KR19980079571A - Liquid Sample Collection Device - Google Patents

Abstract

The liquid collecting device of the present invention consists of a main body having passages formed between opposite ends of the main body which face each other, the passages forming a capillary fluid sample flow path. One end of the passage is opened to the end of the body portion located adjacent to the liquid sample for inflow of the liquid sample into the hole, while the passage of the passage into the body surface extends outwardly from the other end of the passage while enclosing the other end of the passage. The other end is formed to be open. The test paper imbibed into the reagent is fixed to the main body near the other end of the passage. The liquid sample introduced into the passage at the end of the body portion flows along the passage by the capillary action to the other end of the passage, and then at the other end of the passage, the sample is absorbed by the test paper. The test paper is fixed to a main body part having a plurality of fixed positions that maintain a predetermined distance from each other along the periphery of the test paper, a gap is formed between adjacent fixed positions, and the liquid sample flows along the capillary liquid sample flow path. During this time, air flows through this gap. The test paper is formed with a protrusion located on the center and an annular protrusion formed extending around the outer periphery of the test paper. The end face of the end portion of the body portion is formed with an extended groove between the outer circumferential surface of the end portion and a passage in the body portion.

Description

Liquid Sample Collection Device

FIELD OF THE INVENTION The present invention generally relates to a device for collecting a liquid sample, such as blood, and in particular, to collect a liquid sample, such as blood, to cause the liquid sample to contact a test paper to measure such as sugar content in the liquid. It relates to a device for.

A test strip (TEST STRIP) in which a measuring section for measuring a liquid sample is used is used in a method for measuring a component or property in a liquid sample, for example, blood sugar level in blood or urine. In practical use, the method contacts the liquid sample by gripping the end of the test strip.

In the case of test strips made to measure an individual's blood glucose level, a needle is used to poke an individual's finger to draw a blood sample. Then press the test strip against your finger and the blood sample will seep into the test strip. However, there are some problems in this way of allowing blood samples to adhere to the test strips. That is, such a technique must involve a person to indicate, and since the blood sample for analysis is typically small, the problem frequently arises that a blood sample is not provided correctly in the measurement part of a test strip.

U.S. Patent No. 5,100,620 discloses a CAPILLARY TUBE REAGENT FORMAT DEVICE, which is designed to collect a blood sample, which is absorbed by a test strip mounted on the device. The device consists of a transparent body in which one hole is formed in communication between opposing ends. The test strip is mounted on a shoulder that surrounds one end of the body to form a fluid flow path between the test strip and the body. An outlet passage is formed in the body to allow the fluid flow passage to communicate with the outside. In actual use, the end of the body comes into contact with the blood sample, whereby blood flows through the hole formed in the body by the capillary action and flows through the fluid flow passage. As blood flows through the fluid flow passage via the hole in the body, air in the hole and the fluid flow passage is discharged through the outlet passage. Blood entering through the fluid flow passage is absorbed by the test strip. In addition, such a device is mounted on the reader for determining the characteristics (eg, blood sugar level) of the blood sample.

Known capillary reagent type devices have several disadvantages and problems. In one aspect, the device needs to have an outlet passage formed in the body. Accordingly, the mold used to make the main body should be appropriately manufactured to form the outlet passage, which not only requires a lot of manufacturing cost but also complicates the mold. In particular, in order to prevent the phenomenon represented by over-evaporation cooling in the document, the size of the outlet passage should be made very small, so that the manufacturing cost is excessively required, and the mold is more complicated. In other words, in the conventional apparatus as described above, the arrangement of the distal ends causes the smooth flow of blood flowing through the holes in the main body. In addition, if the device is mounted on a reader that determines the desired characteristics for a sample collected on a test strip, there is a problem that the reader is contaminated or contaminated by the liquid sample on the test strip. Moreover, the device is not suitable for placement of test strips to facilitate absorption of blood samples.

As described above, there is a need for a liquid sample collection device that does not require an outlet passage for discharging air when using such a device.

There is also a need for a liquid sample collection device in which a liquid sample can be smoothly flowed from a liquid sample source into the collection device.

In addition, there is a need for a liquid sample collection device in which the measuring device is not contaminated or contaminated when measuring a component or property of a desired liquid sample.

The present invention consists of a liquid sample collecting device which can be mounted on a reading unit for measuring the characteristics of a liquid sample, the liquid sample collecting device having an adjacent liquid sample at one end and another end for accommodating the reading unit at one end thereof. And a main body portion formed with a sample storage portion for forming a hole, the main body portion having a first end portion and a second end portion facing and open to each other to form a capillary sample fluid flow path. The first end of the hole is opened to the sample receiving portion, and the second end is opened to the recess. The body portion is formed with a body surface surrounding the second end of the hole and extending outwardly from the second end. A liquid sample introduced into the hole of the first end portion by transferring a color reagent and having a test paper having a first face portion and a second face portion facing each other mounted in the recess of the body portion together with the first face portion of the test paper in contact with the body surface. This capillary action flows through the capillary liquid sample flow path to the second end of the hole and contacts the test paper.

In another aspect of the invention, the invention consists of a liquid sample collection device that is mountable on a reading unit for measuring the properties of a liquid sample, the liquid sample collection device being formed between open ends opposite each other. Holes are formed to form the capillary sample fluid flow path. One end of the hole is opened to the end of the body located adjacent to the liquid sample to introduce the liquid sample into the hole, while the other end of the hole is opened to the body surface which extends outward from the other end of the hole while enclosing the other end of the hole. Is formed. One end surface portion and an outer circumferential surface portion are formed at an end portion of the main body portion, and a groove (GROOVE) is formed at one end surface portion of the end portion of the main body portion. In order to allow the liquid sample to flow smoothly into the passage, a groove is formed between the outer peripheral surface portion of the end portion and the hole in the body. The liquid sample flowed into the hole at the end by delivering the color reagent and the test paper having the first and second face portions positioned opposite to each other are mounted on the body portion together with the first face portion of the test paper facing the body surface. Opposite the other end flows along the capillary liquid sample flow path by capillary action and contacts the test strip.

In another aspect of the invention, the invention consists of a liquid sample collection device that is mountable on a reading unit for measuring the properties of a liquid sample, the liquid sample collection device being formed between open ends opposite each other. Holes are formed to form the capillary sample fluid flow path. One end of the hole is opened to the end of the body located adjacent to the liquid sample to introduce the liquid sample into the hole, while the other end of the hole is opened to the body surface which extends outward from the other end of the hole while enclosing the other end of the hole. Is formed. The liquid sample flowed into the hole at the end portion by delivering the color reagent and the test paper having the first face portion and the second face portion positioned opposite to each other are fixed on the body portion together with the first face portion of the test paper facing the body surface. Opposite the other end flows along the capillary liquid sample flow path by capillary action and contacts the test strip. The test paper is fixed to a main body part having a plurality of fixed positions that maintain a predetermined distance from each other along the periphery of the test paper, a gap is formed between adjacent fixed positions, and the liquid sample flows along the capillary liquid sample flow path. During this time, air flows through this gap.

In another aspect of the invention, the invention consists of a liquid sample collection device that is mountable on a reading unit for measuring the properties of a liquid sample, the liquid sample collection device being formed between open ends opposite each other. Holes are formed to form the capillary sample fluid flow path. One end of the hole is opened to the end of the body located adjacent to the liquid sample to introduce the liquid sample into the hole, while the other end of the hole is opened to the body surface which extends outward from the other end of the hole while enclosing the other end of the hole. Is formed. The test strip carrying the color reagent is fixed to the main body adjacent to the other end of the hole. The test strip is provided with a projection extending in the axial direction and located at a generally central portion, the projection being aligned with the hole in the body portion, and the liquid sample introduced into the hole at the end portion is capillary liquid sample by the capillary action toward the other end of the hole. At the other end of the hole, the liquid sample contacts the protruding part of the test paper and is absorbed by the test paper.

In another aspect of the invention, the invention includes test paper for measuring the properties of a liquid sample. The test strip is formed with a blood absorption section for absorbing a liquid sample. The blood absorbent portion carries the color reagent and is formed mainly flat. The central portion of the blood absorbing portion is formed with a protrusion extending axially from the test paper plane. The test strip may be formed with an annular protrusion extending around the outer periphery of the test strip.

1 is a partial cross-sectional view of a liquid sample collection device and reading unit according to the present invention.

2 is a longitudinal sectional view of the reading unit shown in FIG.

3 is an enlarged cross-sectional view of the liquid sample collection device shown in FIG.

4 is a perspective view of a sample inlet of the liquid sample collection device.

Figure 5 is a perspective view of the sample outlet side of the liquid sample collection device of the present invention.

6 is a plan view and a side view of a sample inlet of the liquid sample collection device.

7 is an end view of the sample outlet portion side of the liquid sample collection device.

8 is a cross-sectional view of the liquid sample collection device mounted on the reading unit.

9 is a perspective view of a test paper attached to a liquid sample collection device.

FIG. 10 is a plan view of the test paper of FIG. 9 mounted on a cross section of the body portion. FIG.

FIG. 11 is a cross-sectional view taken along the line A-A of the test paper on FIG. 10, and the main body is not shown.

12 is a state diagram used in the measurement apparatus with a liquid sample collection device of the present invention.

* Explanation of symbols for the main parts of the drawings

1 reading unit 4 measuring unit

5 end portion or collector 41: light emitting portion

42: light receiving portion 43: holder

51: main body 53: test paper

Features and details of the liquid sample collection device of the present invention and the reading unit in which the liquid sample collection device is used are as follows with respect to blood sample collection for measuring blood glucose levels in blood samples. However, the liquid sample collection device and reading unit of the present invention may be used to collect liquid samples other than blood and to measure other features besides blood sugar levels.

As shown in FIG. 1, the present invention consists of a liquid sample collection device or tip (TIP) 5 and a combination of the reading unit 1. 1, generally speaking, the liquid sample collection device 5 consists of a general cylindrical body portion 51 and a test paper 53 fixed to one end surface of the body portion 51. As shown in FIG. The collecting device 5 is suitable for use to collect the liquid sample absorbed by the test paper 53. The collecting device 5 can be detachably mounted on a holder 43 at the end of the reading unit 1. The reading unit 1 is manufactured for measuring a desired characteristic of the liquid sample (for example, blood sugar level in the blood sample).

As shown in FIG. 1, the reading unit 1 is provided with a measuring unit 4 for measuring a desired characteristic of the liquid sample collected by the collecting device 5. The measuring unit 4 of the reading unit 1 consists of a light emitting unit 41 and a light receiving unit 42 that emit light. When the reading unit 1 is operated, the light emitting part 41 emits light. The collecting device 5 containing the liquid sample is mounted on the holder 43. The light emitted from the light emitting part 41 is emitted onto the test paper 53, and is reflected back to the light receiving part 42. ), And then photoelectric conversion is performed. In response to the amount of light stored, the light receiving portion 42 outputs an analog signal, and the signal is amplified. The amplified signal is converted into a digital signal by the A / D converter and input to the control means 10 so that a desired characteristic (for example, blood sugar level) is calculated according to the data stored in the operation unit.

The collecting device 5 is preferably transparent or translucent (color transparent), and is manufactured for single use. That is, the collection device is discarded after one use. The main body 51 is composed of a main body 513 and an end 52. The end 52 is formed in a general FRUSTO-conical shape. In the use of the collecting device, the end portion 52 of the main body portion 51 is in contact with the liquid sample or liquid sample, and thus the liquid sample which is in contact with the end portion and is absorbed is introduced into the end portion 52 by capillary action. The introduced liquid sample is spread throughout the test paper 53. Thus, the end 52 of the main body 51 acts as a sample inlet of the main body.

As shown in detail in FIG. 3, the main body portion 51 includes a main body 513 for supporting the collecting device 5 on the holder 43 of the reading unit 1. The main body 513 surrounds the recessed part 540 of the main body part 51 together with the bottom of the recessed part 540 constituting the end face 542 of the main body part 51. A part of the end surface 542 of the main body portion is provided with a seating paper 512 for fixing the test paper 53 to the main body portion 51. In addition, one bottom portion 511 is formed in the main body.

The main body 51 is formed with a radially annular flange 514 facing outward at the end of the main body at a position far from the end 52. The flange 514 serves as a gripping portion on which a human finger rests when the collecting device 5 is detached from the holder 43 of the reading unit 1. As a result, the collecting device 5 can be easily and firmly detached on the holder of the reading unit 1.

The concave portion 540 in the main body 513 is actually formed in dimensions and arrangement corresponding to the dimensions and arrangement of the outer surface of the holder 43 of the reading unit 1. As shown in Figs. 3 and 8, the main body 513 is preferably formed so that the inner surface of the main body surrounding the concave portion 540 slightly tapered, the tapered shape is close to the end surface 542 The main body 513 is formed to be small and have an inner diameter far from the end surface 542. By this method, even if there is a difference between the outer diameter or the arrangement of the holder 43 of the reading unit 1 and the inner diameter of the main body 513 of the collecting device 5, the collecting device 5 is connected to the reading unit 1. It can be firmly mounted on the holder 43.

In the preferred embodiment, although the bottom 511, the body 513, and the flange 514 are formed separately from each other and assembled together, they are formed as a unit. Moreover, although the ends 52 are formed in combination with the bottom 511, they may be formed separately and connected to each other.

A hole or a passage 520 having both ends open is formed to extend through the main body 5 from one end to the other end. The hole 520 forms a capillary sample fluid flow path for introducing a liquid sample or a liquid sample by capillary action from the end portion 52 of the main body 513 toward the concave portion 540. The hole 520 is actually formed perpendicular to the test paper 53. The hole 520 is opened to the sample inlet port 523 at the end portion 52 and is opened to the sample outlet port 527 near the concave portion 540 of the body 513. A cross section 542 of the body portion 51 surrounds the sample outlet port 527 and forms a body surface radially outward therefrom.

As described above, the test paper 53 is fixed to the seating portion 512 of the end face of the main body portion 51. As shown in FIGS. 9 and 10, a generally circular test strip 53 may be appropriately secured through a binder or bonding (eg, adhesive bonding). In particular, as shown in FIG. 10, the test paper 53 is fixed to the seating portion 512 of the end face of the body portion 51 in a plurality of fixed positions 534 circumferentially spaced from each other, The fixed position is disposed on the outer periphery of the test paper 53. When fixed to the body portion 51 in this manner, an outlet 544 is formed between each pair of adjacent fixing positions 534. Therefore, when the test paper 53 is fixed to the main body portion 51, a plurality of discharge papers 544 circumferentially separated from each other are formed between the end faces 542 of the main body portion 51. In this method, when a liquid sample is introduced into the passage 520 by capillary action in the actual use of the device, it is discharged through the discharge paper 544 between the test paper 53 and the end face 542 of the body portion 51. Air can be exhausted. By allowing the test paper 53 to be fixed to the body portion 51 by a binder or adhesive bonding, the test paper 53 can be supported or fixed to the body portion 51 in a stable manner, and the liquid sample can be spread relatively smoothly. For this reason, it is possible to prevent the occurrence of unnecessary gaps caused by deformation of the test paper 53 (for example, deformation such as curves, distortions, and waves).

As shown in FIG. 3, a portion of the end face 542 of the body portion 51 is recessed to form an annular gap 54 between the end face 542 and the test paper. This gap 54 causes the liquid sample to flow in a radially outward direction when the liquid sample reaches the outlet port 527 of the passage 520. By this method, the liquid sample is gradually spread by capillary action throughout the test paper 53 in a relatively quick and smooth manner.

Although the depth of the gap 54 is formed to the most appropriate dimension to perform the above-described function, a depth of 0.02 mm (average) or more, that is, a depth of 0.04 mm to 0.4 mm will be good. Within this dimension range, the above-mentioned gap 54 may effectively perform its function. In other words, the depth of the gap 54 may be constant or may be changed.

The annular specimen storage portion 55 is formed on the outer peripheral surface portion in the radial direction of the gap 54. The annular specimen storage portion 55 is formed deeper than the gap 54 while communicating with the gap 54. The specimen storage part 55 is formed in the radially inward direction of the seating place 512, in which the test paper 53 is fixed to the end surface 542 of the main body part 51. The annular sample reservoir 55 is formed to restrict the liquid sample from flowing radially outward. That is, as the liquid sample flowing through the passage 520 reaches the outlet port 527 and flows radially outward from the gap by the shape of the gap 54, the liquid sample is annular sample storage unit 55. After reaching, it is introduced into the reservoir 55, thereby preventing the liquid sample from excessively flowing radially outward beyond the reservoir 55. By this method, it is possible to prevent the liquid sample from flowing into the seating paper 512, in which the test paper 53 is fixed to the end face 542 of the body portion. In this way, the liquid sample is prevented from flowing outward in the radial direction beyond the outer periphery of the test paper via the discharge area between the sticking papers 544, in which the test paper 53 is formed of the main body 51. It is fixed to the end face. Therefore, even if an excess amount of the liquid sample is collected, it is possible to prevent the liquid sample from leaking beyond the outer periphery of the test paper. This has a significant meaning in preventing contamination of the reading unit 1 because a liquid sample is brought into contact with and buried at the end of the reading unit.

The gap is formed radially outward of the reservoir 55. In a preferred form of the invention, the spacing consists of four spherical protrusions or convex spacings that are spaced apart from each other. The gaps 56 are formed at 90 intervals to maintain a constant distance from each other. As shown in Fig. 8, this gap 56 is provided with an end face of the reading unit 1 when the collecting device 5 is mounted on the holder 4 of the reading unit 1. 53 to be isolated from. When the collecting device 5 is mounted on the holder 4 of the reading unit 1, the end face of the holder 4 is in contact with the gap 56, whereby the end face of the holder 4 is the test paper. Contact with (53) is prevented and a liquid sample is absorbed in this test paper. As shown in FIG. 8, the height in the axial direction of the spacer 56 is formed larger than the thickness of the test paper 53. The spacing 56 prevents the test paper 53 from contacting the end of the reading unit 1, as well as the portion of the liquid sample on the reading unit, which prevents the reading unit from being soiled or contaminated.

In other words, the spacer 56 acts to maintain a constant distance between the test paper 53 and the light emitting portion 41 and the light receiving portion 42 of the light measuring portion 4. As a result, the measurement caused by the error in the measurement section caused by the deviation in the optical characteristics, that is, the change in the interval between the light emitting section 41 and the light receiving section 42 of the test paper 53 and the light measuring section 4. Negative error is minimized. This will improve the measurement.

As shown in FIGS. 3 to 5, one end of the end portion 52 of the main body portion 51 forms a sample inlet end portion 521, while the end portion 52 of the main body portion 51 is formed. The other end of) will form the sample outlet end 525. The open end face (or outer end face) of the sample inlet end 521 is formed of a groove 522. The groove 522 extends perpendicular to the axis of the passage 520 and also extends between the outer circumferential surface of the end portion 52 and the passage 52.

The groove 522 is formed to allow the liquid sample to smoothly flow into the passage 520. In order to collect the blood sample cited as an example, as shown in FIG. 12, the end face of the sample inlet end 521 formed at the end 52 of the main body 51 is on the same side as the human finger. When in contact, the groove 522 prevents the passage 520 from clogging in the absence of the groove 522. Accordingly, the supply of blood or another liquid sample flowing through the passage and into the test paper 53 is smoothly performed.

As shown in FIG. 6, the total outer circumferential length of the groove 522 with respect to the passage 520 is L ₁ , and the inner diameter of the passage 52 (the inner diameter near the sample inlet port 523) is d ₁ . In other words, the outer circumferential length L ₁ and the outer circumferential length 2d ₁ of the passage 520 satisfactorily satisfy the following expression (I).

L ₁ 2d ₁ × 50% (Ⅰ)

In order to satisfy the above-described expression, by forming the groove 522 and the passage 520, the suction initiation of the specimen (i.e., the initiation of the sample into the passage 520 by capillary action) can be performed quickly and smoothly. Can be.

The depth P ₁ of the groove 522 is preferably chosen based on the skin state, for example. Depth P ₁ is typically at least 0.1 mm, preferably between 0.2 mm and 1.8 mm. If the depth P ₁ is too small (ie, the groove 522 is too shallow), if the pressure on the skin is too large, the transfer or movement of the specimen, such as blood through the groove 522, may be insufficient. .

The shape, number, location and other characteristics associated with the groove 522 are not limited to those shown in the figures. If the purpose of the collection device is not to limit the contact of the end face of the sample inlet end 521 of the end 52 formed in the body portion 51 to obtain a sample or specimen, the described configuration will There may be changes. For example, the plurality of grooves 522 may be formed radially (eg, cross-shaped) around the sample inlet port 523 of the passage 520, or formed side by side in the passage 520. Can be.

As shown in Figs. 3 and 8, a protrusion is formed at the sample outlet end 525 of the end 52 formed in the main body 51, and the protrusion is formed near the gap 54. Compared with the hollow portion of the protruding portion 540 toward the concave portion 540 of the main body portion with a slight distance in the axial direction. As a result, the gap 54 is bound to the radially inner end of the gap. As shown in Figs. 3 and 8, the test paper 53 is in contact with the end face of this protrusion. A radially extended groove 526 is formed in the end face of this protrusion to allow passage 520 and gap 54 to communicate. Accordingly, both ends of the groove 526 are opened to the gap 54.

By the groove 526, the liquid sample flowing through the passage 520 can spread outwardly from the sample outlet port 527 through the groove 526. This causes the specimen to spread outwards throughout the test strip 53. As a result, the liquid sample spreads quickly and relatively uniformly, and the characteristic to be measured is accurately measured.

With reference to FIG. 7, the length of the outer circumference of the groove 526 boundary with respect to the passage 520 is assumed to be L ₂ , and the inner diameter of the passage 520 (the inner diameter near the sample outlet port 527) is d ₂ . In other words, the outer circumferential length L ₂ and the total inner diameter 2d ₂ of the passage 520 satisfactorily satisfy the following expression (II).

L ₂ 2d ₂ × 50% (Ⅱ)

By forming the grooves 526 and the passages 520 in accordance with the above expression, the dispersion and spread of the liquid sample flowing out of the sample outlet port 527 is quick and smooth.

The shape and arrangement of the grooves 526 is not limited to FIGS. 3, 7 and 8. For example, a plurality of grooves 526 extending radially around the sample outlet port 527 of the passage 520 or along the passage 520 may be formed.

As shown in FIG. 12, in actual use of the present invention, the end portion 52 of the blood collection device is disposed near a liquid sample to be collected (eg, blood collected from an individual's finger), and The liquid sample is then introduced into the passage 520 by capillary action and supplied to the test paper 53. The (average) inner diameter of the passage 520 is about 0.2 mm-2.0 mm, preferably about 0.5 mm-1.0 mm. If the inner diameter of the passage 520 is too large, it is difficult to move the liquid sample by capillary action. If the inner diameter of the passage 520 is too small, the speed of the liquid sample flowing through the passage 520 becomes too slow, and an excessive amount of time is required to supply a sufficient amount of blood to the test paper 53.

The inner diameter or cross sectional area of the passage 520 may be constant along the length of the passage 520, and may vary. The total length of the passage 520 between the two open ends corresponding to each other is preferably in the range of about 1 mm-5 mm, and even more preferably in the range of about 2 mm-4 mm.

The body portion 51 consisting of the end portion 52 and the body 513 is formed of a rigid body having a certain strength. The rigid body is acrylic resin, polystyrene, polyethylene, polypropylene, strong polyvinylidene chloride, polycarbonate, poly methyl methacrylate, ABC resin, polyester, polyphenylene sulfide (PPS), polyamide, polyimide, polyacetal, Polymer alloys, or polymer bends or the like, and contain at least one or more of the above materials and the like. Among these substances, those found to be particularly suitable for the rapid influx and spread of liquid specimens are hydrophilic substances such as acrylic resins or substances which are treated as hydrophilic.

Hydrophilic treatment is carried out by physical treatments such as plasma treatment, glow discharge, corona discharge, ultraviolet radiation and the like, by adding a surfactant, water soluble silicone, hydroxypropyl cellulose, polyethylene glycol, polypropylene glycol or the like. (Coating) is processed.

The test paper 53 carries a reagent (color reagent) by absorbing it into a carrier (CARRIER) capable of absorbing a sample. The carrier consists of a porous film or porous material sheet capable of absorbing a liquid sample. For example, non-woven fabrics, woven fabrics, stretched sheets, and the like. When using the present invention to collect blood samples, the porous film has a good porosity that can filter red blood cells in the blood. Have The reagent is selected according to the characteristic (s) or component (s) (eg, blood glucose level in the blood sample) of the liquid sample being measured.

Since the test paper contains a carrier made of a porous film, in such a state, the reagent reacts with oxygen in the atmosphere as a medium, such as an oxidase reaction, and the sample is covered by the sample so that the sample is covered by the sample. Even after spreading, the reaction proceeds rapidly because oxygen in the atmosphere is supplied from the detection side. Since the porous film has a porosity capable of filtering red blood cells in the blood, the color state can be detected without removing the sample or the filtered component (such as red blood cells).

Even if the material formed of the porous film consists of a material of polyester group, polyamide group, polysulfone, cellulose and the like, the material is impregnated with the aqueous solution in which the reagent is dissolved or the blood cell associated with the measurement Because of the filtering, the material having hydrophilicity or the hydrophilic treated material becomes good. The hydrophilic treatment is performed by the method described above in connection with the body portion.

When a liquid sample collection device is used to collect blood samples, reagents that are permeated into the porous film to measure, for example, blood glucose levels, are glucose oxidase (GOD), peroxidase (POD) and 4 Color chemicals (color reagents) such as -amino aminoantipyrine, N-ethyl N- (2-hydroxy-3-sulfopropyl) -m-toluidine. Incidentally, it includes a substance that reacts with blood components such as ascorbate oxidase, alcohol oxidase, cholesterol oxidase and the like, and the colorant (color reagent) according to the measurement component. Moreover, the reagents may include phosphoric acid (PHOSPHATE) buffers and buffers. The form and components of the reagents are not limited to those described above.

As shown in more detail in FIGS. 8-11, the present invention may also include special configurations and arrangements of test papers 53. The shape of test paper 53 is preferably circular, but is oval, square, rectangular. , Diamond, hexagon, octagon and the like may be used.

In the case of the circular test paper 53, the outer diameter of the test paper 53 is preferably about 2 mm-10 mm, but more preferably about 4 mm-7 mm. The thickness of the test paper 53 may range from about 0.02 mm to 1.0 mm, but about 0.05 mm to 0.4 mm is good.

The test paper 53 is formed with convex portions or protrusions 531 located on the center and extending in the axial direction, which protrusions 531 extend outward with respect to the plane of the test paper 53. As shown in FIGS. 3 and 8, when the test paper 53 is mounted on the end face 542 of the main body portion 51, the protrusion 531 extends or protrudes toward the passage 520. Although the extent or height of the protrusion 531 is not limited to a particular dimension, the protrusion 531 is preferably formed such that the protrusion extends or protrudes into the passage 520 (that is, the protrusion 531 is a groove ( 526 is formed to extend beyond the protrusion of the main body 51 formed), the sample outlet port 527 is formed in the protrusion 531. Accordingly, the height of the protrusion 531 is preferably about 0.02 mm-1.0 mm, and preferably about 0.05 mm-0.4 mm.

The shape and external dimension of the protrusion 531 is preferably equal to or smaller than the inner diameter of the passage 520 in the sample outlet port 527. The shape, external dimensions, and other features of the protrusion 531 are not limited to those described above, and are preferably appropriately selected according to, for example, the shape and dimensions of the passage 520 cross section.

The protrusion 531 has an advantage in that the liquid sample can be smoothly supplied to the test paper 53. That is, due to the protrusion 531, the liquid sample in the passage 520 first contacts the test paper 53 in the protrusion 531 extending into the sample outlet port 527, which is the liquid sample 53 Means that it is supplied quickly.

The test paper 53 is formed with an annular convex portion or protrusion 532 which also extends in the axial direction, which protrudes in the same direction as the protrusion 531. The annular protrusion 532 is formed radially outward on the protrusion 531 at the center and is disposed near the outer periphery of the test paper 53. As shown in FIGS. 3 and 8, when the test paper 53 is mounted on the end face 542 of the body portion 51, the end of the protrusion 532 is disposed in the sample reservoir 55. do.

The annular protrusion 532 limits the spread of the liquid sample outward on the test paper 53. As a result, excess liquid sample can be prevented from flowing out beyond the annular projection 532 toward the outer periphery of the test strip.

Although the outer diameter of the annular protrusion 532 becomes 60% -95% of the outer diameter of the test paper 53, and preferably 70% -90% of the outer diameter of the test paper 53, the outer diameter of the annular protrusion 532 is such a specific value. It is not limited to.

The width of the annular protrusion 532 is about 0.03 mm-1.0 mm, preferably in the range of about 0.05 mm-0.5 mm. The height of the annular projection 532 can be about 0.02mm-1.0mm, the range of about 0.05mm-0.4mm is good.

The shape and dimensions (eg, diameter, width, height, and the like) of the annular protrusion 532 may be appropriately selected according to further features and shapes of the body portion 51.

The hemispherical protrusions 531 and the annular protrusions 532 can be formed into protrusions (for example, by pressing a lower end of the test paper 53 using a punch), and can be formed by cutting.

As shown in Figs. 9 to 11, the outer periphery of the test paper 53 is formed with a fixing portion 533 which is used as an area in which the test paper can be fixed to the main body portion 51. The fixing portion 533 is located radially outward of the annular convex portion 532. As described above, the test paper 53 is fixed to the seating portion 512 of the main body portion 51 in the fixing portion 533 by a binder or adhesive bonding.

FIG. 12 illustrates one method in which the sample collection device of the present invention is used, namely collecting blood samples. As shown in FIG. 12, when a person's finger or another part of the human body is pierced, for example, with a needle, a small amount (eg 2-6 μl) of blood 18 flows to the surface of the skin. do.

The sample collection device 5 is mounted on the holder 43 of the light measuring section 4 of the reading device 1, and the end of the sample inlet end 521 at the end 52 of the collection device 5. The face will be close to or in contact with the skin. Blood 18 from the finger reaches the sample inlet port 523 through the groove 522 and flows along the passage 520 toward the test paper 53 by capillary action. Since the blood 18 effectively flows into the passage 520 from the open side of the groove 522, the end face of the end portion 52 of the main body portion 51 is located very close to the skin or is located in the skin. The blood does not spread excessively throughout the skin or blood is lost. The blood flowing through the passage 520 and reaching the sample outlet port 527 is in contact with the convex portion 531 of the test paper 53, where a portion of the blood is absorbed by the test paper 53, and Another portion flows radially outward through the groove 526 and along the body surface formed by the end surface 542 of the body portion 51. Blood flowing outwardly through the groove 526 reaches the gap 54, a portion of which is absorbed by the test strip 53 near the gap 526, while another part of the test strip 53 It spreads radially outward toward the outer periphery. As the blood is absorbed and spread by the test paper 53, in particular, it is absorbed near the protrusion 531, so that an additional suction force is generated, and the blood is directed to the test paper 53 and continuously supplied to the test paper 53.

Thus, by allowing the sample collection device according to the present invention to be constructed, even when the amount of blood collected as the sample or the sample is relatively small, the blood can be supplied to the test paper without waste. On the other hand, when the amount of blood collected as a sample or a sample is so large that an excessive amount of blood is supplied to the test paper 53, the excess blood is stored in the sample storage unit 55, and thus the outer peripheral portion of the test paper 53 Beyond this can prevent blood flow to the outside. Blood flowing outward beyond the outer periphery of the test paper 53 is prevented by the annular protrusion 532 on the test paper 53. Therefore, it is possible to prevent the blood from leaking beyond the edge of the test paper 53 and contaminating the end surface of the main body 51, so that the peripheral portion of the optical measuring unit 4 and the reading unit 1 You can prevent it from getting dirty. As a result, there is no adverse effect on the measurement result in actual use of the reading unit. Moreover, upon disposal of the sample collection device 5 after use, the risk of human infection or contamination is reduced and thus safe because there is no risk at all.

When blood spreads through the test paper 53, the target component (glucose) in the blood reacts with the reagent carried by the test paper, and the color is expressed according to the amount of the target component. By measuring the intensity of the color indicated by the method described above, a target component (eg, blood sugar level) in the blood is determined. Since red blood cells and the like in the blood are filtered and captured in the gap 54, there is no adverse effect on the color measurement shown on the test paper 53.

As described above, blood is supplied through the use of the collecting device 5 according to the present invention and quickly spreads throughout the test paper 53, so that it is reliably placed on the skin by a simple operation regardless of the amount of blood 18. Will appear. Accordingly, the measurement error may not be frequently generated and the measurement accuracy may be improved. Moreover, the collection of liquid samples or specimens is not subject to human intervention at all in terms of placing the specimen or samples on the test strip, thereby reducing or eliminating human-related errors.

The sample collection device of the present invention can be used for collecting blood samples, as well as for collecting other types of liquid samples. For example, it can be used for urine, lymph, cerebrospinal fluid, saliva and other similar fluids, or dilute and concentrated fluids.

Furthermore, the component to be measured in the sample may be an inorganic ion such as albuminoid, cholesterol, uric acid, creatinine, alcohol, sodium, hemoglobin and the like.

According to the present invention, the sample collection device and the reading unit equipped with the device collect the desired sample relatively quickly and accurately regardless of the shape and quantity of the sample, the collection location and the collection method, as well as obtain accurate measurement results. .

Moreover, the sample collection device is easy to handle, particularly with the end detachable to the reading device. Proper mounting of the sample collection device on the reading unit can be obtained easily and reliably, and in such a way is configured to prevent measurement errors and deviations in the measurement results due to improper or incorrectly mounted collection devices on the reading unit.

Moreover, it is possible to prevent the reading unit from being contaminated or dirty by sticking a portion of the specimen on the reading unit, and has a high degree of safety.

The principles, preferred embodiments and types of operation of the present invention have been described above. However, the invention to be protected is not limited to the above specific embodiment. Moreover, the embodiments described above may be for explanation rather than limitation. Various changes and modifications can be used identically and can be configured differently without departing from the spirit of the invention. Accordingly, such changes, modifications, and configurations that are within the spirit and scope of the invention will be considered to be within the scope of the invention.

Claims (30)

A liquid sample collection device that can be installed in a reading unit for measuring the characteristics of a liquid sample, the liquid sample collecting device comprising: a main portion having a concave portion for accommodating the reading unit at one end and a sample accommodating portion for disposing an adjacent liquid sample at the other end; A hole is formed in the main body to form a capillary sample fluid flow path such that a first end and a second end facing and open to each other are formed, and the first end of the hole is opened to the sample receiving part. The second end is opened to the concave part, and the main body part is formed with a main body surface which surrounds the second end of the hole and extends outwardly from the second end, and the color reagent is transferred and opposed to each other. The test paper having two surface portions is mounted in the concave portion of the main body portion together with the first surface portion of the test paper in contact with the main body surface, thereby introducing into the hole of the first end portion Liquid specimen collection device such that a fluid sample is flowing into the second end through the capillary holes the liquid sample flow path by the capillary phenomenon, which is in contact with the test strip. The liquid sample collection device according to claim 1, wherein the sample inlet has an end surface and an outer circumferential surface, and the end face of the sample inlet is formed with at least one groove extending between the outer circumferential surface of the end and the hole in the body portion. The test strip of claim 1, wherein the test strip is spaced apart along the periphery of the test strip with gaps located between adjacent fixed positions through which air can flow while the liquid sample flows along the capillary liquid sample flow path. Liquid sample collection device, characterized in that fixed to the body portion in a fixed position. The liquid sample collection device according to claim 1, wherein the test paper has a flat shape lying in a plane, and the test paper has a central portion formed with a protrusion extending from the plane extending in the axial direction. 5. The liquid sample collection device according to claim 4, wherein the protrusion extends into the hole in the main body. The test strip of claim 1, wherein the test strip has a flat shape lying in a plane, the test strip including an axially extending annular projection extending around an outer periphery of the test strip, the annular projection extending in a direction toward the body surface of the body portion. A liquid sample collection device, characterized in that it extends from the plane of the test paper. 7. The liquid sample collection device according to claim 6, wherein the body portion includes an annular sample storage portion formed on the body surface of the body portion, and the annular projection extends into the sample storage portion. 2. The apparatus according to claim 1, wherein when the collecting device is mounted on top of the reading unit once, at least it is installed radially toward the outside of the hole and extends axially away from the surface of the main body so as to leave space in the cross section of the reading unit from the test paper. A liquid sample collection device comprising at least one protrusion. A liquid sample collection device that can be installed in a reading unit for measuring the characteristics of a liquid sample, the liquid sample collecting device comprising: a main body portion provided with a hole extending between opposing ends of the main body portion and forming a capillary sample flow passage open at both ends; Open to the end of the body portion that is positioned adjacent to the liquid sample for injecting the liquid sample into the hole, the opposite end of the hole is open at the body surface of the body extending outwardly from the opposite end of the hole and the end of the body portion An end face and an outer circumferential surface, the end face of the end portion of the body portion having at least one groove extending between the outer periphery of the tip and the hole in the body portion, having first and second surfaces facing each other with color reagents; A test strip containing the test paper, and the liquid sample introduced into the hole at the The liquid sample collection device facing the first surface of the test strip the body portion surface of the base to flow along the capillary tube liquid specimen flow path so as to contact the test strip, characterized in that provided in the main body portion. 10. The test strip of claim 9 wherein the test strip is spaced apart along the periphery of the test strip having a gap located between adjacent fixed positions through which air can flow during liquid sample flow along the capillary liquid sample flow path. Liquid sample collection device, characterized in that fixed to the body portion in a fixed position. 10. The liquid sample collection device according to claim 9, wherein the test paper has a flat shape lying in a plane, and the test paper has a central portion formed with a protrusion extending from the plane extending in the axial direction. 12. The liquid sample collection device of claim 11, wherein the protrusion extends into a hole in the main body. 10. The test strip of claim 9, wherein the test strip has a flat shape lying in a plane, the test strip including an axially extending annular projection extending around an outer periphery of the test strip, the annular projection extending in a direction toward the body surface of the body portion. A liquid sample collection device, characterized in that it extends from the plane of the test paper. 14. The liquid sample collection device according to claim 13, wherein the main body portion includes an annular sample storage portion formed on the main body surface of the main body portion, and the annular projection extends into the sample storage portion. 10. The at least one projection of claim 9, wherein when the collecting device is mounted on top of the reading unit once, at least one protrusion extending radially away from the body surface and radially outwardly of the hole to leave space in the cross section of the reading unit from the test strip. Liquid sample collection device comprising a. 10. The liquid sample collection device according to claim 9, wherein the main body portion has a concave portion for receiving an end of the reading unit, and the concave portion has a bottom surface formed by a surface of the main body. A liquid sample collection device mountable on a reading unit for measuring the characteristics of a liquid sample, the liquid sample collecting device comprising: a body portion having a hole extending between opposing ends of the body portion and forming a capillary sample flow passage open at both ends, and one end of the hole Open at the end of the body portion positionable adjacent to the liquid sample for injecting the liquid sample into the hole, the opposite end of the hole being open at the body face of the body extending outwardly surrounding from the opposite end of the hole; A test paper having color reagents and having opposite first and second surfaces formed therein, wherein a liquid sample inserted into the hole at the end flows along the capillary liquid sample flow path toward the opposite end by capillary action. The first surface of the test paper is fixed to the body portion with the body surface facing the body surface, and the test paper is positioned between adjacent fixed positions through which air can flow while the liquid sample flows along the capillary liquid sample flow passage. A liquid sample collection device, characterized in that it is fixed to the body portion in a plurality of fixed positions spaced apart along the periphery of the test paper having a gap. 18. The liquid sample collection device according to claim 17, wherein the test paper has a flat shape lying in a plane, and the test paper has a central portion formed with a protrusion extending from the plane extending in the axial direction. 19. The liquid sample collection device of claim 18, wherein the protrusion extends into a hole in the body portion. 18. The test strip of claim 17, wherein the test strip has a flat shape lying in a plane, the test strip including an axially extending annular projection extending around the outer periphery of the test strip, the annular projection extending toward the body surface of the body portion. Liquid sample collection device, characterized in that extending from the plane of the test paper. 18. The liquid of claim 17, wherein an opposite end of the hole extending through the body portion is surrounded by a protrusion, wherein the protrusion is formed so that a liquid sample flows radially outward from the opposite end of the hole. Sample collector. 18. A liquid sample as claimed in claim 17, wherein an end portion of the body portion has an end surface and an outer peripheral surface, and the end surface of the end portion is formed with at least one groove extending between the outer peripheral portion of the end portion and the hole in the body portion. Collector. 18. The apparatus according to claim 17, wherein at least one of the collecting device is axially extended away from the body surface and radially outwardly of the hole so as to leave space in the cross section of the reading unit from the test strip when it is mounted on top of the reading unit once. Liquid sample collection device comprising the above projections. A liquid sample collection device mountable on a reading unit for measuring the characteristics of a liquid sample, comprising: a main body portion having a hole extending between opposing ends of the main body portion and forming a capillary sample flow passage open at both ends, and one end of the hole; The part is open at the end of the body portion which is located adjacent to the liquid sample for injecting the liquid sample into the hole, the opposite end of the hole is open at the body face of the body extending and surrounding outward from the opposite end of the hole, A test paper having a reagent, the test paper having a protrusion extending in the axial direction, and a liquid sample inserted into the hole at the end of the test paper by a capillary action, and the opposite end of the hole where the liquid sample contacts the protrusion of the test paper and is absorbed into the test paper. The projections of the test strips flow along the capillary sample flow path toward the And a test paper is fixed to the body surface of the body portion in parallel with a hole in the body portion. 25. The liquid sample collection device according to claim 24, wherein the axially extending protrusion extends into a hole in the body portion. 25. The liquid sample collection device of claim 24, wherein the test strip includes an axially extending annular projection extending around an outer periphery of the test paper, wherein the annular projection extends toward the body surface of the body portion. 25. The test piece of claim 24 wherein the test strip is spaced apart along the periphery of the test strip with gaps located between adjacent fixed locations through which air can flow while the liquid sample flows along the capillary liquid sample flow path. Liquid sample collection device, characterized in that fixed to the body portion in position. 25. A liquid sample collection device according to claim 24, wherein the end of the body portion has an end surface and an outer circumferential surface, and the end surface of the end portion is formed with at least one groove extending between an outer periphery of the end portion and a hole in the body portion. . A test strip for enabling measurement of liquid sample characteristics, the test strip comprising a blood absorbing portion for absorbing a liquid sample, the blood absorbing portion having a color reagent, the blood absorbing portion being formed in a flat shape lying on a plane having a central portion, And a protruding portion extending in the axial direction extending from the plane at the center of the blood absorbing portion. 30. The test strip of claim 29, wherein the test strip includes an axially extending annular projection extending around an outer periphery of the test strip, the annular projection extending from a plane of the test strip and the annular projection being positioned at the center of the test strip. Test strips positioned radially outwardly in the direction of extension of the projections.