JP2005342198A - Capillary blood-collecting device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a safe and convenient capillary blood-collecting device which can always collect a fixed quantity of the blood, simplify a blood-collecting operation, and reduce a risk of infection. <P>SOLUTION: The capillary blood-collecting device has a cylindrical main body to suck an ingredient to be collected using a capillary phenomenon, wherein the above cylindrical main body is comprised of a high molecular material and an inner surface of the cylindrical main body is processed to be hydrophilic. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a capillary blood collection tool used for blood collection of a patient.

Conventionally, a capillary blood collection tool has been used to collect blood from a patient who cannot collect blood with a syringe. The patient who cannot collect blood from the syringe is specifically an infant or an elderly person, and there are cases where the blood volume is small or the blood vessel is thin and the needle cannot be inserted.
A conventional capillary blood collection device is composed of a glass tube. Thus, the reason why glass is used as the material for the capillary blood collection tool is that it is easy to manufacture and because glass is hydrophilic and capillarity, blood can be easily sucked into the capillary tube.

However, glass capillary blood collection devices have a problem that they are easily broken because they are made of glass, and practical workability is poor. Such a fragile blood collection tool is problematic because when the blood is broken, the collected blood scatters and there is a risk of blood infection, and there is a possibility that the patient or blood collection operator may be damaged by fragments.
In view of the above problems, an object of the present invention is to provide a capillary blood collection device that is safe and has good workability.
In addition, the above-described conventional glass capillary blood collection device is composed of a simple glass tube, and when used, a blood collection operator makes one end of the capillary blood collection device contact the blood to suck the blood by capillary action, and an appropriate amount is obtained. When the blood is sucked up, the other end of the capillary blood collection tool is pressed with a finger to complete the suction (blood collection). Then, the blood collection operator carries the capillary blood collection device to the analyzer while holding the other end of the capillary tube after blood collection with a finger, and sets the capillary blood collection device in the analysis device. If it is necessary to apply an anticoagulant action, place an iron core in the capillary tube and plug it with rubber caps at both ends so that it is uniform with the anticoagulant previously coated in the capillary tube. An operation step of moving and stirring the iron core from the outside of the capillary using a magnet is also required.
However, there is a problem in that the amount of blood collected is not stable when the amount of blood sucked into the capillary blood collection device (the amount of blood collected) is adjusted with the finger of the blood collection operator. In addition, if the timing of pressing with a finger is slow, blood may leak from the capillary blood sampling device. Further, if the capillary blood sampling device is pressed with the finger in this state, there is a problem that the finger touches the finger. Furthermore, there is a possibility that blood is leaked from the capillary blood collection tool when the blood collection operator carries the capillary blood collection device after blood collection to the analyzer, and this may stir the blood in the capillary. Sometimes it can happen. Above all, there is also a problem that forcing such a work to a blood collection worker is severe. In addition, when such a conventional capillary blood collection tool is used, it is impossible to collect blood continuously from a plurality of patients.
Another object of the present invention is to solve the above-mentioned conventional problems, to always collect a certain amount of blood, simplify the blood collection operation, and further reduce the risk of infection. It is to provide a blood collection tool.

In order to achieve the above-described object, a capillary blood sampling device according to the present invention is a capillary blood sampling device having a cylindrical main body that sucks a component to be collected using a capillary phenomenon, and the cylindrical main body is a polymer material. And the inner surface of the cylindrical main body is treated to be hydrophilic.
Preferably, a liquid sealing resin for stopping a component to be sucked in a predetermined position may be provided in the cylindrical main body.
In addition, the inner surface of at least one end of the cylindrical main body may be formed in a tapered shape that widens toward the outside.
Further, the liquid sealing resin may be made of a porous resin, or may be made of a porous resin main body provided with a water-swellable material in each hole.
If necessary, the outer shape of the cylindrical body may be formed into a polygon.

A capillary blood sampling device according to the present invention is a capillary blood sampling device having a cylindrical main body that sucks a component to be collected using a capillary phenomenon, and the cylindrical main body is made of a polymer material, and the cylindrical main body Since the inner surface of the tube is hydrophilic, it does not break like a glass capillary blood sampling device, and is safe and has good workability.
Further, by providing a liquid sealing resin for stopping the component to be sucked in a predetermined position in the cylindrical main body, it is not necessary for the blood collection operator to adjust the blood collection amount with a finger, so that a constant amount is always obtained. Blood can be collected. In addition, since the liquid sealing resin is positioned below the collected blood, it is not necessary for the blood collection operator to press the capillary blood collection tool with a finger. Of course, there is no risk of infection. Even when it is necessary to apply an anticoagulant action, an iron core can be placed in the capillary tube, and the iron core can be moved from the outside of the capillary using a magnet so as to be uniform with the anticoagulant. Furthermore, since it is not necessary to carry the capillary blood sampling device after blood collection every time blood is collected, blood can be collected from a plurality of patients continuously, and blood leaks during transfer of the blood capillary device after blood collection. Nor.
By forming the inner surface of one end of the cylindrical main body into a tapered shape that widens toward the outer side, it becomes easy to insert the liquid sealing resin into the tubular main body. In addition, it is very difficult to form the inner surface of one end of the cylindrical body in this manner with a glass capillary blood sampling device, but the capillary blood sampling device according to the present invention is made of a polymer material. Therefore, such processing can be easily performed at low cost.
Further, when the liquid sealing resin is formed of a porous resin, air can pass through the porous resin even after blood collection. In addition, even an analyzer that sucks blood by inserting a tube, or an analyzer that sucks blood from a capillary blood collection device by applying a negative pressure can be used without any problem.
Further, when the liquid sealing resin is formed of a porous resin body provided with a water-swellable material in each hole, the porous resin cannot pass air or water after blood collection. For this reason, for example, even an analyzer that extrudes blood by pressing a liquid sealing resin in a capillary blood sampling device can be used without any problem.
Furthermore, the rigidity of a cylindrical main body can be improved by shape | molding the external shape of the said cylindrical main body in cross-sectional polygon.
Since it is a plastic material, it can be colored easily, and when there are a plurality of types of capillaries with different anticoagulants, the effect of preventing mistakes in the arrangement can be imparted by distinguishing them by color.

  Embodiments of a capillary blood collecting device according to the present invention will be described below with reference to one embodiment shown in the accompanying drawings.

1 is a cross-sectional view of an embodiment of a capillary blood collecting device according to the present invention, FIG. 2 is a cross-sectional view of the capillary blood collecting device shown in FIG. 1, and FIG. 3 is an end view of the capillary blood collecting device shown in FIG. It is an enlarged view.
As shown in FIGS. 1 and 2, this capillary blood sampling device is composed of a cylindrical main body 1 whose outer shape is rectangular in cross section.
This cylindrical main body 1 is processed into a tapered shape in which inner surfaces of both end portions 2 and 3 widen outward (see FIG. 3).
After the cylindrical main body having the above-described configuration is molded from a plastic resin, it is treated by an appropriate method so that its inner surface becomes hydrophilic.
This hydrophilic treatment is performed by, for example, sucking and discharging a solution obtained by dissolving 0.5% of a surfactant in water into the cylindrical main body 1 and then drying it.
Moreover, as for the cylindrical main body 1, an anticoagulant is given to the inner surface as needed. In this anticoagulant treatment, for example, a solution obtained by dissolving 1.5% (W / W) of an anti-anticoagulant (for example, heparin lithium) in water is once sucked into the cylindrical body 1 and then discharged. Is done.
The hydrophilic treatment and the anticoagulant treatment described above can be performed simultaneously as necessary. Specifically, after a solution obtained by dissolving 0.5% of a surfactant and 1.5% (W / W) of an anti-anticoagulant (for example, heparin lithium) in water is once sucked into the cylindrical body 1 and discharged. The two treatments can be performed simultaneously by drying. Thereby, since the process process at the time of manufacture reduces, there exists an effect that manufacture becomes easy.
The liquid sealing resin 4 is inserted into the cylindrical main body 1 configured as described above.
As shown in FIG. 1, the liquid sealing resin 4 is inserted at a position that is one third of the entire length of the cylindrical main body 1. In this way, by inserting the liquid sealing resin 4 at a position that is one third of the total length, twice the amount of blood collected when blood is sucked from the upper end in FIG. It can be obtained when blood is sucked from the lower end in FIG. Thus, for example, according to the number of test items in the analyzer, when 50 μL of blood is required, blood is aspirated from the upper end in FIG. 1, and when 100 μL of blood is required, FIG. One capillary blood collecting tool can be used properly according to the amount of blood collected so as to suck blood from the lower end of the blood.
The above-described liquid sealing resin 4 may be a porous resin or a resin in which a water-swellable material is inserted into each hole of the porous resin.
In the case of the former (ie, porous resin), air can pass even after blood is sucked up. For this reason, even if the analyzer is an analyzer that sucks blood by inserting a tube into the tubular body of the capillary blood collecting device, the analysis is performed by sucking blood from the capillary blood collecting device by applying a negative pressure. Even devices can be used without problems.
In the case of the latter (liquid sealing resin in which a water-swellable material is inserted in each hole of the porous resin), after blood is sucked up, neither air nor blood can pass. For this reason, for example, even an analyzer that extrudes blood by pressing a liquid sealing resin in a capillary blood sampling device can be used without any problem.

Since the above-described capillary blood collecting tool has the outer shape of the cylindrical main body formed in a rectangular cross section, the capillary blood collecting tool does not bend even if the cylindrical main body is formed of plastic resin. As described above, there is an analyzer that applies a capillary blood sampling device to an analyzer that sucks blood by inserting a tube into the capillary blood sampling device. When using a capillary blood sampling device in such an analyzer, Since the tube cannot be inserted, the capillary blood sampling device having only a rigidity enough to bend cannot be used. However, the capillary blood sampling device according to the above-described embodiment can be used without any problem even in such an analyzer.
In addition, since the above-described capillary has a rectangular outer shape, it is possible to print or affix a barcode on one surface of the capillary, thereby preventing patient misidentification.
Further, in the capillary blood sampling device described above, both end portions 2 and 3 of the cylindrical main body 1 are formed in a tapered shape. For this reason, since the liquid sealing resin 4 can be easily inserted from either end, the manufacturing is very simple. Further, by forming the end portion in a tapered shape, blood can be sucked up by capillary action. For this reason, the above-described capillary blood collection tool has an effect that blood sucking property is good from either end.

In the embodiment described above, the outer shape of the cylindrical main body is formed to have a rectangular cross section. However, this is not limited to this embodiment, and any shape may be used, but it is necessary to ensure a predetermined rigidity. In some cases, the cross-sectional polygon is preferable.
In the above-described embodiment, the liquid sealing resin 4 is inserted at a position that is one third of the entire length of the cylindrical main body 1. However, the position of the liquid sealing resin 4 is limited to this embodiment. Without being limited, it can be arbitrarily determined according to the amount of blood to be collected by the capillary blood collection tool. For example, when it is necessary to suck up 30 μL of blood from one side and 120 μL of blood from the other side, the liquid sealing resin 4 is inserted at a position one fifth of the total length of the cylindrical body. In the case where blood is sucked only from one side, the liquid sealing resin 4 can be inserted at a position corresponding to the required amount.
In the above-described embodiments, heparin lithium is exemplified as an anticoagulant in order to maintain the anticoagulant action of the cylindrical body, but it is not limited to heparin lithium, and any reagent having an anticoagulant action may be used. A plurality of reagents may be mixed in order to balance the electrolyte concentration in the blood. And the density | concentration can also be changed according to a use purpose.
In the above-described embodiments, the chemical treatment in which the hydrophilic treatment of the cylindrical main body is performed using a surfactant solution is described as an example. It is not particularly limited as long as it is a certain substance, and the concentration of the surfactant may be not more than the critical micelle concentration. Furthermore, the method of hydrophilic treatment is not limited to this example, for example,
Discharge treatment represented by corona discharge treatment, glow discharge treatment, low temperature plasma treatment and plasma polymerization treatment,
Deposition process,
Flame treatment,
Ozone treatment,
Ionizing radiation treatment represented by UV treatment, electron beam treatment and radiation treatment,
Ion treatment,
Roughening treatment,
Laser treatment,
Rubbing treatment,
Primer treatment,
Thin layer coating process,
You may process by electrodeposition processes or processing methods, such as a graft process.

Sectional drawing of one Example of the capillary blood-collecting device which concerns on this invention 1 is a cross-sectional view of the capillary blood collecting device shown in FIG. FIG. 3 is an enlarged view of the end of the capillary blood sampling device shown in FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Cylindrical main body 2 End part 3 End part 4 Liquid sealing resin

Claims (6)

A capillary blood collection tool having a cylindrical body that sucks a component to be collected using capillary action,
The cylindrical body is made of a polymer material, and
A capillary blood sampling device characterized in that the inner surface of the cylindrical main body is treated to be hydrophilic. The capillary blood collecting device according to claim 1, wherein a liquid sealing resin for stopping a component to be sucked at a predetermined position is provided in the cylindrical main body. The capillary blood collecting tool according to claim 2, wherein an inner surface of at least one end of the cylindrical main body is formed in a tapered shape that spreads outward. The capillary blood collecting tool according to claim 2 or 3, wherein the liquid sealing resin is made of a porous resin. The capillary blood collecting device according to claim 2 or 3, wherein the liquid sealing resin is composed of a porous resin main body provided with a water-swellable material in each hole. The capillary blood sampling device according to any one of claims 1 to 5, wherein the outer shape of the cylindrical main body has a polygonal cross section.

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