JP5512787B2 - Blood component sampling system, blood component sampling method, and blood collection tube - Google Patents

Description

The present invention facilitates sampling of blood components used in testing (in the present invention, blood components include all of blood, platelets, platelet concentrate, plasma, red blood cells, white blood cells, etc.) The present invention relates to a blood component sampling system, a blood component sampling method, and a blood collection tube. In particular, the present invention relates to a sampling system, a blood component sampling method, and a blood collection tube that can be suitably used for sampling a platelet concentrate.
The blood collection tube can be suitably used in a blood analyzer, but any blood collection application can be used according to its specific form.
Hereinafter, an example of a platelet concentrate sampling system, a blood component sampling method, and a blood collection tube will be described.

FIG. 9 is a schematic diagram of a platelet concentrate sampling system 31 (also referred to as “sampling bag”) and a blood component sampling method that are currently being implemented. (A) is a sampling system, (B) is a segment tube, (C) is the figure which is transferring the platelet concentrate from a segment tube to a test tube.
<1> A platelet concentrate is collected from the first tube 34 into the bag body 32 (capacity: 800 ml / also referred to as “platelet storage bag”).
<2> The platelet concentrate is collected from the bag body 32 into the child bag 33 from the second tube 35.
<3> A part (also referred to as “segment tube”) of the second tube 35 filled with the platelet concentrate is cut with a tube sealer (not shown).
<4> Open the lower end of the segment tube with a cutter or the like, transfer the platelet concentrate to the test tube (36) from the opening, and perform a blood test with a blood tester.
<1> to <3> can be aseptically operated in a closed system, so it is carried out in a hygiene area. <4> is a method that spills or scatters platelet concentrate when transferring platelet concentrate to a test tube. This is done in exposed areas.

In Patent Document 1, a sample container (200, 250) is connected to a blood collection bag (84) via a tube (204), and blood (blood components) collected in the sample container (200, 250) is bacteria. An invention that describes use for detection is disclosed.
After taking a blood sample in the sample container (200, 250), the tube (204) is sealed at two locations and cut between these seals to separate it from the blood collection bag (84).
The sample container (200) described in FIG. 2 of Patent Document 1 is lightly squeezed (squeezed) to fill this valve [sample container (200)] with approximately 1.5 mL to 4 mL of platelet condensate.

  The sample container (250) described in FIG. 3 of Patent Document 1 is formed in a bag shape, and the bag is filled with a selected amount of platelet condensate from 1.5 ml to 4 ml from the product bag 84 by gravity drop (flow). Satisfies by opening line 204 or the fragile connector (not shown) of the clamp.

  In Patent Document 2, a blood collection tube with a blood collection needle attached to the tip is connected to the upper end of the bag-shaped bag body, a branching portion is arranged in the middle of the blood collection tube, and a penetration needle is connected to the tip of the branching portion. A needle holder in which a branched blood collection tube is attached and a groove for attaching a vacuum blood collection tube (test tube) is formed on the outer periphery of the penetrating needle or a blood collection tube (test tube) attachment groove at the end of the branched blood collection tube An invention of a blood collection bag is described in which a needle holder having a shape is connected.

  Patent Document 3 (4) discloses an invention of an assembly including a package (36) and a bag system (1) for taking out a biological fluid, particularly blood, and the bag system is sterilized in the package. And the package is arranged to be opened prior to use of the bag system, the bag system comprising: a fluid removal device in communication with at least one fluid collection bag (2); and a bag system. An assembly is described that includes a sampling bag (9) that includes at least one sampling container (15) detachably coupled to sample the fluid to be collected.

Special table 2005-524445 (FIG. 2, FIG. 3, paragraph numbers [0046] to [0048]) Utility model registration No. 3013313 (FIG. 1, FIG. 3, paragraph number [0005]) Japanese Patent Application Laid-Open No. 2004-249110 (Summary Orchid, FIG. 1) JP-A-2004-249111 (Abstract orchid, FIG. 1)

The problems to be solved by the present invention are as follows.
In the invention described in FIG. 2 of Patent Document 1, since the sample container (200) is not provided with a member (for example, a mouth portion, a stopper, etc.) for collecting a blood sample, blood collected in the sample container (200). When the sample is transferred to an inspection instrument [test tube or the like], a part of the sample container (200) must be opened with a cutter or the like. For this reason, blood components may spill and blood samples cannot be collected aseptically as test tubes.
In the invention described in FIG. 3 of Patent Document 1, since blood components are collected by a gravity drop (flow) in a closed state, blood components may not be collected quickly.

In the invention described in Patent Document 2, the needle caps (8, 19) attached to the needle holder (10, 20) are once removed to expose the penetrating needles (7, 17), and then the vacuum blood collection tube is attached thereto. Since the mouth part (16a) of (16) is connected, it is not a closed system and sterility is impaired. Further, since the operation is troublesome and the operator's finger or the like may come into contact with the penetrating needles (7, 17), it is not necessarily safe.
The invention described in Patent Document 3 (4) is similar to Patent Document 2 because the sampling bag (9) further includes a hollow needle (16) for collecting a blood sample and a sampling container (15). In addition, since the operation is troublesome and the operator's finger or the like may come into contact with the hollow needle (16), it is not necessarily safe.

[1] The present invention is a blood having a bag body (2), a first tube (4) for introducing blood into the bag body (2), and a second tube (5) for introducing blood into a blood collection tube. A blood collection tube (13) attached to the component sampling system (1),
The blood collection tube (13) has a cylindrical main body (13.1) having elasticity, and a plug (13.3) having a buttocks (TU) and a trunk (BD).
The plug (13.3) is attached to one end of the main body (13.1), and the second tube connecting part (13.2) of the blood component sampling system (1) is attached to the other end. And
The main body (13.1) is crushed by applying external pressure, and the internal air is discharged in the direction of the bag main body (2). Then, the external pressure is released to return to the original shape. Negative pressure
The blood component stored in the bag body (2) is formed so as to be collected in the body (13.1) via the second tube (5),
A substantially cylindrical body (13.6) is extended at the bottom of the main body (13.1),
At the side of the substantially cylindrical body (13.6), an opening (13) through which the second tube (5) of the sampling system (1) for blood components can be drawn out of the cylindrical body (13.6). .7) is provided.
[2] The present invention is a blood having a bag body (2), a first tube (4) for introducing blood into the bag body (2), and a second tube (5) for introducing blood into a blood collection tube. A blood collection tube (23, 23A) attached to the component sampling system (1),
It has a cylindrical main body (23.1) having elasticity and a plug (23.3) having a collar (TU) and a trunk (BD), and is provided at one end of the main body (23.1). The plug body (23.3) is attached, and the second tube connection part (23.2) is attached to the side part of the main body (23.1).
The main body (23.1) is crushed by applying external pressure, and the internal air is discharged in the direction of the bag main body (2). Then, the external pressure is released to return to the original shape. The negative pressure allows the blood component stored in the bag body (2) to be collected in the body (23.1) via the second tube (5),
A mounting groove (23.6) for the second tube is formed in the lower part of the second tube connection part (23.2),
A step (23.132) is formed in the lower part of the second tube mounting groove (23.6), and the cut end of the second tube (5) is connected to the second of the step (23.132). A blood collection tube (23, 23A) formed to be able to be locked in the tube mounting groove (23.6) is provided.
[3] The present invention relates to a bag main body (2) for storing blood and a blood collection tube according to any one of [1] or [2] for collecting blood in the bag main body (2). (13, 23, 23A)
A first tube (4) having one end connected to the bag body (2) and the other end connected to a blood component storage container, and introducing blood into the bag body (2);
A second tube (5) having one end communicating with the bag body (2) and the other end communicating with the blood collection tube (13, 23, 23A), respectively, and introducing blood into the blood collection tube (13, 23, 23A). )
A blood component sampling system (1) is provided.
[4] The present invention uses the blood component sampling system (1) according to [3] having the blood collection tube (13, 23, 23A) according to [1] or [2],
<1> step of collecting blood components into the bag body (2) of the blood component sampling system (1) via the first tube (4);
<2> The main body (13.1, 23.1) of the blood collection tube (13, 23, 23A) is crushed by applying external pressure by pumping, and the internal air is discharged in the direction of the bag body (2). Thereafter, by releasing the external pressure, the negative pressure generated when trying to return to the shape of the base causes the blood components stored in the bag body (2) to pass through the second tube (5), Aseptically collecting in the body (13.1, 23.1) of the blood collection tube (13, 23, 23A);
<3> A portion of the second tube (5) close to the main body (13.1, 23.1) of the blood collection tube (13, 23, 23A) is sealed with a tube sealer, cut, and a blood analyzer The step of installing in the holder (H) of
<4> A step of puncturing the blood collection member of the blood analyzer into the plug (13.3, 23.3) of the blood collection tube (13, 23, 23A) to measure blood components;
A blood component sampling method comprising the above steps is provided.

<1> When the blood collection tube 13 is placed in the holder H of the blood analyzer, the second tube 5 is not provided in the lower portion of the main body 13.1 (substantially cylindrical body 13.6), and the second tube 5 is substantially Since it is stored in the space S in the cylindrical body 13.6, the stability when placed in the holder H is good.
<2> When the blood collection tube (23, 23A) is disposed in the holder H of the blood analyzer, the second tube 5 is not provided at the lower portion of the main body 23.1, and the second tube 5 is provided on the side of the main body 23.1. Are mounted in the mounting grooves 23.6 and 23.7, the stability when placed in the holder H is good.

It is the schematic of the sampling system of the blood component of this invention. It is a partially expanded perspective view which shows the reference example of a blood collection tube. It is a partially expanded perspective view which shows the other reference example of a blood collection tube. It is a partially expanded perspective view which shows the Example of the blood-collecting tube of this invention. It is a partially expanded perspective view of an example of the usage method of the blood collection tube of FIG. It is the schematic which shows the other Example of a blood collection tube, (A) is a front view, (B) is a side view, (C) is sectional drawing. It is the schematic which shows the other Example of a blood collection tube, (A) is a front view, (B) is a side view, (C) is sectional drawing. (A), (B), (C): It is the schematic which shows an example of the sampling method of the blood component by the sampling system of a blood component. (A), (B), (C): It is the schematic of the sampling system of the conventional blood component, and the sampling method of a blood component.

[Blood component sampling system 1]
As illustrated in FIG. 1, the blood component sampling system 1 of the present invention includes a bag main body 2 that stores blood components, and blood collection tubes (3, 3A, 13,. 23, 23A) (see FIGS. 2 to 7).
The bag body 2 transfers the blood components in the bag body 2 to the first tube 4 (blood component introduction tube) that introduces blood components into the bag body 2 and blood collection tubes (3, 3A, 13, 23, 23A). It has the 2nd tube 5 (blood component discharge | emission tube).

The first tube 4 has a member that has one end connected to the bag body 2 and the other end connectable to a blood component storage container or the like (not shown). The connectable member may be, for example, a “connector”, and the end of the first tube 4 is directly marketed with a tube connected to a blood component storage container or the like (not shown). The processed shape (for example, “sealing / sealing part” by welding or the like) may be used so that the aseptic connection device can be used.
The second tube 5 has one end connected to the bag body 2 and the other end connected to a blood collection tube (3, 3A, 13, 23, 23A).

[Collecting blood tubes 3, 3A, 13, 23, 23A]
The blood collection tube (3, 3A, 13, 23, 23A) includes a main body (3.1, 13.1, 23.1) having an elongated cylindrical shape and elasticity, as illustrated in FIGS. It has a plug (3.3, 13.3, 23.1) having a section (TU) and a body (BD).
The blood collection tubes (3, 3A, 13, 23) of FIGS. 2 to 6 are substantially cylindrical (3.4) at one end (upper part) of the main body (3.1, 13.1, 23.1). , 13.4, 23.4).
The substantially cylindrical body (3.4, 13.4, 23.4) has a maximum diameter in the main body (3.1, 13.1, 23.1) as illustrated in FIGS. The notch part SS is formed in two places in the part having The notch SS is formed by easily plugging the plugs (3.3, 13.3, 23.3) from the top surface, and may be formed at three or more locations.
In the blood collection tube 23A of FIG. 7, one end (upper part) [upper edge part 23.11] of the main body 23.1 has a maximum diameter.

The blood collection tubes (3, 3A, 13) shown in FIGS. 2 to 5 have a large diameter portion (lower portion) from the substantially cylindrical body (3.4, 13.4) toward the other end (lower portion) on the opposite side. 3.11, 13.11), transition portions (3.13, 13.13), and small diameter portions (3.12, 13.12) are sequentially formed.
The main body 23.1 of the blood collection tube 23 in FIG. 6 is tapered so as to taper from the substantially cylindrical body 23.4 toward the other end (lower part) on the opposite side.
The main body 23.1 of the blood collection tube 23A in FIG. 7 is formed in a tapered shape so as to taper from one end (upper portion) [upper edge portion 23.11] toward the other end portion (lower portion) on the opposite side. Has been.
The blood collection tubes (23, 23A) shown in FIGS. 6 and 7 also have a step-like transition portion (first step portion) 23.13 formed in the middle (substantially middle abdomen) of the main body 23.1, A groove 23.6 that can accommodate the welded and cut second tube 5 is formed in the length direction of the main body 23.1.

The blood collection tubes (3, 3A, 13, 23) shown in FIGS. 2 to 6 have plugs (3.3, 13.3) in the inner space of the substantially cylindrical body (3.4, 13, 4, 23.4). , 23.3) is mounted (by press-fitting).
In the blood collection tubes (3, 3A, 13) shown in FIGS. 2 to 5, the body portion BD of the plug (3.3, 13.3) is provided in the internal space of the large diameter portion (3.11, 13.11). Wearing (by press fitting).
In the blood collection tube 23A of FIG. 7, instead of the substantially cylindrical body (3.4, 13, 4, 23.4), as will be described later, the cap 23.3 is replaced with the main body 23. 1 It is made to fix to the upper part (space).
Accordingly, the plug (3.3, 13.3, 23.3) can be stably attached to the main body (3.1, 13.1, 23.1), and the blood of the blood analyzer to be described later It can sufficiently withstand the load when puncturing a sampling member (such as a needle having a sharp tip and a hollow inside).

  In the blood collection tubes (3, 3A, 13) shown in FIGS. 2 to 5, the diameter of the main body (3.1, 13.1) is increased from the upper part toward the lower part (3.4, 13, 4, 4). ), Large diameter portions (3.11, 13.11), small diameter portions (3.12, 13.12) are formed in this order, and the blood collection tubes (23, 23A) of FIGS. 1 (diameter) is tapered so as to be tapered as described above, and a groove 23.6 that can accommodate the cut second tube 5 is formed. It can be easily mounted in the mounting groove HM of the holder H of the analyzer.

The blood collection tubes (3, 13) shown in FIGS. 2, 4, and 5 are connected to the second tube connecting part (3.12, 13.12) below the small diameter part (3.12, 13.12) of the main body (3.1, 13.1). 3.2, 13.2) are formed and connected to the second tube 5.
The blood collection tube 3A of FIG. 3 forms a second tube connecting portion 3.2A on the upper side of the small diameter portion 3.12, not the lower portion of the small diameter portion 3.12 of the main body 3.1, and the second tube 5 is connected.

The blood collection tubes (23, 23A) shown in FIGS. 6 and 7 form a second tube connection part 23.2 on the side part (substantially abdomen) of the main body 23.1. The second tube connection portion 23.2 is a hole (space) formed in the wall surface of the main body 23.1 as illustrated in FIG. It is formed to reach the vicinity of the bottom of the body BD of the body 23.3.
The second tube 5 is inserted and connected to the hole (space).
In addition, the hole (space) of the second tube connection portion 23.2 communicates with the internal space of the main body 23.1 via the communication hole 23.5.

The difference between the blood collection tube 3 in FIG. 2 and the blood collection tube 3A in FIG. 3 is that the former forms a second tube connection portion 3.2 below the small diameter portion 3.12 of the main body 3.1, and a second tube 5 is connected to the second tube connecting portion 3.2A on the upper side of the small-diameter portion 3.12, and the second tube 5 is connected thereto. Are substantially the same.
In the illustration of the blood collection tube 3A in FIG. 3, the position where the second tube connection portion 3.2A is formed is described at the upper portion of the small diameter portion 3.12 (near the transition portion 3.13). It is not limited to. Any region may be used as long as it is within the region of the large-diameter portion 3.12 or from the substantially middle portion of the small-diameter portion 3.12.

When the second tube connection part 3.2 is formed (arranged) in the lower part of the main body 3.1 (small diameter part 3.12) like the blood collection tube 3, the second tube (5) is cut, and then the second tube connection part 3.2 is formed. If the remaining part of the tube (5) is short, there seems to be almost no problem, but if it is too long, when the blood collection tube 3 is stored in the holder H of the blood test machine as will be described later, the second tube connection part 3. There is a concern that the second tube 5 connected to 2 is bulky and difficult to be accommodated in the holder H, and that the second tube 5 comes into contact with the bottom of the holder and the stability is deteriorated. Depending on the shape of the holder H, most of the holders H have a flat or round bottom, so that the structure in which the second tube 5 is in direct contact with the bottom of the holder H is Not very welcome. If possible, a structure in which the second tube 5 is attached to the side of the main body 3.1 as in the blood collection tube 3A in FIG. 3, or a lower portion of the main body 13.1, as in the blood collection tube 13 in FIG. 4 (FIG. 5). A structure in which the second tube 5 is accommodated in the internal space of the substantially cylindrical body 13.6, a groove 23.6 formed in a side portion of the main body 23.2 like the blood collection tubes 23 and 23A in FIG. 6 (FIG. 7). In (23.7), a structure in which the second tube 5 can be mounted is preferable.

  In addition, the blood collection tube 13 of FIG. 4 (FIG. 5) further includes a substantially cylindrical body 13.6 extending below the small-diameter portion 13.12 of the main body 13.1, and the length of the substantially cylindrical body 13.6. A rectangular opening 13.7 (the shape seen from the side) is formed (two places) along the length direction of the main body 13.1 on the side portion in the direction.

The opening 13.7 is formed so that the second tube 5 can be pulled out of the substantially cylindrical body 13.6 and returned to the inside again, and the shape, structure and number achieve the purpose. If possible, it is not limited to the illustrated one.
The bottom of the substantially cylindrical body 13.6 is open and formed flat.
The substantially cylindrical body 13.6 is also formed so that the second tube 5 can be drawn out of the substantially cylindrical body 13.6 and returned to the inside again, so long as the object can be achieved. It is not limited to what is illustrated.
More specifically, as shown in FIG. 5A, the second tube 5 is taken out from the opening 13.7 and cut by a tube sealer (not shown).
As shown in FIG. 5 (B), when stored in the holder H of the blood test apparatus, the remaining cut second tube 5 is accommodated in the inner space S of the substantially cylindrical body 13.6. Stabilize.
In addition, by installing the substantially cylindrical body 13.6 below the blood collection tube 13 (small diameter portion 13.12), when it is sampled by a blood analyzer to be described later, it becomes a support when it is placed in the holder H. Sex is also stable.

Further, the blood collection tube (23, 23A) of FIG. 6 (FIG. 7) further forms a second step portion 23.132 in the middle of the second tube mounting groove 23.6, and the second step portion 23.132. The end of the second tube 5 after being cut is locked in the second tube mounting groove 23.6 so that it can be mounted.
Further, a groove 23.7 for mounting the remaining end portion of the second tube 5 is formed in the lower portion of the second tube mounting groove 23.6.
As described above, the end of the second tube 5 after cutting is mounted (locked) in the second tube mounting grooves 23.6 and 23.7 as described above, thereby sampling the blood analyzer described later. At the time, the end of the second tube 5 after cutting is made not to obstruct the work.

The blood collection tubes (3, 3A, 13, 23) shown in FIGS. 2 to 6 have plugs (3.3, 13...) In the inner space of the substantially cylindrical body (3.4, 13, 4, 23.4). 3 and 23.3) are installed.
Further, in the blood collection tubes (3, 3A, 13) shown in FIGS. 2 to 5, the body portion BD of the plug (3.3, 13.3) is provided in the internal space of the large diameter portion (3.11, 13.11). 6 is attached (by press-fitting), and the body BD of the plug 23.3 is attached (by press-fitting) in the internal space above the main body 23.1 in the blood collection tube 23 of FIG.
Thus, it is considered that the plugs (3.3, 13.3, 23.3) are attached to the main body (3.1, 13.1, 23.1) with sufficient strength.

Since the main body (3.1, 13.1, 23.1) repeats pumping, the stopper (3.3, 13.3, 23.3) is attached to the main body (3.1, It is more preferable that it never deviates from 13.1, 23.1).
In the blood collection tube 23A of FIG. 7, instead of the substantially cylindrical body (3.4, 13, 4, 23.4), a cap 23.5 is used to connect the plug 23.3 to the upper part of the main body 23.1 (the space of ).

More specifically, in the blood collection tube 23A of FIG. 7, the body BD of the plug 23.3 is mounted in the internal space above the main body 23.1, and the upper edge 23.11 of the main body 23.1 is mounted. The bottom part of the flange TU of the plug body 23.3 is attached to the top surface, and the cap body 23.3 is covered with a cap 23.5 and fixed.
The groove 23.53 of the bottom wall surface 23.52 of the cap 23.5 is attached to the end of the upper edge 23.11 of the main body 23.1, and the stopper 23.3 is attached to the top wall surface 23.11 of the cap 23.5. 51, the bottom wall surface 23.52, and the upper edge 23.11 of the main body 23.1.
Thereby, the plug body 23.3 does not come off from the main body 23.1 even if the pumping of the main body 23.1 is repeated a plurality of times.
The other shape, structure, and usage of the blood collection tube 23A in FIG. 7 are substantially the same as those of the blood collection tube 23 in FIG.

The main body (3.1, 13.1, 23.1) of the blood collection tube (3, 3A, 13, 23, 23A) is crushed by applying external pressure, and the internal air is discharged in the direction of the bag body 2, Thereafter, by releasing the external pressure, the blood component stored in the bag main body 2 by the negative pressure generated when trying to return to the shape of the base passes through the second tube 5 to the main body (3.1, 13.. 1, 23.1) so that it can be collected.
The constituent material of the blood collection tube (3, 3A, 13, 23, 23A) is not particularly limited as long as it is a material having the above-mentioned performance. Among them, adhesion to the second tube, internal visibility, and pumping property In view of the above, a flexible polyvinyl chloride (20 to 80 parts by weight of a plasticizer such as DOP or TOTM with respect to 100 parts by weight of polyvinyl chloride) is preferable. Thermoplastic elastomers and synthetic resins having the same physical properties as the polyvinyl chloride can also be used.

[Operation method of blood collection tube 3 (FIG. 2)]
A description will be given along the example of FIG. Each of (A), (B), and (C) is a sanitary area (an area in a sterile room or the like where there is no opportunity to come into contact with germs in the atmosphere).
<1> Blood components are collected in the bag body 2 through the first tube 4.
<2> The main body 3.1 is crushed by applying external pressure by pumping, the internal air is discharged in the direction of the bag main body 2, and then, by releasing the external pressure, an attempt is made to return to the shape of the base. The blood component stored in the bag main body 2 is collected in the main body 3.1 through the second tube 5 by the negative pressure generated at times.
<3> At a position close to the main body 3.1, the second tube 5 is sealed with a tube welding device, cut, and placed in the holder H of the blood analyzer [see FIG. 5 (B)].
<4> A blood sampling member of a blood analyzer (such as a needle having a sharp tip and a hollow inside) is punctured into the stopper 3.3 to collect blood from the main body 3.1. The blood component is measured by the detection unit of the blood analyzer.

[Operation method of blood collection tube 3A (FIG. 3)]
Instead of the blood collection tube 3 (see FIG. 2) described in FIG. 8, the end of the second tube 5 is connected to the second tube connection portion 3.2A of the blood collection tube 3A (see FIG. 3).
As in the above <1> and <2>, blood components stored in the bag main body 2 are collected in the main body 3.1 through the second tube 5.
<3> ′ The second tube 5 is sealed with a tube welding device at a position close to the main body 3.1, cut, and placed in the holder H of the blood analyzer. In the blood collection tube 3A, the second tube 5 is not present in the lower part of the main body 3.1 (small diameter part 3.12), and the second tube 5 is present in the upper part of the main body 3.1 (small diameter part 3.12). Good stability when placed in H. As in the above <4>, blood components are measured with a blood analyzer.

[Operation Method of Blood Collection Tube 13 (FIGS. 4 and 5)]
Instead of the blood collection tube 3 described in FIG. 8, the end of the second tube 5 is connected to the second tube connection portion 13.2 of the blood collection tube 13 (see FIGS. 4 and 5).
As in the above <1> and <2>, blood components stored in the bag main body 2 are collected in the main body 13.1 through the second tube 5.
<3>'' As shown in FIG. 5 (A), the second tube 5 is pulled out from the opening 13.7, and at a position close to the main body 13.1 (substantially cylindrical body 13.6), the tube welding device. Seal with and cut.
The remaining cut second tube 5 is returned (stored) to the space S in the substantially cylindrical body 13.6 through the opening 13.7 and placed in the holder H of the blood analyzer. In the blood collection tube 13, the second tube 5 is not provided in the lower portion of the main body 13.1 (substantially cylindrical body 13.6), and the second tube 5 is accommodated in the space S in the substantially cylindrical body 13.6. Therefore, stability when placed in the holder H is good.
As in the above <4>, blood components are measured with a blood analyzer.

[Operation Method of Blood Collection Tube 23 (FIG. 6)]
Instead of the blood collection tube 3 described in FIG. 8, the end of the second tube 5 is connected to the second tube connection part 23.2 of the blood collection tube 23 (see FIG. 6).
The blood components stored in the bag main body 2 are collected in the main body 23.1 through the second tube 5 in the same manner as in the above <1> and <2>.
<3> At a position close to the main body 23.1, seal with a tube welding device and cut.
The remaining cut end portion of the second tube 5 is engaged with and attached to the second tube attachment groove 23.6 of the second step portion 23.132. Further, the remaining end of the second tube 5 is mounted in the groove 23.7 and placed in the holder H of the blood analyzer.
In the blood collection tube 23, the second tube 5 is not provided at the lower part of the main body 23.1, and the second tube 5 is mounted in the mounting grooves 23.6 and 23.7 on the side of the main body 23.1. Good stability when placed in
As in the above <4>, blood components are measured with a blood analyzer.

DESCRIPTION OF SYMBOLS 1 Sampling system of blood component 2 Bag main body 3, 3A Blood collection tube 3.1 Main body 3.11 Large diameter part 3.12 Small diameter part 3.13 Transition part 3.2, 3.2A Second tube connection part 3.3 Plug Body 3.4 Substantially cylindrical body 13 Blood collection tube 13.1 Main body 13.11 Large diameter part 13.12 Small diameter part 13.13 Transition part 13.2 Second tube connection part 13.3 Plug body 13.4 Substantially cylindrical Body 13.6 Substantially cylindrical body 13.7 Opening 23, 23A Blood collection tube 23.1 Main body 23.11 Upper edge 23.13 Transition part (first step part)
23.132 Second step portion 23.2 Second tube connection portion 23.3 Plug body 23.4 Approximate cylindrical body 23.5 Cap 23.51 Top wall surface 23.52 Bottom wall surface 23.53 Groove 23.6 Second Tube attachment groove 23.7 Second tube (end) attachment groove 4 First tube (blood component introduction tube)
5 Second tube (blood component discharge tube)
6 Blood collection needle H Holder HM (Holder) Device groove
BD (plug) body TU (plug) substantially cylindrical body S space SS notch

Claims (4)

Blood component sampling system (1) having a bag body (2), a first tube (4) for introducing blood into the bag body (2), and a second tube (5) for introducing blood into the blood collection tube A blood collection tube (13) attached to the
The blood collection tube (13) has a cylindrical main body (13.1) having elasticity, and a plug (13.3) having a buttocks (TU) and a trunk (BD).
The plug (13.3) is attached to one end of the main body (13.1), and the second tube connecting part (13.2) of the blood component sampling system (1) is attached to the other end. And
The main body (13.1) is crushed by applying external pressure, and the internal air is discharged in the direction of the bag main body (2). Then, the external pressure is released to return to the original shape. Negative pressure
The blood component stored in the bag body (2) is formed so as to be collected in the body (13.1) via the second tube (5),
A substantially cylindrical body (13.6) is extended at the bottom of the main body (13.1),
At the side of the substantially cylindrical body (13.6), an opening (13) through which the second tube (5) of the sampling system (1) for blood components can be drawn out of the cylindrical body (13.6). . 7) formed, blood collection tube (13) Blood component sampling system (1) having a bag body (2), a first tube (4) for introducing blood into the bag body (2), and a second tube (5) for introducing blood into the blood collection tube Blood collection tubes (23, 23A) attached to the
It has a cylindrical main body (23.1) having elasticity and a plug (23.3) having a collar (TU) and a trunk (BD), and is provided at one end of the main body (23.1). The plug body (23.3) is attached, and the second tube connection part (23.2) is attached to the side part of the main body (23.1).
The main body (23.1) is crushed by applying external pressure, and the internal air is discharged in the direction of the bag main body (2). Then, the external pressure is released to return to the original shape. The negative pressure allows the blood component stored in the bag body (2) to be collected in the body (23.1) via the second tube (5),
A mounting groove (23.6) for the second tube is formed in the lower part of the second tube connection part (23.2),
A step (23.132) is formed in the lower part of the second tube mounting groove (23.6), and the cut end of the second tube (5) is connected to the second of the step (23.132). A blood collection tube (23, 23A) characterized by being formed so as to be able to be locked in the tube mounting groove (23.6). The blood collection tube (13, 23, 23A) according to any one of claims 1 and 2, wherein blood is collected in a bag main body (2) for storing blood and further in the bag main body (2). And
A first tube (4) having one end connected to the bag body (2) and the other end connected to a blood component storage container, and introducing blood into the bag body (2);
A second tube (5) having one end communicating with the bag body (2) and the other end communicating with the blood collection tube (13, 23, 23A), respectively, and introducing blood into the blood collection tube (13, 23, 23A). )
A blood component sampling system (1) characterized by the above. Use of the blood component sampling system (1) according to claim 3 comprising the blood collection tube (13, 23, 23A) according to claim 1 or claim 2,
<1> step of collecting blood components into the bag body (2) of the blood component sampling system (1) via the first tube (4);
<2> The main body (13.1, 23.1) of the blood collection tube (13, 23, 23A) is crushed by applying external pressure by pumping, and the internal air is discharged in the direction of the bag body (2). Thereafter, by releasing the external pressure, the negative pressure generated when trying to return to the shape of the base causes the blood components stored in the bag body (2) to pass through the second tube (5), Aseptically collecting in the body (13.1, 23.1) of the blood collection tube (13, 23, 23A);
<3> A portion of the second tube (5) close to the main body (13.1, 23.1) of the blood collection tube (13, 23, 23A) is sealed with a tube sealer, cut, and a blood analyzer The step of installing in the holder (H) of
<4> A step of puncturing the blood collection member of the blood analyzer into the plug (13.3, 23.3) of the blood collection tube (13, 23, 23A) to measure blood components;
A blood component sampling method comprising the above steps.