opening 12b forming the deterrence unit 7f. The storage opening 12a and the restraining opening 12b each penetrate the layer member 12 in the thickness direction. Further, the storage opening 12a is connected to the suppression opening 12b. The material of the layer member 12 is not particularly limited, but may be, for example, a resin having adhesiveness.

Therefore, first, the base member 11, the layer member 12, and the film member 13 are prepared (preparation step). Then, since the layer member 12 becomes an adhesive layer, as shown in FIG. 16, the layer member 12 is adhered to the base member 11 to fix the base member 11 and the layer member 12 (first fixing step). ).

At this time, the transfer opening 11d of the base member 11 is connected to the storage opening 12a of the layer member 12. Moreover, the deterrent recess 11c of the base member 11 is connected to the deterrent opening 12b of the layer member 12. As a result, the restraint portion 7f is formed by the restraint opening 12b and the buffer opening 11a, and a step 7g is formed between the restraint portion 7f and the storage portion 7d. In FIG. 16, the broken line indicates the boundary between the storage opening 12a and the restraining opening 12b.

After that, as shown in FIG. 17, the film member 13 is adhered to the layer member 12, so that the layer member 12 and the film member 13 are fixed (second fixing step). As a result, the storage opening 12a and the restraining opening 12b of the layer member 12 are covered with the film member 13. In this way, the sample collection tool 1 is manufactured.

The method for producing the sample collection tool 1 is not particularly limited. For example, the sample collection tool 1 may be manufactured from one, two, or four or more members. Further, a manufacturing method may be used in which the layer members 12 do not have adhesiveness and the members 11, 12, and 13 are fixed to each other by, for example, an adhesive, or by, for example, heat welding. The manufacturing method of being fixed may be used. Further, for example, the order of fixing the base member 11 and the layer member 12 and fixing the layer member 12 and the film member 13 is not particularly limited.

From the above, the sample collecting tool 1 according to the present embodiment includes a main body portion 2 having an inner space portion 7 for transferring a liquid sample to the inside by a capillary phenomenon, and the main body portion 2 is a plate formed in a plate shape. The inner space portion 7 includes a shaped portion 4 and a protruding portion 5 protruding from the first surface 4a of the plate-shaped portion 4 in the thickness direction D3 of the plate-shaped portion 4, and the inner space portion 7 is used for collecting a sample. A sampling port 7a opened to the outside of the main body 2 is provided at the tip of the protruding portion 5.

According to such a configuration, the collection port 7a is provided at the tip of the protrusion 5. As a result, by turning the collection port 7a upward, the sample supplied by dropping from above can be sucked from the collection port 7a and collected. At this time, since the plate-shaped portion 4 receives the sample, it is possible to prevent the sample from dripping from the sample collecting tool 1. On the other hand, by turning the collection port 7a downward, the sample on the surface can be sucked up from the collection port 7a and collected.

In this way, the sample can be reliably collected by any of the collection methods. Moreover, the protruding portion 5 protrudes from the first surface 4a of the plate-shaped portion 4 in the thickness direction D3, and the collection port 7a is arranged at the tip of the protruding portion 5. As a result, the position of the collection port 7a can be easily recognized.

Further, in the sample collection tool 1 according to the present embodiment, the inner space portion 7 is a transfer portion 7c extending from the collection port 7a in the thickness direction D3 inside the protrusion 5 and the plate-shaped portion 4. A storage unit 7d for storing a sample inside and an opening 7b opened to the outside of the main body 2 are provided, and the transfer unit 7c is located at one end of the storage unit 7d in the thickness direction D3 view. The opening 7b is connected to the other end of the storage portion 7d in the thickness direction D3 view.

According to such a configuration, the transfer portion 7c extends from the collection port 7a in the thickness direction D3 inside the projecting portion 5. Then, in the thickness direction D3 view, the transfer unit 7c is connected to one end of the storage unit 7d, and the opening 7b is connected to the other end of the storage unit 7d. As a result, the sample transferred from the transfer unit is transferred from one end to the other end of the storage unit. Therefore, the sample can be transferred over the entire area of the storage unit 7d.

Further, in the sample collection tool 1 according to the present embodiment, the inner space portion 7 is a transfer portion 7c extending from the collection port 7a in the thickness direction D3 inside the protrusion 5 and a plate-shaped portion 4. A storage portion 7d for storing a sample inside is provided, and the plate-shaped portion 4 includes a first wall portion 4e and a second wall portion 4f separated in the thickness direction D3 to form the storage portion 7d. The transfer section 7c is connected to the storage section 7d by penetrating the first wall section 4e, and the plate-shaped section 4 guides the sample from the transfer section 7c to the storage section 7d. It is configured to include a guide portion 4h extending from the first wall portion 4e to the second wall portion 4f.

According to such a configuration, the guide portion 4h extends from the first wall portion 4e through which the transfer portion 7c penetrates to the second wall portion 4f. As a result, the guide unit 4h guides the sample from the first wall portion 4e to the second wall portion 4f, that is, guides the sample from the transfer unit 7c to the storage unit 7d. Therefore, the sample can be smoothly transferred from the transfer unit 7c to the storage unit 7d.

Further, in the sample collecting tool 1 according to the present embodiment, the surface of the guide unit 4h is smoothly continuous with the surface of the transfer unit 7c.

According to such a configuration, the surface of the guide portion 4h is smoothly continuous with the surface of the transfer portion 7c. As a result, the sample is guided from the transfer unit 7c to the storage unit 7d. Therefore, the sample can be transferred more smoothly from the transfer unit 7c to the storage unit 7d.

Further, in the sample collecting tool 1 according to the present embodiment, the first surface 4a of the plate-shaped portion 4 is provided with a recess 4d around the protruding portion 5.

According to such a configuration, if a sample leaks from the collection port 7a when the collection port 7a is turned upward, the leaked sample can be retained in the recess 4d. As a result, it is possible to effectively prevent the sample from dripping from the sample collection tool 1.

Further, in the sample collecting tool 1 according to the present embodiment, at least the region of the plate-shaped portion 4 that overlaps the protruding portion 5 in the thickness direction D3 is transparently formed, and the protruding portion 5 is transparent. It is a composition that is formed in.

According to such a configuration, at least the region of the plate-shaped portion 4 that overlaps the protruding portion 5 in the thickness direction D3 view and the protruding portion 5 are transparently formed. As a result, the position of the collection port 7a can be easily recognized when the sample is collected from the collection port 7a with the collection port 7a facing downward.

Further, in the sample collecting tool 1 according to the present embodiment, the inner space portion 7 includes an opening port 7b that is open to the outside of the main body portion 2, and the opening port 7b is the plate-shaped portion 4. It is configured to be arranged on the second surface 4b, which is the surface opposite to the first surface 4a.

According to such a configuration, the collection port 7a is arranged at the tip of the projecting portion 5 protruding from the first surface 4a of the plate-shaped portion 4, whereas the opening port 7b is the first of the plate-shaped portions 4. It is arranged on the second surface 4b, which is the surface opposite to the surface 4a. As a result, it is possible to prevent the open port 7b from being mistaken for the collection port 7a.

Further, the sample collecting tool 1 according to the present embodiment is configured to include a columnar portion 3 connected to the side peripheral surface 4c of the plate-shaped portion 4.

According to such a configuration, since the columnar portion 3 is connected to the side peripheral surface 4c of the plate-shaped portion 4, for example, by operating the columnar portion 3 so as to rotate, the orientation of the collection port 7a can be easily achieved. Can be changed to.

Further, in the sample collecting tool 1 according to the present embodiment, the plate-shaped portion 4 is formed on a second surface 4b, which is a surface opposite to the first surface 4a, at least a part of the sample of the storage unit 7d. The columnar portion 3 is provided with a transmission portion 4g for transmitting the above-mentioned material, and the columnar portion 3 protrudes from the second surface 4b of the plate-shaped portion 4 in the thickness direction D3.

According to such a configuration, the columnar portion 3 protrudes from the second surface 4b of the plate-shaped portion 4 in the thickness direction D3. Thereby, for example, when the sample collection tool 1 is placed on the flat mounting surface X2 with the second surface 4b of the plate-shaped portion 4 facing downward, the permeating portion 4g can be separated from the mounting surface X2. it can. Therefore, it is possible to prevent the transmission portion 4g from coming into contact with the mounting surface X2.

Further, the method for manufacturing the sample collection tool 1 according to the present embodiment is the sample collection tool 1, and the inner space portion 7 is inside the protrusion 5 from the collection port 7a to the thickness direction D3. A method for manufacturing a sample collecting tool 1, wherein the sample collecting tool 1 is provided with a transfer portion 7c extending to the above and a storage portion 7d connected to the transfer portion 7c and storing a sample inside the plate-shaped portion 4. A base member 11 having a transfer opening 11d constituting the transfer portion 7c, a layer member 12 having a storage opening 12a constituting the storage portion 7d, and a film member 13 covering the storage opening 12a. The base member 11 and the layer member 12 are fixed so that the transfer opening 11d and the storage opening 12a are connected to each other, and the membrane member 13 is the storage opening 12a. The layer member 12 and the film member 13 are fixed so as to cover the surface member 12.

The sample collection tool 1, the method for manufacturing the sample collection tool 1, and the measurement system 100 are not limited to the configuration of the above-described embodiment, and are not limited to the above-mentioned action and effect. Further, it goes without saying that the sample collection tool 1, the method for manufacturing the sample collection tool 1, and the measurement system 100 can be variously modified within a range that does not deviate from the gist of the present invention. For example, it goes without saying that one or a plurality of configurations and methods according to the following various modification examples may be arbitrarily selected and adopted for the configurations and methods according to the above-described embodiment.

(1) In the sample collecting tool 1 according to the above embodiment, the inner space portion 7 is provided with a deterrent section 7f for suppressing the transfer of the sample from the storage section 7d. However, although such a configuration is preferable, the sample collection tool 1 is not limited to such a configuration. For example, the inner space portion 7 may not be provided with the restraining portion 7f, and the opening port 7b may be connected to the terminal portion of the storage portion 7d.

(2) Further, in the sample collecting tool 1 according to the above embodiment, the transfer unit 7c is connected to the end of the storage unit 7d in the thickness direction D3. However, although such a configuration is preferable, the sample collection tool 1 is not limited to such a configuration. For example, the transfer unit 7c may be connected to a position away from the end of the storage unit 7d (for example, the central portion of the storage unit 7d) in the thickness direction D3.

(3) Further, in the sample collecting tool 1 according to the above embodiment, the plate-shaped portion 4 includes a guide portion 4h extending from the first wall portion 4e to the second wall portion 4f, and the surface of the guide portion 4h is transferred. The structure is such that it is smoothly continuous with the surface of the portion 7c. However, although such a configuration is preferable, the sample collection tool 1 is not limited to such a configuration. For example, the plate-shaped portion 4 may be configured not to include the guide portion 4h. Further, for example, the surface of the guide portion 4h may be continuous with the surface of the transfer portion 7c with a step.

(4) Further, in the sample collecting tool 1 according to the above embodiment, the plate-shaped portion 4 is formed transparently except for the detected portion 2a and the detection circuit portion 6, and the protruding portion 5 is formed transparently. It is a composition that is done. However, the sample collection tool 1 is not limited to such a configuration. For example, the plate-shaped portion 4 may be configured such that only the region that overlaps with the protruding portion 5 in the thickness direction D3 is transparently formed. Further, at least one of the plate-shaped portion 4 and the protruding portion 5 may be formed opaquely.

(5) Further, in the sample collecting tool 1 according to the above embodiment, the first surface 4a of the plate-shaped portion 4 is provided with a recess 4d around the protruding portion 5. However, although such a configuration is preferable, the sample collection tool 1 is not limited to such a configuration. For example, the first surface 4a of the plate-shaped portion 4 may be flat over the entire circumference of the protruding portion 5, that is, may not have the recess 4d.

(6) Further, in the sample collecting tool 1 according to the above embodiment, the first surface 4a of the plate-shaped portion 4 is provided with a recess 4d formed by denting around the protruding portion 5. However, the sample collection tool 1 is not limited to such a configuration. For example, as shown in FIG. 18, the plate-shaped portion 4 includes an annular convex portion 4i that projects annularly from the first surface 4a so as to surround the protruding portion 5, and the concave portion 4d is inside the annular convex portion 4i. It may be configured to be formed of.

(7) Further, in the sample collection tool 1 according to the above embodiment, the opening port 7b is arranged on the second surface 4b of the plate-shaped portion 4, that is, is arranged on the surface 4a opposite to the collection port 7a. It is a composition that is done. However, although such a configuration is preferable, the sample collection tool 1 is not limited to such a configuration. For example, the opening 7b may be arranged on the first surface 4a of the plate-shaped portion 4, that is, on the surface 4a on the same side as the collection port 7a. Further, for example, the opening 7b may be arranged on the side peripheral surface 4c of the plate-shaped portion 4.

(8) Further, the sample collecting tool 1 according to the above embodiment is provided with a columnar portion 3 connected to the side peripheral surface 4c of the plate-shaped portion 4. However, although such a configuration is preferable, the sample collection tool 1 is not limited to such a configuration. For example, the sample collection tool 1 may be configured not to have a columnar portion 3 but to be formed so as to have a plate shape as a whole.

(9) Further, in the sample collecting tool 1 according to the above embodiment, the columnar portion 3 is configured to protrude from the second surface 4b of the plate-shaped portion 4 in the thickness direction D3. However, although such a configuration is preferable, the sample collection tool 1 is not limited to such a configuration. For example, the columnar portion 3 may be smoothly continuous with the second surface 4b of the plate-shaped portion 4 in the thickness direction D3 without a step. Further, for example, the columnar portion 3 may be recessed from the second surface 4b of the plate-shaped portion 4 in the thickness direction D3.

(10) Further, in the sample collecting tool 1 according to the above embodiment, the inner space portion 7 is provided with a step 7 g between the storage portion 7d and the restraining portion 7f. However, although such a configuration is preferable, the sample collection tool 1 is not limited to such a configuration. For example, as shown in FIG. 19, the inner space portion 7 does not have a step 7g between the storage portion 7d and the restraint portion 7f, and the dimension W3 of the restraint portion 7f in the thickness direction D3 is the storage portion 7d. It may be configured that the size is gradually increased with respect to the dimension W4 in the thickness direction D3 of the end portion of the above.

(11) Further, in the sample collection tool 1 according to the above embodiment, the volume of the buffer unit 7e is larger than the volume of the transfer unit 7c. However, although such a configuration is preferable, the sample collection tool 1 is not limited to such a configuration. For example, the volume of the buffer portion 7e may be less than or equal to the volume of the transfer portion 7c.

(12) Further, in the sample collecting tool 1 according to the above embodiment, the volume of the buffer portion 7e is 30% or more of the volume of the storage portion 7d. However, although such a configuration is preferable, the sample collection tool 1 is not limited to such a configuration. For example, the volume of the buffer portion 7e may be less than 30% of the volume of the storage portion 7d.

(13) Further, in the sample collecting tool 1 according to the above embodiment, the permeation portion 4g is formed in a deformable film shape. However, the sample collection tool 1 is not limited to such a configuration. For example, the transmission portion 4g may be configured to have rigidity so as not to be deformed.

(14) Further, in the sample collecting tool 1 according to the above embodiment, the permeation unit 4g has a configuration in which a part of the sample of the storage unit 7d is permeated. However, the sample collection tool 1 is not limited to such a configuration. For example, the permeation unit 4g may be configured to permeate the entire sample of the storage unit 7d.

(15) Further, in the sample collecting tool 1 according to the above embodiment, the hydrophilicity of the restraining unit 7f is smaller than the hydrophilicity of at least a part of the storage unit 7d. However, although such a configuration is preferable, the sample collection tool 1 is not limited to such a configuration. For example, the hydrophilicity of the restraint unit 7f may be the same as the hydrophilicity of the storage unit 7d. Further, for example, the hydrophilicity of the restraint portion 7f may be larger than the hydrophilicity of the storage portion 7d.

(16) Further, in the sample collecting tool 1 according to the above embodiment, the transfer unit 7c is separated from the measurement region 7h in the thickness direction D3 view. However, the sample collection tool 1 is not limited to such a configuration. For example, as shown in FIGS. 20 and 21, it is preferable that the transfer portion 7c is connected to the measurement region 7h in the thickness direction D3 view. That is, it is preferable that the distance W2 (see FIG. 9) between the transfer unit 7c and the measurement region 7h is zero. According to such a configuration, the amount of sample required for measuring the sample can be very small.

(17) Further, in the sample collecting tool 1, as shown in FIGS. 22 to 25, the inner space portion 7 is inside the first wall portion 4e and the guide portion 4h from the transfer portion 7c. A guide hole portion 7i extending to the second wall portion 4f may be provided, and the guide hole portion 7i may be formed so that the opening cross-sectional area becomes smaller in a predetermined direction.

According to such a configuration, the guide hole portion 7i extends from the transfer portion 7c to the second wall portion 4f, and the opening cross-sectional area of the guide hole portion 7i becomes smaller in a predetermined direction. As a result, the sample is transferred by the capillary phenomenon with the inside of the guide hole portion 7i directed in a predetermined direction. Therefore, the sample can be smoothly transferred from the transfer portion 7c to the second wall portion 4f.

The plate-shaped portion 4 according to FIGS. 22 to 25 extends from the first surface 4j facing the second wall portion 4f in the thickness direction D3 and extending from the first surface 4j to the second wall portion 4f in the thickness direction D3. It is provided with a pair of second surfaces 4k and 4k facing each other in the lateral direction D2. The guide hole portion 7i is composed of a first surface 4j, a pair of second surfaces 4k and 4k, and a second wall portion 4f. The first surface 4j and the second surface 4k are arranged over the first wall portion 4e and the guide portion 4h.

The distance in the thickness direction D3 between the first surface 4j and the second wall portion 4f becomes smaller toward one side of the longitudinal direction D1 (in FIGS. 22 to 25, the arrow direction side of the longitudinal direction D1). The distance of the pair of second surfaces 4k and 4k in the lateral direction D2 is constant over the longitudinal direction D1. As a result, the opening cross-sectional area of the guide hole portion 7i becomes smaller toward one side in the longitudinal direction D1.

The opening cross-sectional area is the cross-sectional area of the inner space formed inside the guide hole portion 7i, and is a cross-section of a virtual surface orthogonal to a predetermined direction (longitudinal direction D1 in FIGS. 22 to 25). The area of the inner space. That is, in FIGS. 22 to 25, the opening of the end portion on the upstream side of the guide hole portion 7i (the other side of the longitudinal direction D1 (in FIGS. 22 to 25, the side opposite to the arrow direction of the longitudinal direction D1)) is cut off. The area is smaller than the opening cross-sectional area of the end portion on the downstream side of the transfer portion 7c (in FIGS. 22 to 25, the side opposite to the arrow direction in the thickness direction D3).

1 ... Sample collection tool, 2 ... Main body, 2a ... Detected part, 3 ... Columnar part, 4 ... Plate-shaped part, 4a ... 1st surface, 4b ... 2nd surface, 4c ... Side peripheral surface, 4d ... Recessed part, 4e ... 1st wall part, 4f ... 2nd wall part, 4g ... transmission part, 4h ... guide part, 4i ... annular convex part, 4j ... 1st surface, 4k ... 2nd surface, 5 ... protrusion part, 5a ... protrusion Main body, 5b ... Convex, 6 ... Detection circuit, 6a ... Conductive, 6b ... First terminal, 6c ... Second terminal, 7 ... Inner space, 7a ... Collection port, 7b ... Open port, 7c ... Transfer Section, 7d ... Storage section, 7e ... Buffer section, 7f ... Suppression section, 7g ... Step, 7h ... Measurement area, 7i ... Guide hole section, 11 ... Base member, 11a ... Buffer recess, 11b ... Guide protrusion, 11c ... Suppression recess, 11d ... Transfer opening, 12 ... Layer member, 12a ... Storage opening, 12b ... Suppression opening, 13 ... Membrane member, 100 ... Measuring system, 101 ... Measuring machine, 102 ... Measuring machine body, 102a ... Mounting port, 103 ... Measuring unit, 103a ... Contact part, 104 ... Position detection unit, 104a ... Electrode, 105 ... Specified sample amount detection unit, 105a ... Electrode, D1 ... Longitudinal direction, D2 ... Short direction, D3 ... Thickness Direction, X1 ... Syringe, X2 ... Mounting surface

Claims (12)

It is equipped with a main body having an inner space for transferring a liquid sample to the inside by capillarity.
The main body portion includes a plate-shaped portion formed in a plate shape and a protruding portion protruding from the first surface of the plate-shaped portion in the thickness direction of the plate-shaped portion.
The inner space portion is a sample collection tool provided with a collection port opened to the outside of the main body portion at the tip of the protruding portion for collecting a sample. The inner space portion includes a transfer portion extending in the thickness direction from the collection port inside the protruding portion, a storage portion for storing a sample inside the plate-shaped portion, and an opening open to the outside of the main body portion. With a mouth,
The transfer portion is connected to one end of the storage portion in the thickness direction.
The sample collecting tool according to claim 1, wherein the opening is connected to the other end of the storage portion in the thickness direction. The inner space portion includes a transfer portion extending in the thickness direction from the collection port inside the protruding portion, and a storage portion for storing a sample inside the plate-shaped portion.
The plate-shaped portion includes a first wall portion and a second wall portion that are separated in the thickness direction to form the storage portion.
The transfer portion is connected to the storage portion by penetrating the first wall portion.
The sample collecting tool according to claim 1 or 2, wherein the plate-shaped portion includes a guide portion extending from the first wall portion to the second wall portion in order to guide the sample from the transfer portion to the storage portion. .. The sample collecting tool according to claim 3, wherein the surface of the guide portion is smoothly continuous with the surface of the transfer portion. The inner space portion includes a guide hole portion extending from the transfer portion to the second wall portion inside the first wall portion and the guide portion.
The sample collecting tool according to claim 3 or 4, wherein the guide hole portion is formed so that the opening cross-sectional area becomes smaller in a predetermined direction. The sample collecting tool according to any one of claims 1 to 5, wherein the first surface of the plate-shaped portion is provided with a recess around the protruding portion. Of the plate-shaped portion, at least a region that overlaps the protruding portion in the thickness direction is transparently formed.
The sample collecting tool according to any one of claims 1 to 6, wherein the protruding portion is formed transparently. The inner space portion includes an opening opening that is open to the outside of the main body portion.
The sample collecting tool according to any one of claims 1 to 7, wherein the opening is arranged on a second surface of the plate-shaped portion opposite to the first surface. The sample collecting tool according to any one of claims 1 to 8, further comprising a columnar portion connected to the side peripheral surface of the plate-shaped portion. The plate-shaped portion is provided with a permeation portion that allows at least a part of the sample in the storage portion to permeate on the second surface, which is a surface opposite to the first surface.
The sample collecting tool according to claim 9, wherein the columnar portion protrudes from the second surface of the plate-shaped portion in the thickness direction. The sample collection tool according to any one of claims 1 to 10, and the inner space portion is formed in a transfer portion extending in the thickness direction from the collection port inside the protrusion portion and the transfer portion. A method for manufacturing a sample collecting tool, comprising a storage portion that is connected and stores a sample inside the plate-shaped portion.
To prepare a base member having a protrusion and a transfer opening constituting the transfer portion, a layer member having a storage opening constituting the storage portion, and a membrane member covering the storage opening. ,
Fixing the base member and the layer member so that the transfer opening and the storage opening are connected to each other.
A method for producing a sample collecting tool, comprising fixing the layer member and the membrane member so that the membrane member covers the storage opening. The sample collecting tool according to any one of claims 1 to 10, and the sample collecting tool.
A measurement system including a measuring machine for measuring a sample collected by the sample collecting tool.

Images